Full text of Productivity of Labor in Merchant Blast Furnaces : Bulletin of the United States Bureau of Labor Statistics, No. 474

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U. S. DEPARTMENT OF LABOR
JAMES J. DAVIS, Secretary

BUREAU OF LABOR STATISTICS
ETHELBERT STEWART, Commissioner

BULLETIN OF THE UNITED STATES \
*T
B U R E A U OF L A B O R S T A T I S T I C S /.................... llO.
MISCELLANEOUS

SERIES

PRODUCTIVITY OF LABOR IN
MERCHANT BLAST FURNACES




DECEMBER, 1928

UNITED STATES
GOVERNMENT PRINTING OFFICE
WASHINGTON
1929

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A D D I T I O N A L C O P IE S
OF THIS PUBLICATION M A Y BE PROCURED FROM
THE SUPERINTENDENT OF DOCUMENTS
U.S.GO VERNM ENT PRINTING OFFICE
WASHINGTON, D. C.
AT

25 C E N T S P E R C O P Y

FOREWORD

It has been the purpose of the Bureau of Labor Statistics in this
study to measure the increase of productivity in pig-iron manufacture
in recent years in terms of output per man-hour and to study the
causes of increased productivity with special reference to technical
improvements and to reductions in the number of men required in
the labor crews. The present bulletin contains the results of the
bureau’s work in the merchant blast-furnace industry.
To determine output per man-hour it has been necessary to obtain
(a) annual production of pig iron in gross tons, and (b) total annual
man-hours of labor chargeable against blast-furnace operation. To
explain the changes in tons of pig iron produced per man-hour,
information has been obtained relating to materials, operation, and
equipment showing some of the principal causes of increasing pro­
ductivity.
Data for this study were compiled for the most part by agents of
the bureau in the field from the records of the companies. The
response to the bureau’s requests has been exceedingly gratifying.
The information relating to production and operation was quite easily
accessible in most cases, but difficulty was frequently encountered in
compiling figures for the total man-hours of labor.1 Pay rolls, force
reports, and other records from which man-hours may be derived
were sometimes fragmentary, or completely absent for some years,
while in other cases the effort required to make compilations from
available records was so great that the schedules for certain com­
panies have been confined to recent years only. The period covered,
from 1911 to 1927, was selected for two reasons. (1) It was desired
to include pre-war, war, and postwar conditions, and (2) the bureau
had already collected figures during this period showing the total
man-hours worked in many of the blast-furnace plants in the country.
The data obtained have made it possible to construct a thoroughly
comprehensive picture of the productivity situation for 1926; in addi­
tion, the information available for earlier years has been reasonably
adequate for the measurement of changing productivity since 1920,
while for years prior to 1920 the number of plants studied is suffi­
ciently large to be at least a fair sample of the industry.
The merchant blast-furnace industry.— Pig iron is an unfinished
product requiring further refinement before final use in the manu­
facture of castings, rolled, and forged products, etc. The pig-iron
industry is devoted to the production of pig iron from iron ore, the
smelting process taking place in a blast furnace.
The term “ merchant blast f u r n a c e as it is commonly understood
in the industry, covers those plants producing pig iron for sale in the
open market. As used in this bulletin, the merchant industry covers
not only the above plants but it also includes a few steel-company
furnaces which, because of their isolation and independence of opera­
tion, closely resemble the former group. The definition of a merchant
blast furnace for the purposes of this study has been framed so as to
i A full description of the methods used in computing man-hours may be found in Appendix 6.




Ill

IV

FOREWORD

include all blast-furnace plants with management and labor crews
independent of steel works and whose metal is cast into pigs to be
remelted by consumers instead of being furnished in molten condition
to adjacent steel furnaces. For purposes of measuring productivity
of labor neither the ownership of the plant nor the marketing of the
product is of any special importance, while the method of casting
the metal and the organization of the labor crews are decisive factors;
therefore, steel-company blast-furnace plants which are independently
operated and which cast their metal into pigs are assigned to the
merchant blast-furnace industry in this study.
Three merchant furnaces in recent years have been furnishing part
of their product in molten condition direct to an adjacent foundry
or open-hearth plant; but these plants are merchant in the strict
sense, and being fundamentally different from blast-furnace plants
connected with a steel works are here included as merchant furnaces.
On the other hand, a blast furnace which furnishes virtually all
its product in molten condition to an adjacent steel works, or which
is an integral part of the layout of a steel plant, is classed as a steel­
works stack and is excluded from the merchant group. Two former
merchant furnaces became so intimately connected with steel plants
during the war that practically all their product is now disposed of
in molten condition. These furnaces have been classed as steel­
works stacks since that time.
Meaning of 'productivity.— Productivity is here defined as the rate
of output of the workers in a given process, plant, or industry. It
represents a ratio betwTeen production and labor time, and it may be
expressed either as the output of product per man-hour of labor time
or as the man-hours of labor time required to produce a unit of
product. The unit of production used in the blast-furnace industry
is a gross ton of pig iron; the unit of labor time is the man-hour.
The total labor time charged against the product includes the
unweighted hours of labor of all men working on the particular
process regardless of their skill or training. The hours of the superin­
tendent are counted just the same as the hours of the unskilled
laborer in the yard crew, though the former may be worth many times
as much as the latter. It is not practicable to make any allowances
for the quality of the labor entering into the product. The total
man-hours of labor time charged against the blast furnace include all
direct labor hours as well as the hours of all overhead producing
labor— plant superintendent, foremen, chemists, and all clerks in the
plant office directly concerned with production. On the other hand,
clerks and bookkeepers working in accounting, all labor in the general
office (if any), and all labor connected with sales or delivery of the
product have been excluded.
A productivity study in the merchant blast-furnace industry
is largely a study of the substitution of machinery and engineering
efficiency for labor. When output is increased because of enlarge­
ment of the plant or improved operating efficiency it is at least
possible to assume that the increased production has come about in
response to a better demand, and therefore no reduction need be
made in the number of men employed; but an increase in productivity
by the introduction of a new labor-saving machine is sure to result
in some displacement of labor in the particular plant. As far as
the whole industry is concerned, unless the increase in productivity,




FOREWORD

V

through the expansion in production, is paralleled by an equal
increase in demand for the product, it will cause a reduction in the
labor requirements of the industry and throw some men out of work.
When changing productivity can be related to its underlying causes
light is thrown on the relative importance of various methods of
increasing production per worker or reducing the labor time required
in production. A cross section view of an industry such as here
presented, showing the variations between plants, brings out the
possibilities of improvement which lie in bringing the industry as a
whole closer to the best practice, as seen in the records of the most
productive plants. Some of the obstacles to such improvement,
such as irregular operation which is brought about primarily by
unstable market conditions, are also shown incidentally by the data
compiled.
Because output per man per hour in pig-iron production has
increased, it is not to be assumed that either the workers or the manage­
ment should claim sole responsibility for the change. An hour of a
man’s time expended in production is merely a useful unit to be related
to production in measuring the combined effectiveness of management,
labor efficiency, new processes, and all other factors which affect
productivity. Where possible important and readily measurable
factors in changing productivity have been isolated and discussed.
The problem in measuring productivity, whether from original
records and individual plants or for an entire industry, is that of
using and harmonizing the statistics of production and of employment
which are already being compiled for other purposes. This is being
done in the internal statistics of many large concerns, but it is not
easily done from secondary statistics by industries. When the
importance and practicability of productivity measurement are
clearly understood it may lead to the keeping of records in such a way
that changes in output per man-hour can be shown with fair accuracy
from month to month or year to year without undue effort.







CONTENTS
Page

1-8
C hapter 1.— Summary_________________________________ _____________________
Analysis of the trend in productivity___________________________________
3, 4
Summary by years_______________________________________________________
4 -6
Adjusted summary_______________________________________________________
6 -8
C hapter 2.— Geographical comparisons_____________________________________
9 -1 8
Description of the districts______________________________________________
9-11
The Great Lakes district___________________________________________
9
The Ohio “ inland” district_________________________________________
9, 10
The Ohio River district_____________________________________________
10
Pennsylvania and New York_______________________________________
10
The S o u t h . . _ _ _ _ _ _ _ _________ _________________ ____________________ 10,11
Productivity by districts____________________________ ____________________ 11-15
Consumption of raw materials, by districts____________________________ 16-18
C hapter 3.— Cross section of productivity showing variations between
plants by years_________________________________________ ____________________ 19-23
C hapter 4.— Methods by which productivity has been increased_________24-63
Increasing output and decreasing labor tim e__________________________ 24 -2 9
Relative influence of output per stack-day and man-hours of labor
#
time on productivity__________________________________________________ 29 32
Increase in output per stack-day________________________________________ 32 41
Reduction in labor tim e_________________________________________________ 41 -5 6
Means employed to reduce labor time in individual establish­
ments______________________________________________________________ 41-47
Productivity by occupations and labor groups____________________4 7 -5 6
Analysis of productivity changes in individual plants_________________ 56-63
Plants making extreme increases in productivity_________ - ______ 57-61
Plants showing moderate increases______* _________________________ 61, 62
Plants showing constant or declining productivity________________ 62, 63
C hapter 5.— General conclusions____________________________________________ 64 -6 6
A P P E N D IX E S
A ppend ix 1.— General tables_______________________________________________
T a b l e A . — Labor

69-115

productivity, production, output per stack-day,
consumption of materials charged, and changes in equipment,
in merchant blast furnaces, by plants and by years, 1911 to 1927. 71-103
T a b l e B.— Labor productivity, production, output per stack-day
and methods of charging and casting in merchant blast furnaces in
the United States, by years and by plants, 1911 to 1927_______ 104-115
A p p e n d ix 2.— Individual plant studies in early years_________________ 116-125
T a b l e C.— Labor productivity, output per stack-day, consumption
of materials charged, and changes in equipment in six merchant
blast-furnace plants reporting for eariler years_________________ 118-125
A p p e n d ix 3.— Representative force reports analyzed and compared___ 126-134
F orce R e p o r t No. 1.— Number of men normally employed in a
northern, inland, two-stack blast-furnace plant, during one-furnace
operation in 1927, by labor groups and occupations______________
128
F orce R e p o r t No. 2.— Number of men normally employed in a
northern, inland, one stack blast-furnace plant in 1927, by labor
groups and occupations__________________________________________
129
F orce R e p o r t No. 3.— Number of men normally employed in a
northern, inland, one stack blast-furnace plant, before and after
the installation of a coke plant, by labor groups and occupations
with the percentage of labor time chargeable to the blast-furnace
department under joint operation with the coke plant in 1927_„ 130, 131




VII

VIII
A p p e n d ix 3 —Continued.
F orce R e p o r t N o .

CONTENTS
Page

4.— Number of men normally employed in a
southern two stack blast-furnace plant during one and two furnace
operations in 1927, by labor groups and occupations_____________
132
F orce R e p o r t No. 5.— Number of men normally employed in a
northern, inland, one stack blast-furnace plant during 2 and 3 shift
operations in 1923 and 1927, by labor groups and occupations____
133
F orce R e p o r t No. 6.— Number of men normally employed in an
eastern Pennsylvania one stack blast-furnace before and after the
installation of mechanical filling equipment, by labor groups______
134
F orce R ep o r t No. 7.— Comparison of the labor force under 2-shift
operation with the force used under 3-shift operation, 1923, plant
16______________________________________________________________
134
A p p e n d ix 4.— Relative efficiency of a blast furnace in producing different
grades of pig iron_________________________________________________ 135-137
A. Foundry versus basic________________________________________ 135, 136
B. Foundry versus basic and malleable____________________________
136
C. Foundry versus ferromanganese______________________________ 136, 137
A p p e n d ix 5. — Statistics of merchant blast furnaces in relation to the
entire blast-furnace industry_______________________________________ 138, 139
A p p e n d ix 6. — Methods of computing man-hours_____________________ 140, 141
A p p e n d ix 7.— Definitions____________________________________________ 142-145




BULLETIN OF THE

U. S. BUREAU OF LABOR STATISTICS
NO. 474

WASHINGTON

DECEMBER, 1928

LABOR PRODUCTIVITY IN THE MERCHANT BLAST-FURNACE INDUSTRY,
1912-1927
CHAPTER 1.— SUMMARY

The productivity of labor in the merchant blast-furnace industry
was more than twice as great in 1926 as in the pre-war period 1912—
1914. A summary of those plants covered by the bureau survey
shows that the average output of pig iron per man-hour of labor in
the period 1912 to 1914 was 0.141 gross ton, while for the year 1926
the output was 0.296 gross ton. Or to state it another way, it
required slightly more than 7 hours of labor time to produce a gioss
ton of pig iron in the pre-war period as against 3 hours and 23 minutes
in 1926. While 1911 figures are given in this study for a few plants,
the sample is not sufficiently representative to stand for the industry
as a who)e, and figures for that year have not been considered in the
summary.
This increase in productivity has taken place almost entirely since
the war. The great expansion in pig-iron production, which began in
1915 and continued almost without interruption until the summer of
1920, was accompanied by a comparatively small increase in output
per man-hour of labor. The summary averages indicate that the
output per man-hour in the mere han t-f urn ace industry remained
fairly constant from 1912 until after the war. In 1920 the output was
0.157 gross ton per man-hour, which means that it required 6 hours
and 22 minutes of labor time to produce a ton of pig iron, only a slight
increase in productivity as compared with the pre-war period. Be­
ginning with 1921 the productivity averages turn sharply upward
and continue in that direction in every succeeding year except one—
that is, the increase in productivity during the period covered by this
study has been due almost entirely to the rapid improvement in the
industry during the last six years.
One of the most important causes of the great improvement in out­
put per man-hour has been the abandonment of many of the ineffi­
cient low-productivity plants. In 1921 the average output per
man-hour in merchant blast furnaces was very much higher than in
the previous year because the depression forced out many of the
weaker plants, leaving mostly high-productivity plants in operation.
During the prosperity of 1923 many low-productivity plants came back
into the industry, but the keener competition of the steel works blast
furnaces since then has driven a great number of them out of business.
Less than three-fourths of the merchant plants operating in 1923
remained active until 1926, and the high-productivity average of the
latei year is due in no small degree to the closing down of inefficient
plants.



1

2

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

Prosperity and depression, however, exert a second influence on
productivity which directly counteracts the effect of the one men­
tioned above. It is usual to find that the productivity of a single
plant is highest in years of full and complete operation and lowest
in times of depression. For general purposes the labor required to
operate a blast furnace can be divided into twro parts— the direct
producing labor which is essential to the operation of the stack itself
and the indirect auxiliary labor required for repairs, transportation,
power, etc. The man-hours of the first type of labor will ordinarily
vary directly with the number of stacks and the length of time
operated; but the indirect labor is not so flexible in amount, being
quite out of proportion when only one stack of a twro-stack plant is
operating or when one stack operates only a short time during the
year. Applying this to the industry as a whole, it is evident that the
decline in productivity brought about by the influx of low-productivity plants in prosperous years is partly counteracted by the output
per man-hour which will be attained by those plants which have been
operating at full capacity all along.
Another important factor causing the increase in productivity
has been the improvement of blast furnaces and the technical im­
provements in operation, both of which are reflected in greater daily
production per furnace. Prior to the war the average daily output of a
merchant blast furnace was about 260 gross tons, while in 1926
the average was 369 tons, about 40 per cent higher. This does not
mean, of course, that the general run of stacks had their capacity
enlarged to this extent; the increased average for the industry has
been due in part to the abandonment of many small stacks and the
construction of a few large ones. An increase in the daily output
of a blast furnace does not require a proportionate increase in labor
per ton; therefore, one method of improving productivity in a plant
is to enlarge the furnace or to operate it more efficiently. In fact,
a considerable part of the increase in productivity from 1911 to
1927 was due to the high output per stack-day of the average blast
furnace.
Productivity has also been influenced by the substitution of ma­
chinery for labor. The most important labor-saving devices have
been (a) mechanical charging and (6) machine casting, which have
eliminated large numbers of hand laborers engaged in charging ma­
terials into the stack and in handling the pig iron after it has been
cast. Of the 37 plants furnishing data for pre-war years 1911-1914,
15 were both hand filled and sand cast, while only 8 were mechanically
filled and machine cast. But in 1926, out of 49 plants furnishing
data, only 3 were both hand filled and sand cast, while 34 were both
mechanically filled and machine cast.
Another development in recent years, which has had an important
effect on the number of men required to operate a blast furnace, is
the substitution of the 8-hour day for the 12-hour day. Although
three crews were required where two had been used before, the labor
force was so reorganized in a majority of plants that very few more
men were employed, while the total man-hours were actually reduced.
Shorter hours have lessened the strain on the workers, so that the
men can be kept more continuously at work. This has frequently
led to the combination or elimination of occupations formerly essen­
tial. Thus shorter hours have furnished added incentive to more



SUMMARY OF TREND IN PRODUCTIVITY

3

efficient production, resulting in higher productivity of labor. The
effect of the 8-hour day on the productivity averages for the industry
has been limited because the 12-hour day still persists in a consider­
able number of plants, but the influence of the shorter day can be
measured in the productivity of individual plants.
The above analysis does not by any means exhaust the list of causes
affecting productivity. It is impossible to take account statistically
of the increased good will existing between the management and the
workers because of shorter hours and higher wages, or of the increased
skill and efficiency of the workers, or of improved management of
labor. These have contributed to the remarkable advance in the
productive efficiency of the industry, but nothing more can be done
in this study than to indicate their presence in the total mass of
factors which have brought about the change.
ANALYSIS OF THE TREND IN PRODUCTIVITY

The summary for the merchant blast-furnace industry, which is
presented in Table 1, shows the productivity averages for the 80
plants covered in this study. Annual averages are shown for all
years, 1919 to 1926, but averages for years prior to 1919 are given
for one 2-year period, 1917-1918, and one 3-year period, 1912-1914.
Figures for the years 1911, 1915, 1016, and 1927 do not cover a
sufficient number of plants to be representative of the industry and
these years have not been considered in the summary. From 1919
to 1926 the productivity averages represent from about 75 to 90 per
cent of the industry in each year, with only a slightly smaller repre­
sentation in 1917 and 1918. In the pre-war years, 1912, 1913, and
1914, the proportion of the industry covered is about 30 per cent,
which would be a sufficiently large sample, if it were thoroughly repre­
sentative. However, when the figures for 1912, 1913, 1914, 1917,
and 1918 are analyzed (see Table 2) it is found that the sample for
each year, while large enough as regards number of plants covered,
is not sufficiently representative in character to be used in drawing
conclusions for the industry as a whole. Certain plants with low
productivity are missing from the data for some years, while the
reverse is true in others. Therefore, since the purpose of this sum­
mary is to give as clear a picture of the trend in labor productivity in
the industry as possible, it was considered desirable to combine the
data for the years 1917 and 1918 and for the years 1912, 1913, and
1914, thus obtaining figures for larger and more representative
samples.




4

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

T a b le

1 .— Average labor productivity in all merchant blast-furnace plants covered
in this stu dy , by selected periods and yea rs , 1912 to 1926

Average productivity
Total
number
of plants

Year

Man-hours
Output per
per gross ton
man-hour
of pig iron
(gross ton)
produced

49
43
49
60
40
36
57
50

78
67
76
88
66
68
90
79

50.3
43.1
42.2
i 60.3
27.1
i 15. 4
2 63.1
i 45. 7

0. 296
.285
.244
.213
.232
. 178
. 157
. 144

3. 379
3. 511
4. 095
4. 693
4. 302
5. 614
6. 367
6.948

56

86

2 70.8

.143

7. 013

CO

1926________ _____ ________________________
1925_________________________________________
1924_________________________________________
1923_________________________________________
1922____________________________ ________ ____
1921_____
________________________________
1920_________________________________________
1919_________________________________________
1918_________________________________________
}
1917_________________________________________
1914_________________________________________
1913
1912_________________________________________

Total
number
of stacks

Average
number of
full-time
stacks
active

60

3 44.6

.141

7.087

i Not including 1 plant for which days operated were not reported.
* Not including 3 plants for which days operated w^ere not reported.
* N ot including 2 plants for which days operated were not reported.

SUMMARY BY YEARS

Table 2 shows the annual totals and unadjusted averages for the
80 plants covered in this study. The total man-hours of labor and
the total production of pig iron include those plants which reported
man-hours in each year, the number of plants being shown in column
2. During the period 1921 to 1926 the variations in the number of
plants shown represent almost exactly the number of plants operat­
ing in the industry each year, and the sample shown for 1919 and 1920
represents a considerable portion of the industry in those years; but
for the period 1911 to 1918 it can not be assumed that the variations
in number of plants correspond very closely to the number of plants
operating. The percentage of the total industry represented in the
bureau figures increases rapidly from 1911 to 1920, partly because
many blast furnaces now abandoned were then operating and partly
because many of the plants for which the bureau has schedules could
not furnish the man-hours for these early years. Lack of data is
responsible for the annual variations in the number of plants in the
averages for 1911 to 1920.1
i The extent to which the bureau figures cover the blast-furnace industry as a whole and the merchant
industry in particular is shown in Appendix 5.




5

SUMMARY BY YEARS

2 .— Labor productivity , total hours o f labor , total production , and average
production per stack-day , in all merchant blast furn aces combined, by years,
1911 to 1927

T a b le

Year

Total
num­
ber of
plants

1

19271„
1926...
1925...
1924...
1923._.
1922...
1921__
1920__
.1919__
1918__
1917__
1916__
1915...
1914...
1913__
1912__
1911__

21
49
43
49
60
40
36
57
50
48
45
9
10
27
28
27
22

Average labor pro­
ductivity
Average
number
of
Total
num­ full-time
M anstacks
ber of
Output hours per
active
stacks
per
gross ton
during
man-hour of pig iron
year
produced
2

34
78
67
76
88
66
68
90
79
75
61
15
16
47
39
37
30

3

25.5
50.3
43.1
42.2
2 60.3
27.1
2 15.4
3 63.1
2 45.7
4 60. 8
4 49. 8
10.9
11.6
3 29.0
3 29.0
« 23.7
3 16.4

4

Gross ton
0.300
.296
.285
.244
.213
.232
.178
.157
.144
. 131
.150
.147
.159
.160
.151
.150
.140

5

3. 329
3. 379
3. 511
4.095
4. 693
4. 302
5. 614
6. 367
6.948
7. 654
6. 688
6. 787
6.278
6.457
6. 632
6. 667
7.119

Production of pig
iron
Total
one-man
hours of
labor

6

6,108, 201
22, 881,062
19,526, 548
20,675,056
30, 649, 850
14,014,155
9,130,917
37, 573, 753
29,368,837
40,231, 261
31, 711,303
6, 271,090
6, 715,495
18, 710,140
18, 982, 366
16, 759, 540
11,959,131

Total

Average
per
stack-day

7

8

Gross tons Gross tons
1, 834, 736
397.5
6, 770, 861
369.1
5, 561,138
353. 5
5,049,452
327. 2
2 294.9
6, 531, 544
3, 257, 670
329.8
2 287.1
1, 626,427
3 247. 5
5,901,039
2 246. 6
4, 227,118
5, 256,144
4 225. 6
4, 741,447
4 249. 8
923, 950
231.9
1,069, 715
252.5
2, 994,879
3 262. 3
2, 862, 336
3 258. 3
2, 513, 681
« 261. 4
1,679, 982
3 260. 5

Per cent of total—

Pro­
Stacks
duction
which
which
were
was
me­
machine
chan­
cast
ically
charged
9

81
85
82
75
72
75
71
63
58
56
50
50
31
31
42
50
45

91
87
88
84
71
73
68
56
56
54
49
73
75
64
56
57
57

1 First six months.
3 N ot including 1 plant for which the days operated were not reported.
3 Not including 3 plants for which the days operated were not reported.
4 N o t including 4 plants for which the days operated were not reported.
5 N ot including 5 plants for which the days operated were not reported.
E X P L A N A T IO N S
Column 1. Number of plants reporting data in each year.
Column 2. Number of stacks represented by the plants in column 1.
Column 3. Number of full-time, active stacks of the plants in column 1; figure obtained by dividing
total stack-days of operation by 365.
Column 4. Gross tons of pig iron produced per man-hour of labor time; obtained by dividing total ton­
nage produced (col. 7) by total man-hours of labor (col. 6).
Column 5. Number of man-hours of labor required to produce a gross ton of pig iron; total man-hours
(col. 6) divided by total production (col. 7).
Column 6. Total hours of labor of all plants shown in column 1.
Column 7. Total production of pig iron of all plants shown in column 1.
Column 8. Average output of pig iron per stack per day; obtained by dividing total production of pig
iron by the total stack-days of operation.
Column 9. Total tonnage which was cast by a pig machine divided by the total production of pig iron
(col. 7).

The above summary table contains the annual man-hour and pro­
duction totals for the full years 1911 to 1926 and the first six months
of 1927. No attempt was made to cover for 1927 all plants covered
for 1926. From these totals the year-by-year productivity averages,
also shown, were computed. In addition the table furnishes much
data from which to study those averages. The average number of
full-time stacks active during the year, when compared with the total
number of stacks, shows the extent to which the plants have been
operated. This is very important as a plant operated intermittently
or one which uses only a part of its equipment can not be expected
to be as effective as one which operates to its full capacity all the time.
Also the average production of pig iron per stack-day, per cent of
total production which was machine cast and the per cent of total
stacks which were mechanically charged are very significant. Collec­
tively, they constitute the most important checks on labor produc­




6

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

tivity contained in this study. Production per stack-day measures,
among other things, the changes in the size of the producing unit.
The per cent of total stacks mechanically charged furnishes one of
the best clews to the reduction of the labor force. The extent to
which the pig-casting machine has been introduced into the industry
also has a bearing on the reduction of labor crews. However, in the
early years the per cent of machine-cast metal is too high, as it happens
that nearly all of the plants missing from the productivity data for
1911-1914 were sand-cast plants. However, this is partly offset by
the fact that in recent years a few plants have used some metal in
molten condition. In 1926, for example, only about 10 per cent of
the total product was sand cast instead of 15 per cent as indicated
by the table. All of these factors are discussed at considerable length
later on.
The averages of output per man-hour indicate that the increase in
productivity, while not a gradual one, has been continuous. In only
one year, 1923, was there a decrease in output per man-hour, and in
that year more plants were in operation than in any other covered
by the bureau’s figures. This shows that the boom conditions of
that year brought many low-productivity plants, which had been
compelled to discontinue operation during the depression of 1921,
back into the industry. Thus the decrease in productivity in 1923
was not due to any decrease in efficiency on the part of the workers
but to a change in the type of plants operating.
In the history of labor productivity from 1912 to 1926 there are
two distinct periods of man-hour production. The first beginning
with 1912 and continuing through 1921, and the second starting with
1922 and ending with 1926. During the first period there was no
concentrated effort on the part of the managements to provide the
newest and best tools or equipment for the use of labor in the manu­
facturing process. In many cases the equipment was antiquated
and most of the work was done by hand. As a result, productivity
during that period was on a low level, the variations from year to
year being mostly due to the variation in plants in operation. How­
ever, as competition became keener and profits lower the fact was
brought home to a large number of operators that if they remained
in the industry their equipment must be modernized. Many oper­
ators took advantage of the depression in busines in 1921 to overhaul
their plants. Thus, with the beginning of 1922, the modern plants
in operation increased rapidly and by 1926 only a few of the plants
still used the old hand methods,
ADJUSTED SUMMARY

An analysis of Table 2 shows that the available productivity data
year by year do not adequately represent the whole industry through­
out the period 1911 to 1927. The averages of output per man-hour
indicate a slow, but steady, increase in productivity from 1912 to
1914, then a rather marked drop during the war period, 1916 to 1919,
followed by a recovery to pre-war levels in 1920, with a rapid increase
since that time except for the year 1923. The number of plants
covered in 1911, 1915, 1916, and 1927 is too small and unrepresenta­
tive to be accepted as a basis for indicating the trend of the industry
as a whole and data for those years are not considered in this sum­




A D JU STE D SUMMARY

7

mary. As previously stated, the productivity averages from 1919 to
1926 represent about 75 to 90 per cent of the industry, and the
averages for years prior to 1919 cover a sufficient number of estab­
lishments to be used for the industry, provided the samples are
thoroughly representative. However, certain plants, with low pro­
ductivity are absent in the averages for the 1912-1914 period, but
they appear in the averages for one of the years 1917 or 1918. Also
the averages for 1917 and 1918 are not thoroughly representative of
the industry as certain other types of plants are included in the aver­
ages for one year and not in the other. Therefore, the fluctuations
in productivity prior to 1919 are due in part to the variations in the
number of plants covered.
Since the trend of productivity over the period covered by this
study is extremely important, it was considered desirable to make
an adjusted summary for years prior to 1919 which would better
express the changes in labor output. When the plants covered in the
years 1917 and 1918 are taken collectively they form an excellent
sample of the industry. A total of 56 plants are included instead of
48, the highest number covered in a single year, and all types of
plants are covered. Thus, as both 1917 and 1918 were war years
and subject to the same operating conditions, it was decided to com­
bine the data and use an average for the war period rather than one
for a single year. All plants with productivity data for either year are
included in the adjusted summary. Since the figures for 1917 were
more representative than those for 1918, the 1918 data were used for
only those plants not furnishing figures for 1917.
A somewhat more complicated adjustment was made in the data
for the years 1912-1914. The first step in the adjustment was almost
identical with the one outlined above. AH plants with productivity
data for any year during the period were used. If a plant has data
for more than one year the year of best productivity, which is usually
the one of full operation, has been selected. This makes possible a
pre-war average including 37 plants instead of 28. However, the
average for the industry of 0.166 gross ton per man-hour is entirety
too high, as the low-productivity plants mentioned above are still
missing from the data. As these plants are included in the figures
for later years it is obvious that some further refinement of the average
must be made if it is to be used. This has been done by computing
productivity averages for the 30 identical plants covered in both
periods, 1912-1914 and 1917-18. These plants are thoroughly
representative of conditions in both periods, and the change in the
averages for them, from 0.160 gross ton in 1912-1914 to 0.162 gross
ton in 1917-18, has been accepted as typical of the change in all
plants during that time. Thus, the figure which has been used in
this report as the best representation of the productivity of labor in
the industry as a whole during the period 1912-1914 was obtained
from the proportion 0.162: 0.143:: 0.160 :X . This results in 0.141
gross ton of product per man-hour of labor.




8

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

The following is an outline of the method used in adjusting the data:
T a b le

3 . — Outline o f method used in adjusting the productivity averages fo r the
years 1912, 1913, 1914, 1917 , and 1918

Year

Adjusted
Average
average
Total
Total
Average
Total
Average
output per output per
number of
number of output per number of output per
man-hour
man-hour
identical
plants cov­ man-hour plants cov­ man-hour
for identical based on
plants cov­
ered in each
in each
ered in each
in each
plants in
the aver­
ered in each
year
each
year
period
ages for
period
period
period
identical
plants

1918...........................
1917...........................
1914__......................
1913 ...........................
1912. ........................

48
45
27
28
27

Gross ton
0.131
}
.150
. 160 )
. 151 V
.150

Gross ton
0.143

30

0.162

37

.166

30

.160

1 Obtained from the proportion 0.162 : 0.143 :: 0.160 : X .




Gross ton

56

Gross ton

i 0.141

CHAPTER 2.— GEOGRAPHICAL COMPARISONS
DESCRIPTION OF THE DISTRICTS

The iron and steel industry as a whole has migrated steadily and
persistently westward and lakeward as western markets have expanded
and the industry has come to depend on lake ores. To this general
trend the merchant blast-furnace industry has been no exception. The
relation between these shifting areas of production and changes in
productivity will be brought out by geographical comparisons below.
In defining districts within the merchant-blast industry it is neces­
sary to be somewhat arbitrary. The districts used have been created
with particular reference to the direct bearing of geographical location
on productivity; for example, all plants located on the Great Lakes
have been grouped together because all of them use dock facilities
and dock labor in handling metals throughout the district from Lake
Ontario to Duluth. The districts are as follows:
THE GREAT LAKES DISTRICT

This district includes all plants located directly on the Lakes,
excluding plants near the Lakes not having a water front.
Without exception, these plants use dock facilities for unloading
materials. Irregular employment of unloading labor during the open
shipping season has caused an inflation of unloading crews to same
extent as compared with inland plants.
The majority of plants in this district are on Lake Erie with several
in or near Chicago. The ores are invariably from Lake Superior
mines, Mesabi ores pjedominating. Limestone is quarried near the
Lakes, and coke is usually produced in by-product ovens integrated
with furnace plants.
Lakeside plants have an advantage in a ready, inexhaustible water
supply for steam and cooling purposes, and the lake shore furnishes
an easy method of slag disposal, new land being made by dumping
slag along the shores of the lake. The excellent operation character­
istic of merchant plants in the Lakes district is better understood
when it is kept in mind that great batteries of steel-works furnaces
are located in this district. Competition with these steel-works
stacks forces merchant furnaces to maintain efficiency of operation
if they are to survive. Most lakeside plants, therefore, are of the
most modern type equipped with complete labor-saving machinery.
It is notable that most of these plants have maintained regular and
continuous operation and have been able to take advantage of the
growing market for merchant iron in the large foundry and steelmaking centers in Buffalo, Cleveland, Detroit, Chicago, and contrib­
utory territory.
THE OHIO “ INLAND” DISTRICT

Here are included all Ohio furnaces, not having Lake or Ohio
River frontage, together with plants in the Shenango Valley of west­
ern Pennsylvania—furnaces along the Shenango and Mahoning
Rivers near Youngstown. The ores, coke, and limestone used by
these plants come from the same sources as those used in the Great
Lakes district.
5421°— 29------ 2



9

10

LABOR PRODUCTIVITY---- MERCHANT BLAST FURNACES

The majority of these plants have been in operation for many years,
but have been thoroughly modernized. All of them receive materials
by railroad, unloading at the plant being done mechanically by car
dumpers or, in smaller plants, on trestles from which the ores or other
materials fall through car bottoms to be repiled as necessary until
ready for use. Few of these plants are integrated with by-product
coke plants. Several are owned and operated by large steel com­
panies. Coking coal is usually brought from the Connellsville district,
or from Kentucky or West Virginia, although some Illinois coal is now
used in making metallurgical coke.
OHIO RIVER DISTRICT

Like plants in the Great Lakes district these plants may be called
“ waterside,” being located on both sides of the Ohio River in West
Virginia, Ohio, and Kentucky. Ores are brought in from Lake
Superior ranges, coke and limestone coming from near-by territory in
Kentucky and West Virginia. The long rail shipment of ore across
Ohio from the Lakes is a disadvantage partially counterbalanced by
cheap coal right at hand. There is an increasing use of river barges
for delivery of coke and limestone and shipment of pig iron.
Formerly this district was of great importance in the merchant
blast-furnace industry but in recent years it has declined. Many
old inefficient plants, handicapped by distance from markets and
materials, have been abandoned, while in some cases the furnaces
have been acquired by expanding steel companies.
PENNSYLVANIA AND NEW YORK

Merchant furnaces in Pennsylvania are located mainly between the
eastern slope of the Alleghenies and the seaboard, with a number of
scattering plants in the western section of the State. As noted above,
the Shenango Valley in extreme western Pennsylvania has been
included with Ohio plants, due to its proximity and similarity to th,e
Youngstown district. Only those New York plants located in the
eastern section of the State are included in this district. One New
England stack is added in 1926.
Production of merchant pig iron in Pennsylvania by merchant
furnace plants is distinctly on the down grade due to a variety of
factors. Many of the plants are located adjacent to ore banks, but
experience has shown that these ores are lean or difficult to smelt in
furnaces as large as those using the fine Mesabi ores. Frequently
located in isolated rural communities, these plants can not obtain the
advantage of intergation with coke plants since there is no local
market for coke-oven gas. Western ores are economically inaccessible
to eastern Pennsylvania smelters on account of long-distance ship­
ment involving reloading at Lake Erie docks. To offset freight
handicaps in the assembly of materials the large eastern pig-iron
markets are near by, but competition with steel-works stacks and
foreign producers has placed the small blast-furnace operator in a
precarious position.
THE SOUTH

Virginia and Tennessee furnaces have been grouped with the Bir­
mingham district plants in this classification. However, Virginia
and Tennessee are declining in importance while production around
Birmingham is expanding.



GEOGRAPHICAL COMPARISONS

11

A distinguishing characteristic of the entire southern district is the
easy economy of operations. Some Alabama ores, although appar­
ently lean in iron content, contain enough limestone to flux completely
the ore in the blast furnace, while coal is usually located within a few
miles of the ore deposits. Virginia and Tennessee ores are somewhat
richer than Alabama deposits, but limestone must be quarried from
the surrounding hills for fluxing purposes.
Geographical advantages and a mild climate combine to render the
problem of handling raw materials a less difficult one than in northern
plants where ores must be shipped in and stored during the summer
months when the Great Lakes are navigable. In the South, mines
are operated the year round and materials are shipped to the furnaces
as needed. Labor requirements in handling materials are therefore
more regular in the South than in districts where storage of immense
stocks is necessary.
PRODUCTIVITY BY DISTRICTS

The summaries made thus far show data for the whole merchant
blast-furnace industry; the next step is the analysis of productivity
by districts. This is set forth in Table 4, which shows the productivity
for selected periods of all districts combined and of each district
separately. The table also shows in each instance the number of
plants reporting, the average number of full-time stacks active, the
average output per stack-day, and the average consumption of mate­
rials per ton of pig iron produced.
Table 4 covers the same plants shown in Table 2, except that in
each period or year prior to 1926 one plant is missing. The missing
plants are those in the West, which are not numerous enough to
constitute a district in any year except 1926; one plant is thus lost
from the record in 1923, and another in the three earlier periods
1912-1914, 1917-1918, and 1920. The loss of these plants, how­
ever, scarcely affects the averages at all.
Thus the productivity averages for all districts combined (Table 4)
correspond very closely to those shown in Table 2. In the discussion
on Table 2 it was pointed out that the productivity average for the
pre-war period 1912-1914 was not sufficiently representative of the
industry, and therefore the average would have to be adjusted in
order to bring it into line with the averages for the later years. That
adjustment was made in Table 3. The necessity for this adjustment
is shown by the data in Table 4, in which the unadjusted productivity
average for the industry is broken down into a number of district
averages; for example, southern district, with a productivity of
0.119 ton per man-hour, is represented in the 1912-1914 average by
only 5 full-time furnaces; but in 1917-18 this same district, with
a productivity of 0.106 ton, is represented in the average to the
extent of 23.4 full-time operating furnaces. The PennsylvaniaNew York district also is not sufficiently weighted in the 1912-1914
average, being represented by 6.6 full-time furnaces as against 13.4
in 1917-18. This does not mean that the plants in these two dis­
tricts were not operating in 1912-1914, but simply that the bureau
was unable to get data for them in this earlier period. This is the
situation which necessitated the adjustment of the 1912-1914 pro­
ductivity average in Table 3 by means of data from a series of identical
plants.




12

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

However, with the exception of the single period 1912-1914, the
variations in the number of operating furnaces as shown in the
table correspond quite closely to actual conditions in each district
and in each period. The influence on the productivity averages of
this shift in production from one district to another is evident.
From 1917-18 down to 1926 the South, for example, has steadily
declined in importance. During the war the South had approxi­
mately one-third of the operating furnaces, while in 1926 this was
reduced to one-fifth. It is obvious that the productivity average
for all districts combined in 1926 would have been considerably
lower had the South maintained its earlier proportion of the total
number of operating furnaces.
4 . — Labor 'productivity, output per stack-day, and consum ption o f materials
charged, by districts and all districts combined fo r selected periods and years,
1912 to 1926

T a b le

District

N um ­
ber
of
plants

Average
number
of full­
time
furnaces
active
during
the year

Average labor
productivity

Output
per
manhour

Average
M anoutput
hours per per stackgross ton
day
of pig
iron pro­
duced

Average consumption of
materials charged per
gross ton of pig iron pro­
duced.

Metal­
lic
charge

Coke

Flux

Pounds
2,123
2,122
1,979
2,071
1, 983

Pounds
841
897
839
764
938

1926
All districts........ ........... ...........
W estern ..._____ ________
Great Lakes......................
Ohio River__.............. .......
Ohio inland-------------------New York and Pennsyl­
v an ia ........................... . .
Southern........................ ..

46
3
10
4
9

48.7
3.5
15.3
3.7
8.5

Gross ton
0. 299
.431
.371
.385
.407

3.349
2. 322
2. 699
2. 600
2. 459

Gross tons Pounds
4,325
379.5
424.1
4, 383
459.2
4, 218
317.9
3,983
430.4
4,109

11
9

8.7
9.1

.236
. 156

4. 245
6. 417

312.2
270.0

3,961
5,510

2,149
2, 823

868
670

58
10
5
13

58.8
18.0
3.7
10.0

.218
.283
.321
.272

4. 579
3. 537
3.120
3. 672

i 303. 5
381.2
281.5
i 393. 3

4, 470
4,311
3,963
4,112

2, 347
2,159
2,195
2,148

999
945
1, 064
1, 032

13
17

11.8
15.3

.168
. 138

5.965
7. 242

242.2
206.0

4,135
5,770

2,350
3,092

1, 2bl
866

53
7
4
9

60.4
14.2
3.2
9.2

. 155
.224
.260
.181

6. 457
4. 469
3. 844
5. 533

i 246. 8
352.6
289.5
i 336. 6

4,
4,
4,
4,

584
694
211
226

2, 519
2,450
2, 404
2, 223

1,142
1,136
1, 280
1,192

14
19

15.9
17.9

.118
.101

8. 482
9.907

181.5
163.6

4, 023
5, 509

2, 482
3, 205

1,322
946

53
9
3
9

68.2
16.8
2.7
11.7

.140
. 161
.205
.195

7.128
6. 222
4. 874
5.120

* 234.9
297.0
233.6
324.4

4,601
4,607
4,194
4,162

2, 556
2,399
2, 298
2, 223

1, 111
1,058
1, 214
1,191

13
19

13.4
23.4

. 116
.106

8. 611
9. 414

2 192. 2
169.8

4, 262
5, 382

2, 586
3,154

1, 379
1, 006

34
10
9

40.4
17.3
11.6

.165
.184
. 187

6.045
5. 447
5. 344

3 272. 2
304.7
280.1

4, 587
4,486
4,314

2, 580
2, 546
2,284

1, 050
1,108
1,182

11
4

6.6
5.0

.134
. 119

7. 444
8. 434

3 221. 5
207.9

4,153
5,358

2,460
3,079

1,400
643

1923
All districts______ ______ ____
Great Lakes.......................
Ohio River______________
Ohio inland_____________
Pennsylvania and New
York__________________
Southern.......... ...................
1920
All districts.......... ............. .......
Great Lakes.____ _______
Ohio River______________
Ohio inland______ ._ . _
Pennsylvania and New
Y o r k ..____ ___________
Southern______________ .
1917-1918
All districts.......... .....................
Great Lakes.......................
Ohio River............. ...........
Ohio inland........ ...............
Pennsylvania and New
Y o r k ...............................
Southern..............................
1912-1914
All districts................ ...............
Great Lakes.......................
Ohio inland_____________
Pennsylvania and New
York__________________
Southern..................... ..

1 N ot including one plant for which the days operated were not reported.
1 N ot including three plants for which the days operated were not reported.
3 N ot including four plants for which the days operated were not reported.




GEOGRAPHICAL COMPARISONS

13

The Pennsylvania and New York district is very similar to the
South, even to the extent that it is not adequately represented in the
pre-war period. It is undoubtedly true, also, that the apparent in­
crease in furnaces operating between the war period and 1920 is due
to a lack of data in 1917-1918 and not due to actual increase in fur­
nace operations in the district. However, since 1920 there is clear
evidence of the steady decline of this district.
The Ohio River district is not represented at all in the averages
for 1912-1914 because of lack of data, but was a flourishing district
at that time. The district has experienced a considerable reduction
in the number of operating furnaces since pre-war days. However,
the number of plants representing the district is so small in all periods
that the “ All districts” average for the industry is hardly affected
by it.
Even the inland Ohio district has not held its own over the five
periods. There has been a considerable decline in the number of
operating furnaces, and while this is partly balanced by the increasing
size of the stacks the fact still remains that the production of pig
iron has steadily declined.
The Great Lakes district alone has increased in importance since
the pre-war period. The data in the table show that the number of
full-time furnaces in the district has not changed since the pre-war
period, but the annual production of pig iron has increased consid­
erably; the average daily output per stack has risen more than 50
per cent in the last 15 years. In 1917-1918 this district produced
about 30 per cent of the total pig-iron output of plants shown in
the table, while in 1926 the proportion had increased to nearly 40
per cent of the total.
The western district is not geographically compact, being composed
of scattered plants which do not logically fall within the other dis­
tricts. It consists largely of new plants which were not in existence
in the earlier periods.
Thus, it is evident that the average output per man-hour for the
whole merchant blast-furnace industry in each of these periods is
markedly influenced by the shifting volume of production in the
different districts. The low-productivity districts (Pennsylvania and
New York and the South) are not adequately represented in the data
for the pre-war period of 1912-1914, which makes the figures for this
period too high, as previously indicated. However, in 1917-1918
these two districts are adequately represented in the productivity
average. The rapid decline of these low-productivity areas in the
more recent period and the increasing production in high-productivity
areas, such as the Great Lakes, tend to increase the average produc­
tivity of the industry. The increased productivity in the merchant
blast-furnace industry then has been partly due to the changing
regional composition of the industry. Even if there had been no in­
crease in productivity from 1912 to 1926 in any district, the average
for the industry as a whole would have increased considerably.
However, the data do show conclusively that in every district there
was a pronounced increase in productivity between 1912-1914 and
1926. In the Great Lakes district the average output per man-hour
in 1912-1914 was 0.184 gross ton; the 1926 productivity of 0.371
gross ton was more than double that amount. The apparent decline
in productivity to 0.161 gross ton in 1917-1918 is due to the absence




14

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

of certain plants from the averages. The 1920 average is also some­
what depressed because three important plants could not furnish
data for that year. The increase in productivity which took place
between 1923 and 1926 is all the more remarkable because of the fact
that the productivity averages in the two periods are for identical
plants. Thus the productivity increase w~as brought about entirely
by improvements in operating efficiency and not by the closing down
of low^-productivity plants. As a matter of fact, in this district all
increases in productivity since 1912-1914 have been due almost
entirely to actual improvements in operation in individual plants,
since practically none have been abandoned, a condition which con­
trasts sharply with the steady abandonment of low-productivity
plants in all other districts. It is significant that all but one small
plant in this district had changed from the 12-hour to the 8-hour
turn by 1926.
The inland Ohio district slightly exceeds the Great Lakes district
in productivity in 1912-1914 and in 1926. However, in the inter­
mediate periods their histories are not at all similar. There was
no improvement in productivity in the inland Ohio district until
after 1920, when the output per man-hour increased more than 50
per cent over a period of three years. This increase was due to
improvements in operation of the existing plants; but the increase
in the following period (from 1923 to 1926), however, was due partly
to the inactivity of some old plants.
The Ohio River district is not adequately represented by the data
for any period except 1926. The figures for all periods represent
only the plants surviving in 1926; in all the earlier periods there were
a large number of plants in operation for which it was impossible to
get data because they had gone out of business in the depressions
of 1921 and 1924. Since the plants which survive are usually those
of high productivity, it is reasonable to assume that the averages
shown for this district in all periods prior to 1926 are somewhat too
high to be representative.
The point of special interest in connection with the PennsylvaniaNew York district is the decline of the industry in Pennsylvania.
This decline is obscured in 1926 by the inclusion in the averages of
several newly constructed New York and New England plants.
When these new plants are eliminated from the 1926 data the re­
sult shows nine plants, 6.8 full-time furnaces in operation, an output
per man-hour of 0.220 gross ton, and an output per stack-day of
278.3 gross tons. These figures and those shown in the table for
the other four periods are for Pennsylvania plants almost exclusively,
only one New York plant being included in the figures for each
period. The extent of the decline of the merchant industry in
Pennsylvania can be measured by comparing the number of full­
time furnaces in operation in 1920 and in 1926, 15.9 as against 6.8.
The trend of productivity in the Pennsylvania-New York district
as a whole is shown by the data from 1917 to 1926, the figures for
the pre-war period being somewhat uncertain because of inadequate
representation of plants. By 1923 a considerable increase in produc­
tivity is evident, due for the most part to improved operation of
existing plants, although three old plants were abandoned during the
period. The period 1923 to 1926 was feautured by the abandon­
ment of old plants in Pennsylvania and the construction of new ones




GEOGRAPHICAL COMPARISONS

15

in New York and New England. These two contrasting develop­
ments combined to bring about a marked increase in productivity in
the whole district during the period.
The inadequate representation of plants in the southern district
in 1912-1914 must be taken into consideration in interpreting the
productivity figures. Since 1917-18 productivity in the South
has increased barely 50 per cent, which is less than the increase in
any other district. Labor-saving machinery and new equipment
have not been generally introduced in the southern district; nat­
urally the output per man-hour is considerably lower than that
in the other districts of the country. In 1920 the man-hour output
in the South was 0.101 gross ton, while the average for the rest of
the country was 0.178 gross ton. In 1926 the variation is still greater,
0.156 gross ton per man-hour in the South as against 0.349 gross ton
for all other districts combined. The plants in the South are operated
mostly by negro labor. The plentiful supply of this labor tends to
prevent the introduction of improved machinery, thus keeping
productivity at a low level.
A fundamental factor affecting the output per man-hour for all
districts combined is the change in daily production per furnace.
While output per man-hour was increasing from 0.140 gross ton in
1917-18 to 0.299 gross ton in 1926, the output per stack-day was
increasing from 234.9 gross tons to 379.5 gross tons. These figures
show the influence on the output per man-hour of the increased
output of the individual Mast furnace.
The data for the various districts reenforce the conclusions drawn
from the data for the industry as a whole. In 1926 in the Great
Lakes district 15.3 full-time furnaces showed an average output of
almost 460 gross tons per day as compared with a daily output
of approximately 300 gross tons in the war and pre-war periods.
Nearly one-half this increase in daily output occurred in the three
years from 1923 to 1926. Correspondingly, the output per man-hour
increased from 0.161 gross ton in 1917-18 to 0.371 gross ton in 1926.
In the southern district, the increase in output per man-hour from
1917-18 to 1926 has almost exactly paralleled the increased output per
stack-day— that is, a large part of the increased productivity in this
district is explained by the increased daily output of the blast furnaces.
The Ohio River district also furnishes an interesting illustration of
the relationship between productivity and a stack-day output. The
average output per man-hour in 1926 exceeds that of the Great
Lakes and is only slightly below that of inland Ohio, but the average
daily output of the blast furnaces in this district was only 317.9 gross
tons as compared with 459.2 gross tons in the Great Lakes and 430.4
gross tons in inland Ohio. The explanation of this fact, that plants
with such a comparatively low output per stack-day should attain such
a high level of productivity, is that the district is represented through­
out the four periods in which it occurs by the few merchant plants
which survived until 1926; naturally, these are the best plants, and
it is not surprising that their average productivity should be high.
All the other districts have their averages greatly reduced by the
inclusion of at least a few inefficient, low-productivity plants.




16

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

CONSUMPTION OF RAW MATERIALS, BY DISTRICTS

The daily output of a blast furnace is determined b f the size and
design of the stack and by the smelting process itself. While the
increased size of the stack has been a major factor in making possible
large daily output, data on this point are available for 1926 only
and will be discussed elsewhere.1 In a blast furnace of any given size
the quality of the raw materials and the efficiency with which they
are smelted determine the stack-day output.
Other things remaining the same a higher yield of iron from the
ores will increase output per stack-day. As a matter of fact ores
are becoming leaner each year as the richer materials are taken from
the mines. In spite of lean ores it has nevertheless been possible to
increase furnace yields by more efficient smelting practice and by an
increasing use of iron and steel scrap and other ore equivalents rich
in iron content. The use of scrap, comparatively rare prior to the
war, has increased rapidly since 1920. Since scrap is practically pure
iron, its use increases furnace yields and therefore output per stackday.
Limestone or other flux is required in the blast furnace for the pur­
pose of combining with the impurities in the ore. The nonferrous
materials in the ore are combined with the flux and are removed from
the furnace in the form of slag. The amount of flux required depends
largely on the nature of the ore and may vary widely.
Fuel requirements vary with the quality and physical characteristics
of the materials charged. More coke is needed in smelting hard,
lumpy, eastern ores than for the fine Mesabi or northern ores. How­
ever, with a given quality of materials, the consumption of coke per
ton of iron varies considerably, according to the skill and judgment
of the furnace operators.
Analysis of materials consumption in the various districts brings
out in sharp contrast the differing conditions in the South as compared
with other districts. The pounds of ore charged per gross ton of
pig iron produced in the South exceed that of any other district by
about 40 per cent; the coke consumption is also very much greater
than the average for the industry, but on the other hand the amount
of flux used is appreciably lower.
As stated elsewhere,2 the southern district in these tables consists
of two distinct areas: (a) The Birmingham section, which includes
the blast furnaces in Alabama, and (b) the Virginia-Tennessee section,
which includes all furnaces in Tennessee, Virginia, and eastern Ken­
tucky. The ores in the vicinity of Birmingham are of two general
types, the so-called “ red” and “ brown” ores. The red or hematite
ores can be further subdivided into “ soft red” and “ hard red,” which
differ only in the amount of limestone they contain. The soft red
ore is found on or near the surface and is the hard ore with the lime
removed by atmospheric action. Underneath the top layer of soft
red the ore becomes hard in proportion to the depth at which it lies;
the amount of lime increases while the iron content correspondingly
diminishes. This hard red ore is therefore largely “ self-fluxing ” ; in
fact, it is not unusual to find these ores so rich in limestone that soft
red or brown ores must be mixed with them in order to take up the
surplus limestone and prevent waste of iron in the blast furnace.




1 See p. 32.

‘ Ch. 2, p. 10

GEOGRAPHICAL COMPARISONS

17

These hard red ores often run as low as 30 to 35 per cent in iron con­
tent. The brown ores, or limonites, aie also found near the surface,
frequently mixed with clay and gravel. They contain very little
lime and are not self-fluxing; they compare with the soft red ores
in iron content, sometimes running well over 40 per cent. How­
ever, all the southern ores are considerably leaner than the typical
ores used in the North.
These qualities of the southern ores explain the high metallic
charge and the low flux consumption of the southern district. Some
plants in this district use as much as 6,000 pounds of ore to produce a
ton of pig iron, while the average for the district is approximately
5,500 pounds. The consumption of flux in the southern district as a
whole falls far below that in other districts, being 670 pounds per ton
of pig iron as compared with an average of 863 pounds for the rest of
the country. However, it is the high flux consumption in the VirginiaTennessee section of the South that makes the average as high as it is;
in 1926 the blast furnaces in the immediate vicinity of Birmingham
averaged about 271 pounds of flux per ton of iron.
The Virginia-Tennessee ores resemble those farther south near
Birmingham in iron content, but they do not contain the large quan­
tities of limestone. Thus the furnace operators in this section must
charge almost as much limestone as would be required in a northern
furnace.
Attention must be called to the fact that the number and identity
of the plants represented in the averages for consumption of materials
do not correspond exactly to those represented in the productivity
averages. Some plants which reported productivity data failed to
furnish any information on consumption of materials, while on the
other hand there are numerous cases of plants which reported on
production of pig iron and consumption of materials in years for
which it was impossible to compute their productivity. Since the
purpose is to obtain as full and complete a record as possible of the
average materials consumption in each district, data have been as­
sembled from all plants whether represented in the productivity
averages or not. It was only by the use of this method that sufficient
data could be obtained for some of the districts in the earlier periods.
For example, the southern district in 1912-1914 shows only 4 plants
in the productivity average, but the average metallic charge covers
10 plants, the average coke consumption 11 plants, and the average
flux consumption 7 plants. On the other hand, the PennsylvaniaNew York district with 11 plants in the productivity average, covers
6 plants in the average metallic charge, 7 in average coke, and 4 in
average flux. In other districts and in all later periods the corre­
spondence between the plants in the productivity averages and those
in the consumption of materials averages is very much closer. In
general the data on metallic charge, coke, and productivity averages
cover practically the same number of plants, but the data on flux
consumption are somewhat weaker, fewer plants being represented
in nearly every case. However, this figure is of much less signifi­
cance than the other two, and the number of plants covered is suffi­
cient to bring out the peculiarities of each district.
Data on the consumption of raw materials by districts are shown in
Table 4. The figures show the number of pounds of each raw material
consumed in the production of a gross ton of pig iron. The metallic




18

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

charge per ton is found by adding together the poundage of iron ore,
scrap, cinder, scale, and all other iron-bearing materials or ore equiva­
lents, then dividing this total by the number of tons of pig iron pro­
duced. The pounds of coke per ton of pig iron are likewise computed
by dividing the total pounds of coke consumed by the number of
tons of pig iron produced. The flux per ton of pig iron is derived by the
same method from the total consumption of limestone and dolomite.
The amount of coke required is much higher in the South than in
other districts. Because of the leanness of the southern ores, the
charge of metal-bearing materials in this district is 20 to 40 per cent
higher, and the smelting of this material requires more coke. In
addition, the southern furnaces use a stronger blast for a given
furnace volume than do those in the North, which probably increases
the consumption of coke.
There has been a remarkable decline in coke consumption in the
four northern districts. The situation in the Great Lakes district
is most striking. In 1912-1914 the blast furnaces in this district
required on the average 2,546 pounds of coke to smelt a ton of pig
iron, while in 1926 they required only 1,979 pounds. Part of this
decrease is due to a greater use of scrap in the charge, but some of it
at least is due to better furnace operation. Each district shows a
lower consumption of coke per ton of pig iron than in w~ar and pre­
war years. The close connection between the relative amounts of
ore and coke consumed is brought out in the data for 1926; the Great
Lakes, Ohio River, and Ohio inland districts, all of which use Mesabi
ores almost exclusively, show very nearly the same amount of coke
consumption per ton of product, the variation being less than 100
pounds— from 1,979 pounds in the Great Lakes to 2,071 pounds in
Ohio River. The western and Pennsylvania-New York districts
show a markedly different coke consumption, thus emphasizing the
different quality of the ores used in those districts.




CHAPTER 3.— CROSS SECTION OF PRODUCTIVITY SHOWING
VARIATIONS BETWEEN PLANTS, BY YEARS

An array of plants according to productivity for each year is set
forth in Table B, page 104, which shows the position in the industry of
each plant. The data emphasize the fact that there has been a wide
range of productivity in all years covered by this study. In 1926 one
plant attained an output per man-hour of 0.573 gross ton, while the
plant at the bottom of the list had an output of only 0.115 gross ton.
Expressed in the opposite way, the first plant required 1.746 hours of
labor to produce a ton of pig iron, while the low-productivity plant
required 8.693 hours. In 1925 the plants vary from a high of 0.512
ton to a low of 0.105 ton. The range remains wide all through the
vears from 0.462 to 0.069 ton in 1923, from 0.446 to 0.063 in 1920,
from 0.326 to 0.059 in 1917, and from 0.313 to 0.051 ton in 1911.
The significance of these figures can perhaps be better understood
when it is pointed out that an output of 0.051 ton per man-hour
means that it requires nearly 20 man-hours of labor to produce a ton
of pig iron. Thus while many low-productivity plants are abandoned
with each depression, nevertheless some plants of this type continue
to operate regardless of all productivity advances in the better plants.
The plants which represent the extremes of productivity are by no
means unique. A comparison of large groups of plants emphasizes
still more the great variations in productivity which can and do exist
side by side in the industry. In 1926 there were 4 plants with an out­
put per man-hour of more than 0.500 ton, and 7 additional plants with
an output between 0.400 and 0.500 ton. At the other extreme there
were 6 plants with an output per man-hour of less than 0.150 ton, and 5
others with an output between 0.150 and 0.200 ton. The average for
all plants in that year was 0.296 gross ton per man-hour.
The marked contrast between conditions in the industry in 1923 as
compared with 1926 is clearly shown by the array of plants for those
years. In 1926 there were 11 plants with a productivity of better
than 0.400 ton per man-hour, while there were an equal number with
productivity less than 0.200 ton. But in 1923 there were no plants
above 0.500 ton, only 4 plants between 0.400 and 0.500 ton, and only
7 others between 0.300 and 0.400 ton, while at the other end of the
list the contrast is even more striking— 19 plants with a productivity
of less than 0.150 ton and 12 others between 0.150 and 0.200 ton.
It has been stated previously that 1923 was a year of full activity
when many low-productivity plants came back into operation after
having been idle for about two years. But it is important to note
also what has happened to these plants in later years. Of the 31
plants having a productivity record in 1923 of less than 0.200 ton
per man-hour, only 17 were operating in 1926, and 2 of these ran a
very small part of the year. Thus almost half the low-productivity
plants of 1923 had ceased operations by 1926. Not all these plants
have been abandoned, but most of them will not operate again.
The “ spread ” of the productivity figures for individual plants, about
the average for the industry in pre-war years, does not differ markedly
from the examples cited above. The variations in 1912 are typical




19

20

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

of pre-war conditions. In that year the 6 best plants had productivity
records between 0.200 and 0.300 ton per man-hour; at the other
extreme there were 5 plants with a productivity of less than 0.100
ton, with 11 others ranging between 0.100 and 0.150 ton. This leaves
only 5 plants with a productivity between 0.150 and 0.200 ton.
The average for all plants in 1912 was 0.150 ton per man-hour.
The productivity position occupied by each plant with reference
to the rest of the industry is determined by a large number of factors
which in some way affect the productivity of the plant. For purposes
of this analysis these factors may be classified into two main groups—
(1) general, and (2) specific. General factors, or causes, are those
which may be common to a number of plants throughout the indus­
try and which can therefore be measured to some extent, or at least
can be rated. Specific factors, or causes, are those which are peculiar
to an individual plant, and which therefore can not be taken into
account other than by merely being noted.
From the data presented in Table B it is possible to enumerate
four general factors which have had some influence in determining
the relative position of the plants in productivity. These are (1)
integration, (2) full-time operation, (3) output per stack-day, and
(4) use of labor-saving machinery.
An integrated plant is one in which the blast furnace is operated
in conjunction with a coke plant, steel works, or any other auxiliary
manufacturing process. Integration is usually advantageous for
productivity because the indirect labor is shared between the dif­
ferent processes, and a considerable saving of such labor often results.
Plant No. 3, which ranks at the top of the industry in 1926, illus­
trates the advantage of being integrated with a coke plant. There
are a number of blast-furnace plants which rank above No. 3 in the
productivity of the immediate blast-furnace crew, but the latter
ranks far above all others in the output per man-hour of its “ all
other ” labor. This shows very clearly the influence of the coke
plant in reducing the indirect labor charged against the blast furnace.
Plant No. 25, which is second in productivity in 1926, is situated near
a rolling mill which shares the indirect labor. The next plant (No.
12) is not integrated at all, but it is a two-stack plant which operated
both stacks nearly all the year. The operation of additional stacks
has some of the advantages of integration in that it makes possible
some saving in indirect labor.
However, the labor economies made possible by joint operation
are not always realized in practice, for even at the bottom of the
list there are plants which have the advantages of integration without
obtaining any results in productivity, for example, plants No. 30
and No. 40 are both integrated, but their productivity averages do
not show any evidence of it. The situation may be summarized by
stating that integration may lead to a considerable, saving of labor,
but it does not necessarily do so. In 1926 the following blast fur­
naces were operated in conjunction with coke plants or other manu­
facturing processes: Nos. 1, 3, 5, 9, 13, 25, 26, 28, 30, 31, 33, 37, 39,
and 40.
The second factor influencing productivity is the extent of full­
time operation. To obtain best performance a plant must be operated
full time at full capacity. Both the blowing-in and the blowing-out
of a stack require several days, during which time there is very little




VARIATIONS BETWEEN PLANTS, BY YEARS

21

output of pig iron to balance the additional man-hours of labor.
Even after the stack has been blown-in it often takes several weeks
to bring its daily output up to full capacity. And lastly, when a
plant operates only a few months during the year the indirect yard
and repair labor is usually much heavier in proportion than normally.
All these circumstances combine to cause a comparatively low output
and a comparatively high total of labor time. This is clearly shown
in Table B. The plant which ranks eighth in productivity in 1926 is
the first one on the list which did not operate full time. On the other
hand, of the six plants at the bottom of the list, only one operated
full time.
A third factor of very considerable importance in determining the
relative position of a plant in the productivity averages is the output
per stack-day. Of the 9 leading plants in 1926 only 3 had an average
daily output of less than 400 tons, and of these 3 the lowest averaged
368 tons. Dividing the entire list into two groups, all 28 plants having
a productivity average higher than 0.250 ton per man-hour have an
average output per stack-day of more than 300 tons, with only two
exceptions, one of which is just under 300 tons. On the other hand,
of the 21 plants having a productivity of less than 0.250 ton per manhour there are only 4 which have a stack-day output of more than 300
tons, and one of these averages 300.8 tons. These comparisons indi­
cate that in the main the plants of high daily output have the best
productivity averages.
Before leaving this point, however, it is necessary to call attention
to the important exceptions to this general statement. Plant No.
50, with a daily output of 262.1 tons, ranks as No. 13 in pro­
ductivity, far above any other furnace of this size, and even above
many furnaces averaging 400 and 500 tons per day. One stack
with a daily output of 500 tons and another with 400 tons rank
quite far down the list in productivity— below what would be nor­
mally expected. However, one of these had just begun operations
and had not reached its best operating efficiency. Three plants with
a fairly large output per stack-day have positions almost at the
bottom of the list. One of these is a northern plant whose average
represents only partial operation; the other two are southern plants
in which modern labor-saving devices have not yet been installed.
The fourth point in connection with variations in productivity
concerns the use of labor-saving machinery, especially machines for
charging and casting. Table B shows the method of charging and
casting of each plant individually.1 These data are summarized in
the following table, only one minor change being made to facilitate
classification. Plants which are listed in Table B as using both
methods of charging or casting in any one year are, for the purposes
of Table 5, classed according to the proportion of the total produc­
tion handled by each method. Thus, plant No. 2 is shown in Table
B as being both hand cast and machine cast in 1926, but in Table 5
the plant is classed as machine cast because 86 per cent of the total
product was cast by that method.
1 See Appendix 1, p. 104.




22
T a b le

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES
5.— A ll merchant blast-furnace plants covered in this study, classified by

methods o f charging and casting, by years, 1 9 1 1-1 9 2 7

Year

1927_______________________ _ _.......................
_______
1926_____________________________
1925_____________________________
- _ _ .
____________
_______
1924________________
1923_____________________________ ___________
1922____ ____________________________________
1921____ ____________________________________
1920____ ___________________________________
1919_____________ : __________________________
1918_________________________________________
1917_________________________________________
1916_________________________________________
1915_________________________________________
1914_________________________________________
1913_________________________________________
1912_________________________________________
1911_________________________________________

Mechan­
Mechan­
Hand
Hand
ically
Total
filled and
ically
number filled and
filled and
filled and machine
of plants sand cast
machine
sand cast
cast
cast

21
49
43
49
60
40
36
57
50
48
45
9
10
27
28
27
22

2
3
3
6
12
7
8
21
21
20
18

3
8
8
10
15
12
11
11
9
10
9

3
12
12
12
11

5
8
6
6
5

4
3
3
8
4
5
7
5
5
6
3
1
2
2

16
34
29
30
23
17
12
17
15
12
10
6
2
5
6
7
6

Insuffi­
cient
data

2
1
1
2
1
2

The introduction of machinery into the industry is best illustrated
by the decline in the number of hand-filled, sand-cast plants since
1920. Prior to 1921 more than one-third of all the plants on the
list belonged in this group, while in 1926 there were only 3 such
plants out of 49. The other side of the situation is shown by the
number of mechanically-filled, machine-cast plants. There was a
steady increase in the number of these plants during the period
1917 to 1920, but the greatest change in this respect took place after
the depression of 1921. Many plants which had had little oppor­
tunity for plant improvement during the war took advantage of the
shutdown to enlarge their stacks and modernize their equipment.
Since 1922 the number of mechanically-filled, machine-cast plants
has increased as rapidly as the number of hand-filled, sand-cast
plants lias declined. The “ hybrid” plants (mechanically-filled and
sand-cast, or hand-filled and machine-cast) constitute a kind of transi­
tion group through which plants pass on their way from hand methods
to machine methods. The combination of hand filling and machine
casting has been comparatively rare in the industry throughout the
whole period from 1911 to 1927 but the combination of mechanical
filling and sand casting has remained quite common until the last
three years. These facts indicate that the skip hoist preceded the
pig machine as a labor-saving device in the industry.
The effect of these methods of charging and casting on productivity
is evident from Table B. Plants which are hand filled or sand cast
are common in the lower half of the list in 1926, but in the upper
25 plants there is only one which is either hand filled or sand cast,
and that one is a hybrid— being hand filled and machine cast. The
best mechanically-filled, sand-cast plant ranks thirty-first in pro­
ductivity, while the best hand-filled, sand-cast plant ranks thirtyseventh. The latter plant, No. 48, when compared with the mechanically-filled, machine-cast plants, shows a lower productivity record
than 30 of them, and a higher productivity record than 3. Further
comparisions can be drawn, but those which have been made are
sufficient to demonstrate the fact that the use of machinery has been
a most important factor in improving productivity in the merchant
blast-furnace industry.



VARIATIONS BETWEEN PLANTS, BY YEARS

23

The four general factors affecting productivity have been enum­
erated, but in addition to these there are frequently specific factors
which are peculiar to individual plants. A multitude of minor varia­
tions in plant layout, yard transportation, and auxiliary equipment
may affect the amount of labor required to operate different plants,
and may thus influence productivity. One plant, for example, is
wedged in between a river and a railroad, with a county highway
running right through the plant. Naturally, operations are cramped
by lack of space, and more labor is required than would otherwise
be necessary. Many little details of plant organization are peculiar
to the plant having them; these details must be kept in mind in com­
paring one plant w^ith another. Not that these minor variations
would have a very important effect on productivity, but they might
have sufficient influence to cause a difference in the productivity of
two plants which in all other respects are practically alike.




CHAPTER 4.— METHODS BY WHICH PRODUCTIVITY HAS
BEEN INCREASED
INCREASING OUTPUT AND DECREASING LABOR TIME

The output per man-hour of a given establishment or of an industry
can be increased (a) by increasing the output, (&) by decreasing the
labor time, or (c) by a combination of both methods. Applying this
principle to merchant blast furnaces, it is evident that the changes
in productivity have been brought about in all these ways.
(a) Production per furnace per day (output per stack-day) may
be increased, either as a result of an increase in the size of the furnace
or because of an advance in technical knowledge, engineering skill,
operating efficiency, etc.
(b) Labor time (man-hours) per furnace per day may be reduced,
as a result of improved labor management, greater effort and skill
on the part of the workers, or the introduction of new methods and
machinery which directly displace labor.
(c) It frequently happens in individual establishments that the
stack is enlarged at the same time that labor-saving machinery is
installed, so that the increase in output per stack-day coincides with
the decrease in labor time. In fact, this is the most economical
method of making the change, for the larger production is essential
to support financially the costs of installing the machinery.
The first method of increasing pioductivity will be found mostly
in plants which are strictly modern in equipment. In plant No. 9,
for example, the stack has been enlarged with each rebuilding, and
the output per stack-day has steadily increased, but the changes in
output per man-hour correspond very closely to the changes in the
output per stack-day, thus indicating that the total daily man-hours
of labor have remained about constant during the period.
When the output per man-hour and the output per stack-day rise
and fall together it shows that the man-hours of labor time are
unchanged. The output per man-hour is the total annual production
of pig iron divided by the total annual man-hours of labor, but the
result is the same of course if put on a daily basis— that is, the output
per man-hour is equal to the average output of pig iron per stack-day
divided by the average man-hours of labor per stack-day. It follows
that if the man-hours per day remain absolutely constant the output
per stack-day will determine increases or decreases in the output
per man-hour and the two will vary in exact proportion to each
other— that is, whenever the changes in output per man-hour closely
follow the changes in output per stack-day, it indicates that the
man-hours of labor time are remaining about constant; the changes
in productivity are being brought about by changes in the output
of the stack and not by changes in labor time.
With this preliminary explanation it is now possible to draw con­
clusions from the data for plant No. 9. In 1918 a daily output of
286 tons was accompanied by a man-hour output of 0.283 ton, while
in 1927 the daily output had increased to 404.7 tons and the manhour output to 0.439 ton. In other words, practically the whole in­
24




METHODS OF INCREASING PRODUCTIVITY

25

crease in productivity which took place in this plant was brought
about by increasing the daily output of the stack while the crews
remained the same as before.
Plant No. 13 furnishes an equally good illustration. The decline
in output per man-hour in 1923 indicates the existence of larger labor
crews in that year, but for all other years the extremely close corre­
spondence between the output per stack-day and the output per
man-hour presents a clear case of an increase in productivity being
brought about by increasing the daily output of the stack while
maintaining the labor force constant.
In plant No. 32 there is another example of very close corres­
pondence between changes in productivity and in output per stackday for the period 1917 to 1922. In the last tw~o years of operation
(1923-24) the output per man-hour increased out of all proportion
to the changes in stack-day output, showing that at this time there
must have been some important reductions in the labor crews. The
change which was actually taking place was the substitution of the
8-hour, 3-shift system for the old 12-hour, 2-shift system; in the
reorganization the labor time wras reduced.
The above plants were entirely modern throughout the period for
which data are available. It is much more difficult to find cases of
old hand-filled, sand-cast plants which show an upward trend of
output per stack-day with constant crews. There are numerous
examples of such plants with unchanging labor time, but in the
majority of cases the output per stack-day either varied within
narrow limits or else actually declined. Plant No. 73, howTever,
can be cited as an example of increasing output per stack-day with
practically constant labor time. Here the variations in output per
man-hour are very largely the result of changesin output per stack-day,
except in one year (1923) when labor crews were abnormally low.
The second method of increasing productivity is to cut down the
labor time while maintaining the same output. Plant No. 43 illus­
trates this method. Disregarding the figures on stack-day output
for 1917 and 1921 as not being representative, it is evident that the
daily output of pig iron varied within very narrow limits all through
the period, but the man-hours per ton decreased from 7.585 hours in
1918 to 5.614 hours in 1925. Thus the increased productivity was
brought about by a reduction of the labor crews.
Plant No. 47 is another example. The output per stack-day in 1918
was almost exactly the same as in 1925, the last full year of operation.
But in the meantime the output per man-hour had risen from 0.089
ton to 0.122 ton, an increase which came about through the reduction
in labor time from 11.285 hours per ton to 8.191 hours.
Still another case is Plant No. 48, in which the output per stack-day
at the end of the period was lower than in the beginning, while the
output per man-hour increased from 0.148 ton in 1911 to 0.201 ton
in 1926; this represents a reduction in labor time from 6.773 hours
per ton to 4.985 hours.
Plant No. 57 experienced very little change in output per stack-day
from 1919 to 1926, but the man-hours per ton decreased from 7.696
hours to 4.392 hours. The installation of a skip hoist in 1924 was an
important factor in producing the result.
5421°— 29------- 3




26

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

By far the most common way of increasing productivity is the
combination of both methods. It is not confined to any one class of
plants but may be found under almost all conditions. Plant No. 5
is an example of its operation in a plant with modern equipment.
Each rebuilding or relining produced an increase in output per stackday, but at the same time there was a steady decline in the labor time
required to operate the furnaces. Since the equipment was already
modern this reduction could not have been brought about by the
installation of the major labor-saving machines; it was largely the
result of crew reorganization and labor management.
Another excellent example of the operation of this method in a
modernized plant is shown by plant No. 21, in which the output per
stack-day doubled between 1919 and 1926 while the output per
man-hour was tripled. The labor time was being rigorously cut
down at the same time that the stacks were being enlarged.
Plant No. 22 makes another good case. From 1911 to 1920 the
output per man-hour coincides very closely with the output per
stack-day, but between 1920 and 1922 the rebuilding of the stack
caused an increase of 30 per cent in the daily output, while the manhour output was being doubled. The labor force was thoroughly
reorganized after the depression and many positions were cut off.
This combination method of increasing productivity is also found
among old plants which change over to modem equipment. Plant
No. 2 shows a decline in output per stack-day and some rather
indifferent results in productivity during the period 1914 to 1921,
but when the pig machine was introduced the stack was also enlarged.
The saving of labor by use of the pig machine combined with the
increased output per stack-day resulted in doubling the productivity
between 1921 and 1923.
Plant No. 12 was only partly modern in the pre-war period, and
both the output per man-hour and the output per stack-day remained
fairly constant. The introduction of the pig machine in 1916 caused
an immediate improvement in output per man-hour, and a remodeling
of the stacks four years later raised the putput per stack-day to a
higher level. Since 1920 both man-hour output and stack-day out­
put have increased steadily, the former at a much faster rate than
the latter, thus indicating a progressive reduction in labor time.
Plant No. 27 is a striking example of the point under discussion.
From 1914 to 1921, inclusive, the changes in output per man-hour
and the output per stack-day correspond closely to each other,
indicating little or no change in labor crews. A skip hoist and a pig
machine were installed in 1922, and at the same time the stack was
enlarged. Output per stack-day was increased 50 per cent, and by
1926 the output per man-hour had increased more than that amount.
Other plants which illustrate the point are Nos. 19, 20, and 33.
Enough cases have been cited to show conclusively that the usual
method of increasing productivity in the merchant blast-furnace
industry has been that of installing labor-saving machinery and
methods at the same time that the stack was being enlarged and
technical operating efficiency increased. It is not unusual to find a
continual stepping up of stack-day output while labor crews remain
constant, but it is rarely indeed that a plant increases its productivity
by cutting dow n its labor time while the output per stack-day remains
constant.




27

METHODS OF INCREASING PRODUCTIVITY

In view of the above facts it is not at all surprising that the increase
in productivity for the industry as a whole should exhibit the charac­
teristics of the combination method prevalent among individual
plants. Table 6 shows the total productivity increase for the indus­
try in relation to the increase in output and the reduction in labor
time. While data available for 1915, 1916, and the first six months
of 1927 are published, they represent so few establishments that they
can hardly be considered fairly representative of the whole industry;
therefore, they are ignored in the following discussion of the table:
6 . — Average output per man-hour, output per stack-day, and m an-hours per
stack-day , together with index numbers thereof , by years , 1911 to 1927

T a b le

[Average for 1912=100.0]

Plants for which data on stack-days are available

Year

N u m ­ Output
ber
per manhour. (all
of
N um ­
plants plants)
ber

Average output
per man-hour

Amount

1927 i____________
1926_____________
1925_____________
1924_______ _____ _
1923 ........................
1922..... ......... .........
1921_____________
1920_____________
1919______________
1918______________
1917_____________
1916_____________
1915_ ......................
1914_____________
1913_____________
1912 ____________
1911_____________

21
49
43
49
60
40
36
57
50
48
45
9
10
27
28
27
22

Gross ton
0.300
.296
.285
.244
.213
.232
.178
.157
.144
.131
.150
.147
.159
.160
. 151
.150
.140

21
49
43
49
58
40
34
54
48
44
41
9
10
24
25
22
19

Gross ton
0.300
.296
.285
.244
.213
.232
.179
.157
.143
. 132
.155
. 147
.159
.158
. 155
.159
.143

Index
number

188.5
185.7
178.7
153.2
133.5
145.9
112.1
98.8
89.5
82.8
97.3
92.4
100.0
99.4
97.5
100.0
89.7

Average output
per stack-day

Amount

Gross tons
397.5
369.1
353. 5
327.2
294.9
329.8
287.1
247.5
246.6
225.6
249.8
231.9
252.5
262.3
256. 0
261.4
260.5

Average man-hours
per stack-day

Index
number

Num ber

152.1
141. 2
135.2
125.2
112.8
126. 2
109.8
94.7
94.3
86.3
95.6
88.7
96.6
100. 3
97.9
100.0
99.7

1, 323. 3
1, 247. 2
1, 241.4
1,339. 9
1, 385. 6
1,418. 7
1, 606. 6
1, 571.9
1, 729. 3
1, 708. 7
1,611.3
1, 574. 5
1, 585.0
1, 655. 4
1,648.1
1, 640. 2
1, 823. 4

Index
number

80.7
76.0
75.7
81.7
84.5
86.5
98.0
95.8
105.4
104.2
98.2
96.0
96.6
100.9
100. 5
100.0
111.2

1 Data for 6 months.

The year 1912 is used as a base for the index numbers instead of
1911 for two reasons: (1) It contains many more plants and therefore
is a much more representative year than 1911, and (2) the year 1911
shows a relationship of stack-day output and labor time that is out of
line with all later years, which would have the effect of throwing the
two indexes far apart all during the period 1912 to 1920 when the true
relationship is best indicated by keeping the indexes close together.
In this table it is seen that in the plants for which stack-days are
available output per man-hour changed from 0.159 ton in 1912 to
0.296 ton in 1926, which as shown in the corresponding index number
makes an increase of 85.7 per cent in output per man-hour.
The output per stack-day increased from 261.4 tons in 1912 to
369.1 tons in 1926, which the corresponding index number shows to be
an increase of 41.2 per cent. The man-hours per stack-day in 1912
were 1,640.2. This was reduced to 1,247.2 man-hours in 1926, a
reduction of 24.0 per cent as shown by the index number.
The differences in the two columns on output per man-hour are
negligible as far back as 1917 when the first real difference occurs;
in all pre-war years, 1911 to 1913, the output per man-hour in plants




28

LABOR PRODUCTIVITY— MERCHANT? BLAST FURNACES

that reported stack-days is higher than for all plants, thus indicating
that the plants not furnishing stack-days were somewhat below the
average in productivity. The adjusted figures, however, do not
materially change the general trend of productivity as previously
indicated. The putput per man-hour changed very little between
1912 and 1917, inclusive, but there was a pronounced drop in 1918
and 1919, followed by a rise to pre-war levels in 1920. Since the
latter year the trend has been steadily upward with the exception
of 1923.
The trend of output per stack-day very closely approximates that of
output per man-hour, although it is not so steep in recent years.
Throughout the entire period 1911 to 1920, the output per stack-day
remained about constant in the neighborhood of 250 to 260 tons, ex­
cept in 1918 when the daily output dropped to 225 tons. This was
due largely to the inclusion of a number of small plants in the averages
for that year. Since 1920 the average output per stack-day has in­
creased every year with the exception of 1923.
The data on labor time per stack-day show the extent to which the
labor force has been cut by new machinery and improved methods. The
exceptionally high figure for 1911 is due to the particular plants which
are included in that year. The table indicates that the average daily
man-hours of labor required to operate a blast-furnace plant ranged
from 1,640 to 1,655 hours in the pre-war years 1912-1914. There was
a slight decrease in the average for 1917, but this was followed by sharp
increases in the following years, the high point being reached in 1919
with 1,729 hours of labor per day. This was the highest number
of hours in any year except 1911. To some extent the figures for
1918 and 1919 are due to the particular plants which furnished data
for those years, plants which are not represented in the averages for
the pre-war years. Had these plants been included in 1912, 1913,
and 1914, the man-hours per day in those years would have been
considerably higher. However, the disorganization of labor brought
about by war conditions in 1918 and by the strike in 1919 caused
some inflation of man-hours in those years. The daily man-hours
for 1920 fall so far below the averages for the three previous years that
some explanation must be sought. A check of the particular plants
represented in each year shows that the average for 1920 is heavily
weighted with two types of plants which are not so fully represented
in the previous years. One of these types is the very efficient, highproductivity large plant which requires from 1,000 to 1,200 hours
of labor per stack-day, and the other is the very small low-productivity
plant which on account of its small size does not require more than
1,200 hours of labor per stack-day. A considerable number of
both types of plants are to be found in the 1920 average although
they were missing from the previous years. Since both types are
below the average of the rest of the industry in daily man-hours, the
two together lower the average for 1920 considerably.
From 1921 to 1925 the decline in labor time per stack-day was very
rapid, reflecting the modernization of plants which took place during
that period. Since 1925 labor time has remained about constant.
It is of interest to express the reduction in labor in a different
way. If the man-hours per stack-day decrease, then it is obvious
that a given number of man-hours of labor will operate a stack




METHODS OF INCREASING PRODUCTIVITY

29

for a greater length of time. If 1,640.2 man-hours of labor are
required to operate a stack-day in 1912 and 1,247.2 man-hours are
required in 1926, then there has been a saving of 393 man-hours
of labor per day, which would be available for operating another
stack-day. These 393 man-hours constitute 31.5 per cent of 1,247.2,
which means that the amount of labor required to operate a stack for
100 days in 1912 would have operated the same stack 131.5 days in
1926. It will be noted that this is the reciprocal of the index of manhours per stack-day. Thus, if the reciprocals of these indexes are
calculated, the resulting indexes will show the stack-days which can
be operated with a given number of man-hours.
The chief point of interest, however, is the way in which the three
series changed in relation to each other. Prior to 1918 there is
nothing of importance to note, but in that year the sharp decline
in output per man-hour is seen to be the result of a decline in output
per stack-day, accompanied by an increase in the labor time required
per day. The former resulted from the inclusion in the averages of a
number of small plants missing from previous years; the latter is the
result of a general increase in the number of men per plant. In 1919
the output per man-hour rose in response to an increase in output
per stack-day, with labor time increasing slightly over the average
for 1918, but in 1920 the case was exactly the reverse— output per
stack-day remained constant, but the output per man-hour increased
in proportion to the reduction in labor time. Since 1920 the stackday output has risen and the labor time has declined. In only two
years were the trends reversed. In 1921 the hours of labor time failed
to decline as output per stack-day increased, while in 1923 the output
per stack-day decreased while the labor time declined as usual.
In both years, however, the output per stack-day proved to be a
more important factor in determining productivity than the labor
time, for in 1921 output per man-hour increased in response to the
change in stack-day output, while in 1923 the output per man-hour
declined along with the stack-day output; the changes in labor
time were more than counterbalanced by the influence of the daily
output of the stack.
RELATIVE INFLUENCE OF OUTPUT PER STACK-DAY AND MAN-HOURS
OF LABOR TIME ON PRODUCTIVITY

It is clear that the increased productivity in the merchant blast­
furnace industry has been brought about by. an increase in the
average output per stack-day and by a reduction in the average
man-hours of labor per stack-day. The extent of the change in
output per man-hour is the sum of the changes which have taken
place in these two factors, as represented by the index numbers in
Table 6.
Each series of index numbers measures the effect upon produc­
tivity of a fairly distinct set of active factors operating upon produc­
tivity independently; that is, changes in output per stack-day, and
consequently in output per man-hour, are determined by one set of
factors, while changes in labor time per day, with a corresponding
effect on productivity, are determined by quite a different set. These
sets of factors while complementary are separate and distinct.
The pig-casting machine is a clear illustration of the distinct and
independent character of factors operating upon productivity through




30

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

changes in labor time per day. This machine is introduced for the
purpose of saving labor, which it does by eliminating the sand cutters
and iron carriers working around the casting beds. To the extent
that the pig machine reduces the labor time per day it causes an
increased output per man-hour; on the other hand, the machine is
completely dissociated from the furnace itself and has little influence
upon the daily production of the furnace. It can not improve the
quality of the iron, nor cause more iron to flow from the hearth,
nor in any way affect the smelting process. It merely handles
whatever output the furnace makes, and unless changes are made in
furnace operation independently the output per stack-day remains
the same as before the installation of the pig machine.
The other machines saving common labor have the same effect.
The skip hoist with larry car and bins has had a most important
influence on the number of men required in charging the stock into
the furnace and therefore upon productivity. While directly em­
ployed in filling the furnace, this auxiliary equipment has only an
indirect connection with the smelting process or the daily furnace
output. In the main, automatic filling affects productivity through
a reduction in labor time, not through increasing output; although,
of course, it must be pointed out that the use of the skip hoist has
made possible the construction of larger stacks than could ever have
been filled by hand labor. Other examples may be cited, such as the
locomotive cranes in the yard, the ore bridge, motor trucks which
displace horse carts, etc. Of the same character is the direct reduc­
tion in the number of men required for operating existing equipment.
All these are methods used in eliminating a certain amount of labor
time, and they cause an increase in productivity as a result of that
elimination. None of them have any direct relation to the produc­
tion of the furnace or to productivity as affected by stack-day output.
On the other hand, the increased daily production of a blast
furnace ordinarily has comparatively little effect upon the labor
time required for operating the furnace plant. When a stack is
“ down” for relining it may be rebuilt with different lines and enlarged
cubical contents. The rebuilt stack may be capable of producing
50 per cent more pig iron per day than the old one, but the effect on
the labor crew may be comparatively slight. Although larger
quantities of materials must be charged into the furnace the ore
bridge, trestle, stockhouse, and skip do not require more men, but
merely more continuous operation or larger loads. Likewise, exactly
the same crews will'operate the enlarged furnace. Whatever change
in practice is required by the larger stack is a matter of technical
knowledge not of human brawn. Although more metal is cast from
the furnace a larger crew is not required in the cast house or in haul­
ing larger ladles to the pig-casting machine, while the casting is done
by the same number of men per turn as before. The power, pump­
ing, and blowing machinery will be operated by unchanged crews.
In the yard there may be some slight increase in the labor required
to handle the larger amounts of pig iron, and the steadier operation
of machinery may necessitate some increase in maintenance and
mechanical labor. However, it is obvious that an increase of 50
per cent in output per stack-day may have a relatively small effect
on the labor time per day.




METHODS OF INCREASING PRODUCTIVITY

31

It is evident that changes in output per stack-day and in labor
time per day represent two distinct ways in which productivity may
be changed. Daily furnace output is increased by purely technical
factors such as a change in the lines of the stack, the use of better
raw materials, the employment of higher blast pressure rather than
by employing more men, etc. In an average plant a small amount of
additional indirect or auxiliary labor would be necessary to handle
the additional product, but this increase in labor would not be in any
way proportional to the increase in tonnage.
The reduction of labor time, fully as useful in increasing produc*tivity as an increase in output, is attained by methods quite distinct
from those associated with greater furnace output. Labor-saving
machines, the shorter workday, and the combination or elimination
of jobs are changes which neither increase nor interfere with the daily
production of iron.
There is only one class of plants in which an increase in daily output
has a marked effect upon the crew. These are the old hand-filled,
sand-cast plants. Heavier production will require, for example, more
fillers’ helpers on the charging side and more iron carriers on the
casting side, with perhaps some additional labor in the iron yard and
in materials unloading. In fact, it is just this direct relationship in
such plants between volume of production and amount of labor re­
quired which brought about the introduction of labor-saving machin­
ery whenever the daily output of the stack was greatly increased. It
is the modernization of a blast furnace plant which brings about the
fairly complete segregation of the two sets of factors; under hand
methods of operation labor time is tied very closely to production.
However, these hand-filled, sand-cast plants with old equipment do
not necessitate any modification in the previous general conclusion
that for the industry as a whole the increase in stack-day output is
comparatively independent of the reductions in labor time. From
Table A, page 71, there have been selected 12 plants which remained
hand-filled and sand-cast down to 1927, or until they ceased operating.
These are plants Nos. 15, 41, 48, 60, 61, 65, 69, 70, 71, 73, 75, and 77.
There are other hand-filled, sand-cast plants, but they do not cover a
sufficient span of years to give evidence of a trend. Each of the above
plants furnished data over a period of at least four years. These are
the plants in which any increased volume of production would be
expected to result in an increase in labor time, with very minor changes
in output per man-hour. But the facts are that all these furnaces
are very small, nine being under 200 tons per day all the time while
the other three occasionally reached 300 tons; and in practically none
of them is there any pronounced upward trend of output per stack-day.
Plant No. 15 shows a large variation in output per stack-day, but
the high record in 1927 represents one-furnace operation, wThile the
older, smaller furnace was being rebuilt. The low record of about
210 tons per day in 1918 should be compared with the record of 250.5
tons in 1926 with full two-furnace operation in both years. The in­
creased output represents improvements in operating efficiency rather
than increases in the size of the stacks.
Plant No. 41, like No. 15, furnishes evidence of low operating effi­
ciency in 1918, when output per stack-day was 260.6 tons. In con­
trast to that year, there was an exceptionally high output in 1925,
329.7 tons, but this was due to a considerable use of scrap in cleaning




32

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

up the plant for a final shutdown. This stack rated at about 290
tons per day throughout the period of its operation.
Plant No. 48, throughout the entire period from 1911 to 1926,
ranged very closely around 250 tons per day. The relining in 1917-18
increased the production to 300 tons in the latter year, but a relining
in 1923 brought a reduced capacity again.
All the other nine plants are very small; a few of them show slight
increases in output per stack-day over the period, but the great
majority range within quite narrow limits.
The conclusion is further strengthened by data for 12 hand-filled,
sand-cast plants which were partly or wholly modernized some time
during the period. Tbese are plants Nos. 14, 18, 19, 27, 28, 39, 45,
52, 53, 54, 57, and 66. Three of these, Nos. 14, 19, and 28, had quite
large stacks in the period before mechanization took place; No. 28
made a record of more than 400 tons per day. But considering the
group as a whole, it is evident that the output per stack-day was
increased only slightly during the period of hand filling and sand
casting; on the other hand the general increase in stack-day output
following modernization is unmistakable.
The final conclusion to be drawn is that to a very considerable
extent at least the hand-filled, sand-cast plants, in which the changes
in production would be likely to produce corresponding changes in
man-hours of labor time, did not increase their production. It is
probable that the close connection between volume of production
and labor time in these plants is in itself a deterrent to any pronounced
increase in stack size. So far as the averages for the industry are
concerned, the general conclusions set forth above still hold; that is,
increases in output per stack-day and reductions in labor time affect
productivity separately and independently. The only group of
plants which forms an exception to the principle did not experience
any marked increase in stack-day output.
A comparison of the two indexes on output per stack-day and manhours per stack-day indicates that in recent years the increase in
output per stack-day has had a somewhat greater influence on pro­
ductivity than has reduction in the labor force. The data for 1927
need not be considered, since they cover only half a year and a much
smaller number of plants. But since 1920 the changing daily output
of the stack has been of more importance in determining the changes
in the final productivity average. It would appear from the data for
the last three years that the increase in productivity due to labor
saving and crew reduction has come to a stop. The majority of exist­
ing plants are now fairly well modernized, and further important re­
ductions in labor time by means of pig machines, skip hoists, and
cranes appear unlikely. However, the output per stack-day con­
tinues to increase steadily, and this is causing corresponding increases
in productivity.
INCREASE IN OUTPUT PER STACK-DAY

The importance of increased daily furnace output in relation to
productivity has been discussed fully, and it has been shown that
recent progress has been by means of greater output per stack-day
rather than through reduction of crews. It has further been shown
that output per stack-day summarizes mathematically the combined
effect of such changes in operation and in equipment as are calculated



METHODS OF INCREASING PRODUCTIVITY

33

to increase production. This section will be devoted to a discussion
of the more important ways in which output per stack-day has been
increased.
Unquestionably the most important single factor in the increase in
daily production per furnace has been the change in furnace dimen­
sions— that is, the enlargement of the stacks and the modification of
the relative dimensions of the different sections of the stack. Up to
the eighties the typical blast furnace had a bosh halfway up the stack
and a hearth perhaps only half as wide as the bosh. Some of the larg­
est stacks in the entire iron industry %ere almost as tall as those of
to-day, and the boshes were almost as wide, but the width of the
hearth, which limits the furnace output, was usually 10 feet or less.
This earlier construction originated during the period when charcoal
and anthracite were the fuels used in smelting. With the introduc­
tion of coke, heavier burdens could be upheld in the stacks and
greater blast pressure was not only made possible by the more porous
mix but was actually required in smelting the fine Mesabi ores. Since
this period the industry has witnessed a steady and consistent devel­
opment in furnace lines. The stacks have been built with wider and
wider sections; boshes have been lowered, and hearths have been
widened until they almost approximate the boshes in diameter as the
lines of the entire crucible are made more nearly vertical. It is not
unusual now to find hearths of 18 to 20 feet diameter, while there are
a few even wider than 20 feet. The purpose of furnace designers is to
bring about the most rapid movement of material through the stack
without impairing the chemical efficiency of the smelting process.
This means that the lines of the furnace itself must offer the least
possible resistance to the flow of material.
By far the most important determinant of output per stack-day is,
of course, the size of the stack or stacks. The size of a stack can best
be expressed in terms of the “ furnace volume,” , which is measured
from the bottom of the hearth upward to the bottom of the closed
bell, representing the total interior capacity of the stack in cubic feet.
This is the figure which is used in this bulletin in measuring the size
of the blast furnaces. Ideally, a more restricted figure for actual
“ working volume” should be used if greatest accuracy is desired in
comparing furnaces. Working volume is the smelting zone in which
actual reduction of the ores takes place. It is measured from the top
of the column of stocked materials (usually about 2 feet below the
bottom of the closed bell) to the center line of the tuyeres. This
excludes the idle open space at the top of stack which is not an effec­
tive part of furnace volume and the cylindrical section of the hearth
below the tuyere line in which the molten metal and slag accumulates
below the smelting zone. The bureau has not been able to obtain
figures for working volume from a sufficient number of plants to make
possible a significant comparison between plants, so the closely
analogous figure for total furnace volume has been used instead.
Table 7 shows the relationship between output per stack-day and
size of stack for all plants furnishing data on both points.




34
T a b le

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES
7 .—

Average output per stack-day, together with fu rn ace volume , by plants ,
1926

Plant
num­
ber

Output
per
stackday

Furnace
volume
(in thou­
sands of
cubic feet)

Plant
num­
ber

Output
per
stackday

Furnace
volume
(in thou­
sands of
cubic feet)

Plant
num­
ber

Output
per
stackday

Furnace
volume
(in thou­
sands of
cubic feet)

1

2

3

1

2

3

1

3

3

3
1
4
13
5
21
17
28
34
19
56
37
12
7
16

Gross tons
648. 7
617.0
527. 3
520.5
506. 2
486.2
474.6
454.4
442.7
432.5
411.0
401.0
396.7
392.8
392.3

Over 24
Over 24
Over 24
18 to 21
18 to 21
18 to 21
15 to 18
15 to 18
18 to 21
15 to 18
21 to 24
Over 24
12 to 15
15 to 18
18 to 21

22
9
20
35
25
26
27
6
30
2
36
41
33
32
40

Gross tons
386.0
380. 9
378.0
370.0
368.3
366.1
3G0. 5
359.1
354.6
345.6
334.9
329.7
325. 0
323.1
317.9

18 to 21
12 to 15
15 to 18
15 to 18
12 to 15
15 to 18
21 to 24
18 to 21
15 to 18
15 to 18
12 to 15
12 to 15
9 to 12
15 to 18
15 to 18

14
38
45
39
58
15
51
48
52
18
43
49
31
11
73

Gross tons
300.8
299.9
298. 2
278.2
261. 0
250. 5
248.3
247. 0
242.1
233.1
220.8
207.6
203.7
193. 0
119.7

15 to 18
12 to 15
12 to 15
12 to 15
12 to 15
15 to 18
12 to 15
9 to 12
15 to 18
12 to 15
12 to 15
9 to 12
12 to 15
12 to 15
9 to 12

Columns 1 and 2 are self-explanatory, and column 3 shows the
total operated furnace volume in thousands of cubic feet of the
stack or stacks in each plant. In the case of plants with more than
one stack the furnace volumes are averaged, the volume of each
being weighted according to the number of days each stack operated
during the year. Thus, the figures show actual operated volume
which may not be the same as capacity volume in plants having
more than one stack in operation; stacks which were idle throughout
the year do not appear in the average at all. For the most part the
records in Table 7 cover the year 1926, but in the case of plants
which did not operate in 1926 the record is for the last year of opera­
tion, even though*this may have been as far back as 1923. The
particular year is not as important as the number of plants which
can be brought into the table.
The output per stack-day is very largely determined by the size
of the stack. The three largest stacks have the highest average
daily output, while the smallest stack has the lowest output. Down
through the list the relationship between size and daily output con­
tinues very close.
However, there are some notable exceptions to the general rule.
Three plants with medium sized stacks, Nos. 17, 28, and 19, have a
much higher daily output than many larger stacks. Plant No. 12,
whose stacks are relatively small, shows an average daily output
which compares favorably with that of stacks twice the size. Plant
No. 9 also has a very high output for stacks of that size. The wide
range of output which exists between stacks of the same size is best
shown by the class of stacks between 12,000 and 15,000 cubic feet
furnace volume. The highest daily output of a plant in this class
was 396.7 tons, while the lowest was 193 tons. In the class of stacks
between 15,000 and 18,000 cubic feet, the highest output was 474.6
tons and the lowest 242.1 tons. There are sufficient data in Table 7
to constitute clear evidence of the fact that while output per stackday is very largely due to the size of the stack, nevertheless there
are other factors which have some influence in determining the final




35

METHODS OF INCREASING PRODUCTIVITY

output per day. The more important of these other factors are the
shape of the stack, the quality of materials, and smelting efficiency.
For the purposes of this study it is not necessary to make any
detailed analysis of the influence of each of the above factors on
output per stack-day. It is of interest, however, to rate the blast
furnaces according to their daily output, independent of their size.
Such a comparison supplements the data in Table 7 by summarizing
the influence of all factors, except size, on the daily output. The
element of size of the stack is eliminated by using a uniform unit
of volume, arbitrarily selected as 100 cubic feet of furnace volume,
hereafter called the “ volume unit.” The total daily output of each
plant is divided by the number of volume units contained in the
operated stack or stacks; or, to put it another way, the output per
stack-day shown in Table 7, column 2, is divided by the number of
cubic feet of average furnace volume shown in column 3, and the
result is multiplied by 100. It would be much simpler to use 1
cubic foot as a volume unit, but the result has so many decimal
places that the larger unit is necessary in order to get a significant
figure.
Table 8 shows the plants with a given output per 100 cubic feet of
furnace volume classified according to size. The first column shows
the output per stack-day per 100 cubic feet of furnace volume; the
second column shows the number of plants in each group; the re­
maining columns show the classification of plants according to size.
T a b le 8 . — N um ber o f plants distributed according to their fu rn a ce volume and to

their output in a stack-day, 1926

Gross tons of output per stackday per 100 cubic feet of furnace
volume

3.2
.......................... ...............
3.1. _
_______________________
2.9_________________________________
2.8
___
2.7_____
.
___________
2.6_________________________________
2.5_
_ ________
2.4_________________________________
_________
2.3
.
2.2_________________________________
2.1.
.
. _____
2.0
_
. .
1.9_________________________________
1.8
_______________________
1.7. ........................................... ...........
1.6___________________ _________ ____
1.5.________________________________
1.3.............. ....... .................... .............




Number of plants having an average operated furnace volume
of each specified number of cubic feet
Total
num­
ber of
112,000 and 15,000 and 18,000 and 21,000 and
plants Less than
24,000
under
under
under
under
12,000
and over
18,000
15,000
21,000
24,000

1
1
1
2
1
\
5
1
3
5
4
3
4
1
3
3
1

1
1

1

1
2
1
2
1
1

i

1
1
1
1
1
1
2

i

1

2

2
1
1
1
2
1
1

1

1
1

3
1
1
1
1

2
1

36

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

This table shows the variation in output of plants of the same size.
In the class of plants with a furnace volume less than 12,000 cubic
feet one had an average daily output of 3.1 tons per volume unit,
while at the other extreme was a plant with only 1.3 tons. In the
12,000 to 15,000 class the plants ranged from a high of 3.2 tons to a
low of 1.5. As the plants increase in size the range narrows con
siderably, a point which required some further analysis. It is signifi
cant that the best output records were made by small or medium­
sized plants. The best daily output per 100 cubic feet of furnace
volume was made by a plant with an average operated stack volume
between 12,000 and 15,000 cubic feet ; the next best output came from
a stack of less than 12,000 cubic feet volume. Six of the eleven best
plants have stacks averaging less than 15,000 cubic feet, w^hile three
others are between 15,000 and 18,000 cubic feet. On the other hand
the best output record among the plants with large stacks, that is, 2.5
tons per 100 cubic feet, ranks below the records of 11 smaller plants.
These illustrations are sufficient to indicate that furnace perform­
ance is determined by other factors than mere size of stack. It
seems clear that stacks of medium size have a distinct advantage as
a smelter over the extremely large stack. No matter how efficiently
the large stacks are run, they can not turn out pig iron proportionately
to their size in comparison with efficiently operated stacks having a
volume of 12,000 to 18,000 cubic feet. This suggests a nice problem
in blast-furnace operation. There is a very fine balance between
various considerations in determining operating policy with reference
to high daily output. While at first glance (Table 7) it would appear
that the spectacular contrast in daily yield furnishes conclusive evi­
dence that the large furnace has the advantage, this is by no means
clearly the case, particularly among merchant furnaces which can
not be driven for long periods at high speed in the uninterriputed
production of a single grade of iron. It must be remembered that
large furnaces and hard driving necessarily go together. Increased
stack size beyond a certain limit appears to make possible greater
output only at the expense of good control of materials. Taking the
industry as a whole with the technical knowledge and skill available
at any given time, there is doubtless always some point beyond
which it is bad economy to increase output per stack-day— a point
at w^hich the advantages of large-furnace tonnage are counterbalanced
by high consumption of materials and greater hazards of hard driv­
ing. This point is at a lower level for merchant blast furnaces than
for steel-works stacks, because the former must frequently shift from
one grade of iron to another instead of driving steadily ahead on basic
iron.
The daily output per 100 cubic feet of furnace volume is, of course,
a summary figure which shows the influence on furnace output of a
large number of operating factors such as quality of materials, effi­
ciency of smelting, etc. In order to complete the picture the more
important of these are shown in Table 9.




37

METHODS OF INCREASING PRODUCTIVITY

T a b l e 9 .— Average output per stack-day, average consum ption o f materials, and

average volume o f air blown, by plants, 1926
Average consumption of—

N o.
N o.
N o.
N o.
N o.
N o.
N o.
No.
No.
No.
No.
N o.
No.
N o.
N o.
No.
N o.
No.
No.
N o.
No.
No.
No.
No.
N o.
No.
No.
No.
N o.
N o.
No.
No.
No.
No.
No.
No.
No.
No.
No.
N o.
No.
No.
N o.

Plant

Average
output per
stack-day

1

2

5 ____ _____ ____________________________
41 i________________________________ _____
3 ________________________________ _____
1 2 ____ ___________________________ _____
34 _____________ ______ ___________ _____
17 _____________ _________________ ______
56
______________ ____________________
6 ____ _________ ________________________
28____________ ________ __________________
13.____________ _________________________
25 _______________ _____________________
3 7 ____________________________________
32 3_____________________________________
4____ ___________________________________
2 1 ..____ _______ _____ ___________________
7 _______________________________________
35 4~ - _________________________________
1________________________________________
51 1__________
_______________________
45 ............ ............. ........... ........................... ...
3 6 _______________________
___________
19 _________
22 _____________
27 .................... ...
20 ................ ... .
26 _____________
9 ______________
.
14 .............. .. . . . .
.
. _
33 . . .
16_________ ___________________ _______ _ .
2______________________________________ .
52_____ _____________________ _________
___________________ __________
No. 3 9_____
...
4 8 ___________________________ __ _
11 3_______________________________
30___________________________________
31_________________
15._____ _________________
58____ _____ ________________________
18________________________
38______ _______________________
40___________________________________
49 4____ _____ ____________
43 L___...................... .........................
1 Data for 1925.

2 ]\T0 data.

Gross tons
506.2
329.7
648.7
396.7
442.7
474.6
411.3
359.1
454.4
520.5
368.3
401.3
323.1
527.3
486. 2
392.8
370.0
617.0
248.3
298.2
334.9
432.6
386.0
360.5
378.0
366.1
380.9
300.8
325.0
392.3
345.6
242.1
278.2
247.0
193.0
354.6
203. 7
250. 5
261.0
233.1
299.9
317.9
207.6
220.8

Ore per
Coke per
ton of iron ton of iron
produced
produced
4

3

Pounds
1,663
1,720
1, 792
1,820
1,898
1,901
1,922
1,952
1,985
1,990
2,008
2,014
2,035
2,040
2,040
2, 042
2,042
2,070
2.076
2.076
2,084
2,110
2,120
2,124
2,167
2,214
2, 218
2,218
2, 262
2, 282
2,315
2,326
2, 331
2, 348
2, 498
2,680
2, 804
2,930
3, 050
3,072
3,082
3,143
3, 335
3,414

Pounds
3,470
4,081
3,821
4,090
3,518
3, 860
4, 278
3,943
3, 768
4,467
3,909
3,544
2,197
4,140
3,922
3,618
4,137
4,377
3,804
3,947
3, 575
4,303
3,897
2, 858
3,147
4,252
4,316
4,260
4,126
4,070
4,202
(2)
2,802
4,182
3, 954
5, 598
5,139
5, 772
5, 092
5, 564
4, 525
4,312
4, 722
4, 661

3 Data for 1924.

Average
volume of
Scrap per
air blown
ton of iron per minute
produced
5

6

Pounds
475
(2)
437
(2 )
58
325
121
23
421
(2)
(2)
349
1, 552
0)
234
372
40
132
(2)

392
241
325
757
851
278

(2)
259
73
165
(2)
(2)

916
289
432

2
388
9

Cubic fee *
33,954
(2)
46, 859
28,758
36, 000
35.000
(4)
31,903
36.000
38, 000
48,000
32, 000
(2)
(2)
30, 000
34, 747
(2)
44, 096
(2)
32, 000
25.000
36, 866
34, 785
38.000
34, 735
32, 501
31,458
33,850
25,939
36, 713
(2)
24.000
32. 000
32, 700
(2)
(2)
(2)
34.000
31, 500
34, 000
40, 000
45,000
(2)
(2)

4 Data for 1923.

The first two columns of the table show the individual plants and
their output per stack-day. These plants are rated according to
the average consumption of coke as shown in column 3, since this is
the best single index of smelting efficiency. The next two columns
show the average consumption of iron ore and of scrap, but it has
not been possible to subdivide the metallic charge in all plants.
Theoretically, column 4 shows only the amount of iron ore proper,
while column 5 shows the amount of scrap, mill cinder, scale, bor­
ings, and other ore equivalents; but where no data are available on
the amount of scrap or ore equivalents, the figures for the whole
metallic charge are shown in column 4. For present purposes mill




38

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

cinder, scale, turnings, and other such ore equivalents 1 are listed in
column 5 as scrap, although their iron content is considerably lower
than that of scrap. The latter ordinarily yields from 90 to 95 per
cent iron, which means that it makes pig iron at the rate of ton for
ton; pig iron runs about 94 per cent iron. But the other ore equiva­
lents, such as cinder, scale, etc., usually range from about 65 to 90
per cent iron, and so rank somewhere in between scrap and ore in
iron content. Column 6 of Table 9 shows the average amount of
the blast in cubic feet of air blown per minute.
In a stack of a given size the daily output of pig iron is determined
by the quality of the raw material charged and by the speed at which
these materials are smelted. Efficiency of operation consists in the
establishment and maintenance of the most economical balance be­
tween these factors. As far as ore and ore equivalents are concerned
the main problem is their bulk; at a given rate of driving the mate­
rial can pass through the stack only about so fast, and therefore the
amount of pig iron produced will depend upon the amount of iron
in a given volume of iron-bearing material. On the other hand, the
smelting process can be speeded up by blowing a stronger blast, but
beyond a certain point this causes a heavier consumption of coke
per ton of product and thus becomes uneconomical.
Plant No. 5 has a remarkable record for coke consumption, only
1,663 pounds per ton of pig iron produced, but it is clear that this
record is at least partly due to the large amount of scrap charged.
This is mostly real scrap, which consumes a very small amount of
coke in passing through the stack. Therefore nearly all the 1,663
pounds of coke consumed at this plant were used in smelting the
3,470 pounds of iron ore.
Plant No. 41 charged some scale and mill cinder, but the exact
amount was not reported, so it is impossible to show the extent to
which coke consumption was affected by their use. The scrap charge
in plant No. 3 consisted of borings and turnings only, consequently
the saving in iron ore proper was not so great as in plant No. 5, and
the amount of coke required was considerably larger. Plant No.
12 also made an exceptionally good record of coke per ton of product.
Here, too, cinder and scale were charged, but the exact amounts were
not reported. It is important to note that the amount of blast blown
in plant No. 12 is among the lowest in the whole list of plants. The
good record in plant No. 34 can be ascribed to the very rich ore
charged, for the amount of scrap used was quite small.
The above figures are in sharp contrast with those at the other
end of the list, where the last nine plants all consumed more than
2,600 pounds of coke per ton of product. One important cause of
this is found in the ore consumption figures. All these plants have
a total metallic charge greater than 4,500 pounds and five of them
run above 5,000 pounds. It is clear that the daily output in these
plants is much smaller than it is in plants of the same size which are
using only 4,000 pounds of ore and 2,000 pounds of coke per ton of
product. The plants with heavy ore and coke consumption appar­
ently use a somewhat stronger blast than the others, as is shown by
1 It must be noted that flue dust and remelt scrap are never counted as part of the metallic charge.
Flue dust consists of fine ore particles which are blown out of the stack with the blast furnace gas and which
are caught in the dust catchers. Remelt consists of runner and ladle scrap which is,formed when the cast
is being made. Both the flue dust and the scrap are charged back into the stack again, but they have
already been counted once and must not be counted again.




METHODS OF INCREASING PRODUCTIVITY

39

the records for plants Nos. 15, 18, 38, and 40. In general, the amount
of blast varies directly with the size of the stack, but the use of scrap
and rich ore makes possible a lighter blast, while lean ores require
a much heavier blast.
To understand the importance of materials consumption more
clearly and to see how it is linked up with output per stack-day and
productivity over a period,of time, it is necessary to turn to the rec­
ords of individual blast-furnace plants (Table A), where all the fac­
tors which enter into the changes are shown in detail. During the
period covered by this study certain plants show remarkable improve­
ment in productivity largely as a result of better smelting efficiency
and the use of better materials. Plant No. 17 was taken over by
new management prior to 1922, and within four and one-half years
coke requirements were reduced 25 per cent. There has been a mod­
erate increase in the use of scrap, but the chief reason for the improve­
ment can be found in the richer ore charged each year. This im­
provement expressed itself in higher output per stack-day and
ultimately in productivity.
The four-year record of plant No. 23 is a striking illustration of
improved operation. With a new furnace in 1923 this plant has
since been operated continuously with a remarkable improvement in
yield, decreasing ore consumption from 4,113 pounds to 3,212 pounds
per ton as the result of an average charge of about 500 pounds of
scrap per ton of iron, beginning in 1924. Coke consumption fell
from 2,200 pounds to 1,800 pounds per ton, while flux shows a corre­
sponding reduction from about 1,200 pounds to 900 pounds per ton.
This improvement is paralleled by increased output per da}^ from
253 to 377 tons without any change in equipment.
Steady progress in coke practice is shown in the record of plant
No. 12, which exhibits a reduction in coke per ton of iron from 2,425
pounds per ton in 1912 to about 1,800 pounds in 1,926. At this plant
special attention has been given to the quality of the coke used, both
with reference to its physical characteristics and its fixed carbon
content. The management at this plant considers coke consumption
one of the most important factors in furnace efficiency and has worked
out a formula for determining the ideal consumption of standard coke
under the best operating practice. This plant has an output per
stack-day 20 per cent larger than the next best furnace of its size
in the country and a much larger output than many furnaces with
volumes from 5,000 to 10,000 feet greater.
The influence of greatly improved smelting efficiency in the case of
plant No. 3 has been very important though obscured by other factors
such as rebuilding and enlarging of furnaces, etc. Reduction in coke
from 2,400 pounds to 1,800 pounds per ton of iron tallies closely with
the improvement in plant No. 12, while an increased use of scrap
since 1922 has contributed to better yield. Flux consumption shows
a remarkable reduction from 1,200 pounds to 750 pounds per ton of
iron. Reference to the history of this plant show s remarkable increase
in furnace output, while productivity has increased at a still faster
rate over the entire period
Plant No. 5 shows a remarkable improvement in coke practice, to
which the consumption of from 350 to 500 pounds of scrap per ton
of iron has contributed. This lavish use of scrap has also brought
about a shrinkage in the flux used from 1,100 to 800 pounds per ton




40

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

and in ore from 4,621 to 3,576 pounds per ton over a period of eight
years.
A marked improvement in yield and coke consumption in the case
of plant No. 21 is found to account largely for improvement in furnace
output and productivity. Coke requirements have been cut about
400 pounds per ton, partly due to the increased use of scrap.
In one plant, No. 15, there appears a cl^ar case of improved output
per stack-day as a result of better operation. By 1926 coke consump­
tion per ton of iron had been reduced 400 pounds below the high
figure in 1919, and in 1927 an additional 300 pounds was clipped from
this record. The great decrease in the use of flux has been due to a
change in the mixture of the ores, a larger proportion of self-fluxing
ores being used in recent years. No major labor-saving devices have
been introduced and there has been no important change in the size
of the furnaces. Although production has been concentrated some­
what more steadily in the larger of the two stacks, it may be said
that the change in productivity, almost entirely due to greater stackday output, has been ultimately due to better smelting efficiency and
richer ores.
Plant No. 43 furnishes an excellent illustration of the use of mixed
ores in the South. Data for 1917 should be disregarded in making
comparisons, for they represent the operation of the old furnace.
Since 1917 the furnace has been relined only once and then without
change in size. Output per stack-day has fluctuated widely, showing
no clear trend in any direction but following the variations in the
amount of flux used. Daily production is above normal when flux
consumption is high and below normal when flux consumption is low.
This variation in the use of flux furnished a clue to the variations in
stack-day output, for the amount of flux used depends upon the
proportion of the two kinds of ore charged. Low flux consumption
indicated the use of large proportion of the leaner self-fluxing ores,
while high flux consumption in all recent years but one shows the
presence in the charge of the much larger proportion of the richer
ores which are not self-fluxing. This change in the quality of the
ore, of course, influences very markedly the output per stack-day.
It is noticeable that the amount of coke required also varies in direct
relation to the changing mixture of the ores. Plants in the Birming­
ham district of the South always have this possibility of mixing ores
in such a way as to get the best possible results in smelting efficiency.
While output per stack-day has shown very little increase over this
period, productivity has shown a pronounced upward trend, due to
the reduction in labor crews which took place.
New management in 1920 at plant No. 7 brought about rapid
improvement in operation as evidenced in the reduction in ore con­
sumption per ton of iron from 4,450 pounds to 3,618 pounds while
scrap consumption increased from about 20 pounds to over 370 pounds
per ton, coke requirements falling from 2,400 pounds to about 2,000
pounds per ton of iron, and flux from over 1,200 pounds to less than
1,000 pounds.
Further analysis of changes in consumption of materials for certain
plants with long histories may be found in Appendix 2, page 116.
In conclusion, it is clear that output per stack-day is largely de­
termined by the size of the stack, and consequently the increased
daily output in the industry in recent years has been due mostly to




METHODS OF INCREASING PRODUCTIVITY

the enlargement of the stacks. In addition, however, stack-day out­
put has been influenced to some extent by changes in materials and
methods of operation. The most important of these changes has
been the rapid growth in the use of scrap, and this together with the
increase in stack size should account for nearly 90 per cent of the
changes in output per stack-day. The remainder is mostly a matter
of the efficiency of operation through the use of better coke, a better
adjusted blast, and so on. However, while individual plants may
have made some remarkable records along this line and thus expanded
the daily output of the stack considerably beyond the average for its
size as far as the merchant industry as a whole is concerned, efficiency
of operation by the management has been of secondary importance
in increasing the output per stack-day.
REDUCTION IN LABOR TIME
MEANS EMPLOYED TO REDUCE LABOR TIME IN INDIVIDUAL ESTABLISH­
MENTS

The second group of factors influencing productivity are those
which affect the amount of labor necessary to operate the blast
furnace.
The number of men required to operate a one-stack blast-furnace
plant varies widely; one northern plant operates regularly on a
crew of less than 90 men, while there is one southern plant which
employs almost exactly twice that many men. However, because
of the varying conditions with reference to layout, equipment, and
so on, it is difficult to make any very detailed comparisons between
plants. But in any one plant the changes in the labor force can be
definitely related to the changes in operation and equipment. In
general, the factors which have been responsible for reducing the
number of men required to operate a blast-furnace plant may be
summarized as follows:2
1. Joint or integrated operation, either of several stacks in one
plant or of a blast furnace in connection with a coke plant or other
manufacturing process.
2. Introduction of machinery, particularly the pig-casting machine,
the skip hoist and its auxiliary equipment, and the power cranes,
both locomotive and electric.
3. The reorganization of the crew, particularly that which took
place as a result of the change from the 12-hour to the 8-hour day.
Joint operation usually makes possible a considerable saving in
indirect or auxiliary labor, especially in repair labor, yard labor, and
transportation labor. The single isolated blast furnace must carry
men for certain occupations even though it is difficult to keep them
busy all the time; it must have a sufficiently large mechanical crew
to take care of all the ordinary repairs— there must be at least one
blacksmith, a carpenter, a welder, a master mechanic, etc. Like­
wise, the single-furnace plant requires a yard crew sufficiently large
to meet the needs of the plant in the rush periods, though it is some­
times quite a problem to keep all these men busy during the whole
day. It is not at all unusual to find the yard railway crews waiting
an hour for the cinder run. On the other hand, if the plant is operat­
ing more than one stack, or if there is a coke plant operated in con­
* See ch. 3, p. 20.

5421°— 29------ 4



42

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

junction with the furnace, the indirect labor is spread over more
continuous operation. In handling materials, an ore bridge and
unloading equipment can serve two or more stacks as well as one;
casting machines can be kept busy more continuously; pumping,
power, and blowing equipment can be better and more cheaply
operated, while floating labor crews can handle maintenance and
certain phases of operations to advantage with fewer man-hours per
furnace than in a single-stack plant.
This is illustrated by a number of individual plant histories.
Plant 15 (p. 78) shows very clearly for the period 1922 to 1927 the
effect of single-furnace and double-furnace operation. The best
productivity record was attained in 1925 and 1926, when there was
full two-furnace operation. The full significance of the figures,
however, becomes evident only when the output of the furnace
crew labor is compared with the output of the “ all other” labor.
Until 1927 there was little change in the productivity of the furnace
crew labor, regardless of whether one stack or both stacks were
operating, showing that there was no saving in this type of labor
in two-stack operation. But there was a marked change in the
productivity of “ all other” labor. It required 3.512 man-hours of
“ all other” labor to produce a ton of pig iron in 1924 with one stack,
but this was reduced to 2.275 hours in 1925 and 2.378 hours in 1926
in operating two stacks. A return to one-furnace operation in 1927
brought the figures back up to 3.271 hours per ton. The saving in
indirect labor under two-furnace operation is very striking in this case.
Somewhat similar is the case of plant No. 10 (p. 76), which became
integrated with a steel plant after operating as a merchant furnace
for many years. Here it is not a matter of one or two furnace opera­
tion but of joint operation with an auxiliary manufacturing process.
No data are presented in this report for this plant after 1918 as
this is the last year it operated as a merchant furnace. Several
changes took place after it became identified with the steel-stack
division of the industry. In 1919 a stack was rebuilt and in a more
recent year a change in plant management was made which introduced
many labor economies. Man-hours per ton were reduced from
8.920 in 1918 to 3.560 in 1923 and further reduced to 2.705 for the
first half of 1927.
It is only intended to point out here that joint operation makes
possible certain labor economies; it does not follow that all plants
which have the advantage of such operation are able to obtain these
economies. There are plants in this study which show an actual
decrease in productivity upon the introduction of joint operation.
This is sometimes partly due to a failure to divide the indirect labor
fairly between the two operations, as in the case of plants which
arbitrarily split such labor with a coke plant or auxiliary manufac­
turing process on a 50-50 basis. (However, this explanation does
not apply to plants with two-furnace operation where all indirect
labor is charged against pig-iron output anyway.) There are plants
in which joint operation did not result in any improvement in pro­
ductivity at all, whether because of peculiar conditions surrounding
the operations at those plants or because of failure to take advantage
of the opportunities.
The second important factor influencing the amount of labor time
necessary to operate a blast furnace is the introduction of laborsaving machines.



METHODS OF INCREASING PRODUCTIVITY

43

Mechanical filling has been brought about by means of the skip
hoist, which is merely a short term covering a whole series of im­
provements in the method of charging the furnace. The old system
of charging by hand was a very cumbersome process, requiring a
large number of men. The ore, coke, and limestone had first to be
brought over from the stock piles or bins in cabs or cars. The
bottom fillers and their helpers loaded the materials into wheel­
barrows and wheeled these over to the cage or elevator, which lifted
them to the top of the stack. Here another group of men called
top fillers dumped the barrow loads into the furnace. Hand filling
was hard, unpleasant work requiring very little skill on the part
of the worker.
Mechanical filling changes the whole process of charging. First,
there is built a high trestle on which loaded cars can be run and
dumped, the materials falling through into a long set of bins situated
directly beneath the trestle. The bins are V-shaped structures built
sufficiently far above the ground that a larry car or scale car can pass
along underneath them. The car operator, by means of a series of
levers, opens the bins at the bottom and allows the materials to fall
into the car, which then delivers the load to the skip hoist itself.
The skip usually consists of two alternating hoists which convey the
materials to the top of the stack and automatically dump them into
the furnace. There is a bell-shaped device at the top of the stack
for the purpose of distributing the stock evenly in the furnace. The
whole structure results in a great reduction in charging labor— the
skip itself eliminates the top fillers, the larry car eliminates the bottom
fillers and fillers’ helpers, and the trestle eliminates most of the labor
engaged in delivering materials. The labor which remains is that of
operating the skip and the larry car and of dumping the cars on top
of the trestle.
There are several striking examples of the effect of installing a skip
hoist. In plant No. 20 (p. 80) one was installed in 1924. Although
the effect on productivity is somewhat obscured by the relining of the
stack which took place at the same time, nevertheless it is possible
to get a fairly definite measure of the increased output per man-hour
due to the reduction in charging labor. After relining the stack the
output of pig iron per stack-day increased from 346 gross tons to 418
gross tons, causing a proportionate increase in productivity estimated
at about 20 per cent. But the output per man-hour of the furnace
crew in 1925 was more than double that in 1924, so that the skip hoist
would account for an increase in furnace-crew productivity of approxi­
mately 80 per cent. It required 1.651 man-hours of furnace-crew
labor to produce a gross ton of pig iron in 1924, but only 0.800 manhour in 1925.
Plant No. 36 (p. 87) changed over from hand filling to mechanical
filling in 1919, but here too the effect of the change on productivity
is obscured by the relining of the stack at the same time. However,
the output per stack-day was not increased appreciably in the follow­
ing year, while the man-hours of furnace-crew labor per ton of product
decreased from 3.477 hours to 1.805 hours, which reduction roughly
corresponds to that shown in the plant mentioned above.
A third case of the installation of a skip hoist is plant No. 57
(p. 96). As is usual when important improvements are introduced the
stack was relined at the same time, but this latter may be disregarded




44

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

for there was no real change in the size of the stack and the output
per stack-day after relining was scarcely higher than before. The
furnace-crew labor, however, was reduced from 2.704 man-hours per
ton of product to 1.818 man-hours, and nearly all of this can be
ascribed to the influence of the mechanical system of charging.
The installation of the skip at plant No. 19 (p. 80) is also worth
mentioning because it is not complicated by any relining of the stack,
although there was a slight increase in output per stack-day after
the change. The skip was installed in 1924 and the furnace-crew
labor' was reduced from 2.992 man-hours per ton of product in 1923
to 1.472 man-hours in 1924, a decrease of over <50 per cent. While
it is too much to say that all of this can be attributed to the labor
saving of the skip, this was the only important machine introduced
at this time.
Plant No. 18 (p. 79) furnishes an excellent illustration of the instal­
lation of a skip hoist in the southern district. In 1920 with a handfilling system it required 6.705 man-hours of furnace-crew labor to
produce a ton of pig iron, while in 1922 after the skip and its auxiliary
equipment had been installed it required only 2.613 man-hours.
The skip was installed in 1921, but the partial operation during that
year was not representative. The output per stack-day is somewhat
lower in 1922 than in 1920 so that nearly all of the reduction in the
furnace-crew labor can be attributed to the installation of the skip.
There was also a great reduction in “ all other” labor between the
same two years, and some of this is undoubtedly due indirectly to
the skip, for there was considerable saving of labor in delivery of ore
under the new system.
The influence of the pig-casting machine on productivity can not be
measured as definitely as that of the skip, because it does not result
in saving as much labor as the change from hand to mechanical
charging and a large part of the saving which is accomplished is in
indirect rather than direct labor. The pig machine does directly
displace a considerable number of sand cutters and iron carriers in the
furnace crew, and to the extent of this displacement its effect on
productivity can be measured by the increase in output per man-hour
of the furnace crew or by the reduction in man-hours per ton of
furnace-crew labor. However, it also exerts considerable influence
on the indirect labor required in the iron yard, a saving which does
not show in the furnace-crew labor and which is frequently obscured
by other factors affecting the indirect labor. The pig machine brings
about a saving of labor in the iron yard because of the fact that it
elevates the pigs in the process of cooling and permits them to drop
into gondolas and open cars from which they can be unloaded by a
locomotive crane in the iron yard. When the pig iron is sand cast
it is frequently loaded by hand into closed cars from which it must
be unloaded by hand in the iron yard, thus requiring a very large
unloading and piling crew.
The following plant histories are shown to illustrate the effect of the
pig machine, but in most cases it can not be traced beyond the furnace-crew labor.3
A pig machine was introduced by plant No. 50 (p. 93) toward the
end of the year 1923, and a small percentage of metal was machine
cast in that year but not enough to affect the productivity figures
« f o r data on effect of pig machine on iron-yard labor see ch. 4, p. 49.




METHODS OF INCREASING PRODUCTIVITY

45

seriously. However, the furnace-crew labor was reduced from 3.136
man-hours per gross ton of pig iron in 1923 to 1.669 man-hours in
1924, which means cutting the furnace crew very nearly in half. The
“ all other” labor does not appear to have been influenced at all by
the machine, probably because the plant was using a full complement
of locomotive cranes already.
Plant No. 59 (p. 97) furnishes a striking illustration of the effect
of the pig machine on productivity, but unfortunately the results of
its introduction are mixed up with the results of some other improve­
ments which took place at the same time, particularly a change in
the bins and an increase in the size of the stack. The machine was
introduced in 1922, but this was a year of very inefficient operation
all around, and the full effect of the change is not noticeable until
the following year. The furnace-crew labor was reduced from 5.232
man-hours per ton of product in 1920 to 2.570 man-hours in 1923,
and at the same time the “ all other” labor was reduced from 6.527
man-hours per ton of product to 3.629 man-hours. The increase in
output per stack-day from 137 gross tons of pig iron in 1920 to 182.1
in 1923 accounts for a considerable part of the decreased labor per
ton in both sections of the crew; but the remaining decrease, which
is still very great, must be attributed jointly to the improvement in
the bins and the use of the pig machine. The pig machine, however,
was undoubtedly responsible for a greater saving in labor than the
change in bins.
Plant No. 51 (p. 93) also furnishes a good illustration of the effect
of the pig machine on productivity, although in this case the results
were less marked than in the previous cases. The furnace-crew labor
was reduced from 2.289 man-hours per ton of product in 1924 to
1.772 man-hours in 1925 when the pig machine was operating. Since
the output per stack-day in both years was exactly the same, and no
other changes in equipment took place, this decrease in labor was
entirely the result of the installation of the pig machine. In fact, the
above figures do not adequately measure the influence of the machine
on productivity, for the “ all other” labor shows a reduction from
3.398 man-hours per ton in 1924 to 2.900 man-hours in the following
year, and much of this also is probably due to the use of the machine.
There are many other cases showing the effect of the installation
of the pig machine, but it often happens that the results are not
clearly shown, being lost among the results of numerous other influ­
ences. A detailed study of Table A (p. 71), however, will furnish
considerable material on the subject of the pig machine in relation
to productivity.
There are no clear cases of the influence of the crane on produc­
tivity, for this has not had such a marked effect as the two machines
previously mentioned, and in addition cranes have usually been
introduced one at a time, so that their full effect in displacing hand
labor in the yard and floating gangs is extended over a period of years
and is thus lost in the general mixture of other changes. For the
purposes of this discussion, however, it is sufficient to point out that
the locomotive crane has been of considerable importance in dis­
placing labor, particularly in the iron yard and in ore unloading.
There was a time, comparatively recent in some sections of the coun­
try, when ore cars were unloaded by a crew of 20 to 40 men under
contract at so many cents per ton, and the iron in the yard was




46

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

moved and piled by another crew of about 20 men. At the present
time, in every modernized plant, the ore is unloaded by means of a
car dumper or a locomotive crane, and nearly all the handling of the
iron is done by a crane. The locomotive crane has been largely
responsible for the great reduction in the unskilled labor gangs work­
ing around the plant. Electric overhead cranes in the cast house and
in various parts of the plant have also played an important part in
the elimination of hand labor.
It would be possible to go on calling attention to other machines
which have been instrumental in displacing large amounts of hand
labor but it is not necessary to go further into details on this point.
However, there are two important machines which have played an
important part in ore unloading in the larger plants— the ore bridge
and the car dumper. In one sense these two machines represent a
second stage of progress in ore handling, for in the same way that the
locomotive crane displaced hand labor these two items of equipment
are eliminating the locomotive crane itself. A car dumper with a
crew of two men can handle all the ore for a one or two furnace
plant as fast as it can be brought in. Then the ore bridge, with a
crew of two operators and two oilers, removes the ore to the stock
pile and at the same time keeps the bins supplied with ore for imme­
diate use. This method of ore handling eliminates the use of several
locomotive cranes, reduces the amount of railroad transportation in
the plant, and cuts the labor force. However, the use of these two
machines is mostly confined to fairly large blast-furnace plants or to
those along the Great Lakes, for they are expensive to install and
would burden the plant with a large overhead cost unless they are
used to capacity. Few of the smaller merchant furnaces use either
one of them.
Another factor affecting labor is skill, willingness, and ability of
the laborer himself. The difficulty is that there is no satisfactory
way of gauging the influence of this most important factor. Nearly
all furnace operators realize that the good will of the workers is of
great importance in determining the output of the plant and the
quality of the product, but this good will operates in such subtle
ways that its results can not be measured statistically. However,
there did occur during the period covered by this study one specific
change which has had some effect on the efficiency of the worker
himself, in the absence of any improvements in equipment or organi­
zation. This was the substitution of the 3-shift for the 2-shift
system in 1923, the elimination of the 12-hour day, and the estab­
lishment of the 8-hour day for workers on continuous processes. Be­
fore this change took place it was confidently expected by many
that there would be a considerable increase in labor cost because of
the increase in the number of men required to operate the furnace.
It is therefore of particular interest to note the results of the change
in the shift system in individual plants.
Theoretically, the substitution of the 8-hour day for the 12-hour
day would have no effect on productivity; that is, each position re­
quiring two men at 12 hours each would require three men at 8
hours each and the output per man-hour of labor would remain the
same. In actual practice, of course, it would be expected that the
output per man-hour would be somewhat higher in the latter case,
for it is evident that a man can work at higher speed for 8 hours




METHODS OF INCREASING PRODUCTIVITY

47

than he can for 12 hours. But the actual results in the blast-furnace
industry following 1923 far exceeded anything that might have been
expected. There are numerous cases of plants in which, within a year
after the change was made, the total labor force was back again at
the same number of men that had been employed under the 12-hour
system.
In plant No. 12 (p. 77) the steady increase in productivity was
accelerated by the introduction of the 8-hour day. The old system
of 10 and 12 hours was abolished at the end of 1923, and a new uni­
versal 8-hour system was substituted. The total labor time ex­
pended per ton of product was 2.917 man-hours in 1923 and 2.227
man-hours in 1924. There was about a 10 per cent increase in
output per stack-day, which accounts for a small part of the increased
productivity, but even when this is allowed for there still remains a
further substantial increase in productivity, or to put it conversely a
reduction in labor time. Of course, this plant shows a steady in­
crease in productivity in every year since 1919, but when the effect
of the increase in stack-day output has been eliminated the rate of
increase between 1923 and 1924 was greater than in any other two
years.
Another even better case is that of Plant 32 (p. 85). Eliminating
1923 as the year of transition from the 2-shift to the 3-shift
system, a comparison can be drawn between 1922 with the 10-hour
and the 12-hour day and 1924 with the universal 8-hour day. No
mechanical improvements of any importance were made in the inter­
val, the output per stack-day was nearly the same in the two years,
and even the length of time operated was almost identical. In other
words, the only important difference in the two years is in the hours
per day. Yet in 1922 it required 3.270 man-hours of labor to produce
a ton of pig iron, and in 1924 only 2.662 man-hours.
Another plant which furnishes a good illustration of this point is
No. 36 (p. 87) in which the transition to the 3-shift system was
made in 1923. In 1920, with the 10-hour and the 12-hour day, the
labor time per ton of product was 3.470 hours, while in 1924, after a
universal 8-hour day had been put into effect, the labor time was
2.245 hours. Allowance must be made for the increase in output per
stack-day from 267.3 tons in 1920 to 329.6 tons in 1924; but giving
full consideration to the increased output of the stack, the great re­
duction in the crew following the introduction of the 8-hour day is
obvious.
PRODUCTIVITY BY OCCUPATIONS AND LABOR GROUPS

The labor force in the various blast-furnace plants has previously
been studied as a unit or at least in large groups. The annual aver­
ages of productivity, however, whether for the whole labor force or
for the blast-furnace crew, do not show the changes which have
occurred in particular labor groups or individual occupations. Minor
improvements in machinery or small reductions in the labor force
are taking place all the time, but the effect is not evident in the out­
put per man-hour for the whole year. For the purpose of illustrating
in detail the slow but steady growth in productivity as it relates to
each small group or occupation throughout the plant, special data
were collected from a few plants.




48

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

Productivity by Labor Groups in a Southern Plant.

Table 10 shows the complete classification of the crew of a southern
merchant furnace over the entire period covered by this study. The
labor has been divided into 13 groups, each containing as nearly as
possible all labor engaged in performing a single operation. In the
cast house are included the keepers, the fall men or cinder snappers,
the stove tenders, and the scrappers working around the stack itself.
The pig-machine labor consists of all those engaged in operating the
pig-casting machine; these superseded the iron carriers, sand cutters,
and scrappers, who formerly took care of the iron from the time it
was cast in sand until the pigs were loaded on the cars for transporta­
tion to the iron yard. The stocking and charging labor consists of
such occupational groups as weighmen, skipmen, larrymen, and coke
punchers; in general, it includes all labor around the trestle and stock
house. The next group consists of labor engaged in delivering ore
from the stock piles to the bins; this was formerly done by means of
small cars, and numerous men were required to load these cars at
the stock piles and deliver them to the bins. In later years most of
this labor has been abolished. Ore-unloading crews are engaged in
emptying the ore cars when they come in from the mines. In the
South there is no summer ore season because the climate makes it
possible to deliver ore from the mines all through the year; conse­
quently, there is no necessity for storing a winter’s supply of ore in
the yard, and as many of the ore cars as possible are dumped directly
into the bins as they come in from the mines.
The general labor consists largely of the floating gangs which work
wherever necessary around the yard, on the tracks, etc. In former
years a large crew of men were kept busy in the iion yard unloading
pigs from the cars which came from the casting floor, piling iron,
loading up iron for shipment, etc. Now all of this is done by means
of locomotive cranes, and the only labor needed in the iron yard is
that of a shipping clerk, who gets a salary and is classified in the
salaried group. Locomotive cranes were first used in this plant in
1917, when one crane was bought. This was soon followed by an­
other, and since 1919 there have always been at least two cranes in
operation at the plant. The only labor required is that of the crane­
men and their firemen.
^
The railway switching crew is confined to those who take charge
of the “ cinder run” — that is, the cinder engineers, the couplers or
switchmen, and the ladle dumpers. These engines also do consid­
erable switching around the furnace, such as taking loaded cars out
to the iron yard, etc. There is a railroad which runs out to the
mines, but these crews are not considered to be part of the blast­
furnace labor. The mechanical crew consists of the master mechanic,
the machinists, carpenters, pipe fitters, blacksmiths, and bricklayers
working on current repairs. In the power-house labor are included
the blowing engineers, oilers, boiler men, and boiler cleaners. The
final group consists of salaried employees— superintendents, foremen
(those on a salary), clerks, timekeepers, and chemists.




T a b l e 1 0 . — Labor productivity in man-hours per ton of pig iron produced, in a typical merchant blast-furnace plant , by labor groups and years ,

1910 to 1927

Year

______
_____
______

Man-hour
0. 039
.059
.197
.203
.435
.325
.463
.280
. 373
! 491
.464
.635
. 719
.594
.726
.509
. 854
. 797

Railway
switching

Man-hour M an-hours M an-hours M an-hour
0.242
0. 959
0.162
(2)
.252
1.050
. 136
(2)
. 282
.341
.720
(2)
.293
1.096
0.193
.303
.288
.874
1.529
.218
.200
1.572
.614
.172
.346
1. 894
.743
.292
.483
2. 677
.945
. 160
. 389
2.952
. 874
. 102
! 358
2. 204
! 787
! 067
.260
2.155
.772
.057
. 308
2. 309
.856
. 494
2. 005
1. 003
.461
1. 870
.936
.488
1.868
.991
. 414
1. 917
. 877
. 435
2. 517
1. 091
.334
2. 556
1. 037

M an-hour
0. 233
. 237
.263
.271
. 265
.278
.294
.280
. 293
! 283
. 273
.287
. 251
.250
.264
. 304
. 304
.311

General
labor

Iron-yard
labor

1 First 6 months.
* Upon installation of pig machine, iron piling was handled by locomotive cranes and switching crews.




Mechan­
ical crew

Superin­
tendents,
Power
foremen,
house
(including clerks, and
blowing
other
engineers)
salaried
employees

M an-hours M an-hour
0.639
0. 465
.641
.474
. 797
.525
.542
. 771
.531
.725
.541
.655
.567
.586
.910
.559
. 492
1 . 028
! 324
'.640
.507
.273
.480
.353
. 541
. 534
.549
.498
.578
.530
. 539
. 455
. 625
. 612
.525
.468

Total

M an-hour Man-hours
0. 284
5.005
.281
5. 023
.318
5. 539
.359
6. 387
.323
7. 542
.ae 2
6. 784
.367
8.192
.282
8. 718
261
8. 981
! 193
7. 439
.142
6. 851
.207
7. 740
. 279
8. 212
! 260
7. 695
.275
8.158
. 250
7. 477
. 316
9! 388
.259
8.467

Average
full-time
furnaces
active
during
year

1.0
1.0
1.0
1.0
1.0
.6
.1
1.0
1 2
L7

2.0
1.6
1.0
L0
1 . 0.
1. 3

1.0
1.3

PRODUCTIVITY

M an-hour
0. 581
.592
.656
.677
.597
.643
.695
.629
. 697
.614
.517
.588
.602
.530
.660
. 627
. 759
.544

Locomo­
tive
cranemen

INCREASING

M an-hours M an-hour M an-hour
0.936
0. 465
.828
.474
.915
. 525
1 . 012
.445
0. 221
.892
.865
.832
. 598
1. 013
.802
.815 ___________
.699
. 722
. 798
.709 !
.768
.682
.749
. 833
.884
.875
.909
.858
.889
.858
.924
.826
. 758
.986
.893
.885
.751

Cast house

Delivery
labor
Ore
(ore from
unloading
stock pile
to bins)

OF

Stocking
and
charging

METHODS

1927 1—
1926____
1925____
1924____
1923____
1922____
1921____
1920____
1919____
1918____
1 9 1 7 ...:
1916____
1915____
1914____
1913____
1912____
1911____
1910____

Iron
carriers,
sand
cutters,
scrappers,
etc.

Pigmachine
labor

50

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

For each of these groups there is shown for every year the total
man-hours of labor required to produce a gross ton of pig iron. The
total man-hours given in the final column at the right corresponds
to the figures in Table A showing the man-hours per ton of pig iron
for the plant as a whole. From 1911 to 1920 the productivity
remained about constant, although there were minor variations chiefly
due to the relative amount of one and two furnace operation. In
1917, when there was full 2-furnace .operation, 6.85 man-hours
were required to produce a gross ton of pig iron, while in 1911, with
only one stack operating, it required 9.39 hours. However, there
does not appear to have been any general upward trend of produc­
tivity during this period. The figures for 1921 are for'only one
month of operation previous to closing down, so that they are not at
all representative of conditions and need not be considered. When
the plant was started up again in the spring of 1922, a much smaller
force could be us^d, as a large amount of the repair work and neces­
sary preparation had already been done by the men who had been
kept on the pay roll during the shutdown. It was not until 1923
that the plant was again operating with a full crew, and from that
year down to 1927, with steady 1-furnace operation, there has been
a marked reduction in the man-hours per ton of pig iron. The best
pre-war record for single-furnace operation was made in 1914, with
7.70 man-hours per ton, and this is the figure which should be com­
pared with 5.02 hours in 1926.
The changes within the different labor groups present some sharp
contrasts. The cast-bouse crew shows very little change over the
whole 17-year period. The economy of 2-furnace operation is
clearly shown by the low record of 0.68 hour per ton, made in 1917;
but for 1-furnace operation the 0.83 hour in 1926 shows very little
improvement over the 0.86 hour of 1914, and barring the year 1921
for reasons given above the year 1924, with 1.01 hours per ton, show^s
a higher time cost than any pre-war year. Thus, the cast-house
crew has remained fairly well stabilized throughout the period, and
the only real improvement shown was brought about by doublefurnace operation.
The influence of the pig machine can be seen in the complete
elimination of two labor groups— the iron carriers and sand cutters
engaged in sand casting and the iron-yard labor engaged in handling
iron in the yard. Therefore the net effect of the pig machine can
be obtained by combining these two groups in the years prior to its
introduction. In making the comparison the years 1921 and 1922
should be excluded, since they are not representative. A consider­
able amount of piling and shipping was done by the yard crew while
the furnace was down, which of course does not show in the figures.
However, in 1923 the total hours required by these two groups were
1.74, as compared with 0.53 hour for the pig machine in 1925 and
0.47 hour in 1926.
The stocking and charging group shows no important changes. Like
the cast-house crew, this group was not affected by any influence
other than that of single or double furnace operation. In 1917, with
2-furnace operation, the low point of 0.52 hour per ton was reached,
the single-furnace operation in 1914 resulting in the very good record
of 0.53 hour, while in 1926 the figure was 0.59 hour.
Ore delivery labor has been cut down almost to nothing in recent
years— 0.06 hour in 1926 and 0.04 hour in the first six months of



METHODS OF INCREASING PRODUCTIVITY

51

1927. The amount of this labor needed at the plant has fluctuated
widely, but in the best pre-war year (1912) it was 0.51 hour. There
was a good record of 0.28 hour for this labor group in 1920, but this
should not be accepted at its face value, for the labor saved here
was counterbalanced by a large amount of ore unloading labor— 0.48
hour. More ore cars were unloaded directly into the bins in this
year than in others immediately preceding and following. The bins
have been recently modernized, and the large number of car loaders
and drivers is no longer needed.
The general labor force has been cut in half since pre-war days.
This type of labor reflects very closely the relative prosperity of the
industry, for in years when the industry is prospeiing these general
yard laborers are taken on freely in order to speed up operations and
keep things in first-class shape; but when times are bad this crew is cut
as much as possible and only the most essential kinds of work done.
There was a steady decline in the hours required for this labor from
1912 to 1914; then in 1915 the man-hours turned sharply upward,
indicating much larger crews, and this trend continued for the next
five years; the figures for 1917 and 1918, because of double-furnace
operation, obscure the actual expansion in the crew at that time.
The crew was larger in these years than it had been previously, but
the man-hours were spread over a greater output of pig iron. The
turn in 1920 is clearly shown, and since that time the general labor
has been reduced in almost every year. The low figure in 1925 is
partly explained by the increase in locomotive-crane labor, but ap­
parently the plant was able to run with a very small crew for one
year. This could not be done continuously.
The locomotive-crane labor fluctuates widely, depending not so
much on the number of cranes working but more on what the cranes
are doing. It requires an engineer and fireman to operate a locomo­
tive crane ordinarily, but when a groundman or hook-on is needed
the total man-hours are increased by one-half. There were no cranes
at all in use at this plant until 1917 and then only one crane for
several years. These cranes have been responsible for a great deal
of labor saving in the iron yard and in general labor.
The railway switching hours vary but little from year to year; in
general the trend has been slightly downward and it is apparently
quite independent of the number of furnaces operated. The best
record on this class of labor prior to 1926 was made in 1914 with
0.25 hour per ton, while the 2-furnace operation of 1917 resulted in
0.27 hour per ton.
For the most part the mechanical crew has remained fairly con­
stant during the period. The amount of mechanical work required
is to a large extent independent of the operation of the stacks but is
apt to depend largely on the nature of the difficulties encountered.
If a serious breakdown occurs, the plant is likely to close down and
the repair work will not appear as operating labor; therefore, it is
only the minor repairs which are included in these man-hours.
The power-house crew remains practically constant all the time
regardless of the changes in operation, so that the man-hours per ton
vary inversely to the production. Thus 1917 is the year of the
lowest record, while the single-furnace operation of recent years has
produced the highest records.
In general the salaried labor has increased slightly over the period.
This is not a specific labor group, however, as it represents a combi­



52

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

nation of employees from various other labor groups; thus, it may be
increased by the transfer of employees to a salary basis.
The above discussion shows that the labor saving in this plant took
place both in the furnace crew proper and in the general overhead
labor and was the direct result of the introduction of important ma­
chines or equipment. Some groups did not participate to any extent
at all in the reduced man-hours of labor per ton of pig iron, and there
is only one case (ore unloading) of steady reduction in the absence of
a new machine. The iron carriers and iron-yard laborers were re­
placed by the pig machine and the locomotive cranes, the ore-delivery
laborers were reduced by a new system of bins, and the general yard
labor by locomotive cranes. The saving in ore-unloading labor can
be traced to better integration of operations.
Productivity by Occupations in a Pennsylvania Plant.

A more detailed analysis of the labor required to operate a blast
furnace is shown in Table 11. This is a Pennsylvania furnace for
which the man-hours per ton of pig iron produced have been calcu­
lated by occupations and labor groups. The table shows the labor
conditions in 1920 at the peak of the boom operations of that year;
in 1921 the data cover only partial operation in a year of extreme
depression when crews were reduced to the very minimum, while
1926 shows the condition of the crew in a full year of operation after
the plant had been thoroughly modernized.
T a b le

1 1 .— Labor 'productivity in a typical merchant blast-furnace plant, by occu­

pations and labor groups, fo r the years 1920, 1921, and 1926

Occupation and labor
group

Man-hour per gross ton
of pig iron produced

1920

Stocking and charging:
Stone breakers_______
Crusher engineers___
Coke sweepers and
helpers
________
Ore loaders___________
Fillers
___________
Top fillers.__ ________
Weighmasters ______
Scale-car operators
Skip engineers.
T otal...........................

1921

1926

0. 056

0. 046

.316

.290

0. 282
.058
.282
.408
1.971
.427
. 116

3. 544

. 130
.130

. 116
.116

.632

.568

Casting:
.990
1.018
Keepers and helpers..
.281
.254
Cinder men_____ _____
F o u n d r y men
. 130
.146
(blowers)___ _____
.130
Stove tenders.
__
. 146
Blowing engineers___
.130
.146
. 130
Water tenders______
. 146
fly'QTio
dLiv Irnnnorc
umiei o____ ___
.058
.161
Iron weighers________
. 146
. 592
. 534
Iron carriers__________
.372
Iron loaders__________
. 650
C a s t in g -m a c h i n e
labor_________
_.
Molders and helpers ...............1____
Total
Yard switching:
Yard foremen________
Locomotive engineers.
Brakemen and fire­
men...... .......................




3.301

.465
.232
. 116
. 116
.232
. 116
.290

_

.581
.116

2. 859

2. 264

|
.058
.204

. 056
. 192

.046
.174

.349

.316

.290

Occupation and labor
group

Man-hour per gross ton
of pig iron produced

1920

1921

Yard switching— Contd.
Trackmen
__ _
Car inspectors______

0.175
.058

0.161
.056

0.145
.046

Total _____________

.844

.781

.701

.058
.058
. 175

.056
.056

.046

.2 1 1

.343

.116
.291

.105
.161

. 099
'.099
.046

Mechanical:
Master m echanic___
Structural engineer...
M achinists.. .
_
B l a c k s m i t h s and
helpers
Carpenters___________
Bricklayers

1926

. 698

. 589

.633

Power:
Boiler firemen. _ __ _
Electrician

. 146

. 130
. 056

.116
.046

Total_______________

. 146

.186

.162

.932

.935

1. 289
.046

. 116
. 068
.058

. 105
.062
.056

.099

Total

1.184

1.179

1. 451

Grand t o t a l .______

9. 707

6. 205

5.808

Total....................... ..

General:
Laborers_____________
Timekeeper _________
Chemist and assist­
ant.................. .............
Night watchmen
StnrplrAPnAr

.046

METHODS OF INCREASING PRODUCTIVITY

53

The appearance and disappearance of certain occupations upon the
introduction of machinery is clearly shown in the record of this plant.
In the stocking and charging group the stone breakers, coke sweepers,
fillers, and weighmasters all disappeared when the skip was installed
in 1921, and the new occupations of skip engineers and scaie-car
operators replaced them. The eliminated occupations required a
total of 3.078 man-hours per ton of pig iron in 1920, while the new
machine operators required only 0.260 hour in 1921 and 0.232 hour
in 1926. The crusher engineers and the ore loaders who remained
throughout all three years, show a gradual reduction in man-hours
per ton of pig iron, a change which is due entirely to the increasing
daily output of the stack, for the actual number of men in these
occupations remained constant. Had the skip been in place in 1920,
the same proportionate reduction would have taken place in the manhours per ton for the scale-car operators and the skip engineers as
actually did take place for the ore loaders and the crusher engineers.
An estimate on this basis shows that the man-hours per ton in 1920
for the scale-car operators and the skip men would have been 0.146
hour for each occupation or 0.292 hour for both. The net effect of
introducing the skip can thus be calculated: 3.078 man-hours of labor
per gross ton of pig iron for the occupations formerly necessary minus
0.292 man-hour of labor for the scale-car operators and the skip men
equals 2.786 man-hours of labor saved by the skip.
The same situation can be seen in the casting labor when the pig
machine was introduced between 1921 and 1926. The iron carriers,
iron loaders, and a large part of the keepers’ helpers disappeared from
the furnace crew while their places were taken by the casting-machine
labor and the molders. It is a little more difficult to estimate the
net effect of the pig machine, but by applying the same principles of
estimation that were applied to the skip it is calculated that the manhours per ton required for a pig machine in 1921 would have been
about 0.780 hour; the keepers and helpers labor would amount to
0.520 hour instead of 1.018, thus leaving 0.498 hour of keepers and
helpers’ labor that was eliminated by the use of the machine. The
total sand-casting labor displaced by the machine was, therefore,
keepers’ helpers, 0.498 hour; iron carriers, 0.534 hour; and iron
loaders* 0.372 hour— a total of 1.404 man-hours per ton of pig iron
produced. From this amount must be subtracted the amount neces­
sary to run the pig machine, or 0.780 hour, leaving the net saving in
labor of 0.624 hour per ton. The saving here compares very favor­
ably with that at the southern plant first mentioned.
So far as the other occupations are concerned, there is a clear-cut
decline in nearly every case. However, this is not due to any saving
of labor, but to the increased output of the stack which resulted in a
larger tonnage of pig iron over which to spread the man-hours of
labor. An important exception to this rule was the general labor,
which increased each year; the machinists also showed considerable
increase, although the mechanical group apart from the machinists
showed a decrease each year. The increase in machinists can be
explained by the increased amount of machinery in the plant after
the introduction of the skip and the pig machine. The increase in
general yard labor is probably due almost entirely to the ore-unload­
ing crew. Both in 1920 and 1921 there was plenty of opportunity
to stock ore while the plant was not in operation, while in 1926 it
had all to be done when the furnace was in blast. Hence, the general




54

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

labor man-hours are larger in 1926. There is no corrective measure
for this situation; it is always possible for a plant to do a great deal
of repair and general yard work while the furnace is down, and there
is no way of taking account of this in operating labor hours.
Productivity by Labor Groups in a Blast Furnace with a Coke Plant.

Another case of a detailed classification of labor time within a
plant is that of a high-productivity blast furnace which is combined
with a coke plant It has many points of contrast with the two
preceding cases in that it is a lakeside plant, it has the advantages of
joint operation, and it is equipped with the most modern machinery,
including an ore bridge. The classification of the labor into groups
is not quite on a comparable basis with the other two. The furnace
crew, with the exception of the pig-machine labor, has been lumped
together into a single group, thus the variation between occupations
within this group is not available; also the furnace crew includes the
full-time mechanical men who are attached to the furnaces and not
to the shops; the latter cover only the work done in the shops for the
blast furnaces. Thus the absolute figures for furnace-crew time can
not be directly compared with the figures in the other two plants.
However, all the other labor charged against the blast furnace in this
plant is shown in complete detail.
Table 12 shows the man-hours required to produce a ton of pig iron
by each group specified as well as the total man-hours per ton of the
plant as a whole.
The detailed data on labor time in this plant shows clearly the
effect of full operation on labor economy. The furnace crew proper
shows a pronounced increase in man-hours per ton of output whenever
there is less than two-stack operation. Also many of the other labor
groups exhibit the same tendency during the two years of limited
production— the ore bridge labor, locomotive cranes, water, electric­
ity, steam and boilers, laboratory, and general works labor. All
these groups require more man-hours per ton of product in years of
partial operation. The reason of course is clear. Labor groups which
have a comparatively fixed number of positions regardless of the
furnaces in operation will make the best record in labor time when the
production is highest— that is, when the overhead is spread over a
larger tonnage. Single-furnace operation does not lead to much of a
saving in labor while the production is cut in half. This explains why,
under identical conditions, a two-furnace plant has an advantage in
productivity over a single-furnace plant.
The efficiency of operation made possible by integration with a
coke plant is shown by the figures for the indirect labor groups.
Nine separate labor groups in this plant have their time distributed
between the blast furnace and the coke plant. This explains the
astonishingly low man-hours per ton in some of these groups. If
figures on yard switching, locomotive cranes, steam and boilers, and
general works are compared with corresponding figures for the other
two plants previously discussed the contrast will be evident. While
this plant is efficiently operated, it still remains a fact that a most
important factor in causing this low labor time is the coke plant
which shares the use of the indirect labor groups. Some allowance
must be made for the fact that the indirect labor in this plant does not
include the full-time mechanical men, but on the whole this would
have little weight.



T able

12 .— Labor

Year

'productivity in man-hours per ton of pig iron produced in an integrated merchant blast-furnace plant on the Great Lakes,
by labor groups and years , 1922 to 1927

2.0
2.0
2.0
1.5

2.0
1.3

M an hours
0. 826
.908
.899
1.160
.968
1. 573

OrePigmachine
bridge
labor
operators

M anhour
0.164
.188
.2 65
.240
.283
.329

M anhour
0. 065
.074
.077

.10 2
.098
.113

Dock
labor

M anhour
0.048
.096
.130
. 141
.160
.244

Loco­
motive
cranes

Yard
switch­
ing

Mechan­
ical
shops

Water

Electric
genera­
tors

Steam
and
boilers

Labora­
tory

Stores
and
supplies

General
works

1

2

3

4

5

6

7

8

9

M anhour
0. 050
.053
.072
. 101
.071
.206

M anhour
0.096
.094
. 145
.162
.204

M anhour
0. 005
.007
.009

.222

.008

.0 11
.0 11

M anhour
0.019

M anhour

.022

0.001
.001

.035
.062
.040
.062

.003
.004
.003
.004

M anhour
0.097
.087
.090

.1 1 1
.104
.146

M anhour
0. 052
.048
.042
.058
.047
.048

M anhour

0.011
.0 11
.019
.025
.025
.030

M anhour
0.153
.157
.168
.226
.178
.196

Total
(all
groups)

M anhours
1.587
1. 746
1.954
2. 403
2.194
3.181

PRODUCTIVITY




This is

INCREASING

E X P L A N A T IO N
Columns 1, 2 , 3, 4, 5, 6, 7, 8, 9 do not show the full force in the plant performing these operations, but only the amount charged against the blast furnace in each year.
a coke-plant furnace and the overhead is distributed between the two operations.

OF

1927,...........................
1926. _______ _______
1925. _______ _______
1924_________ _____ _
1923________________
1922____ _____ ______

Blast­
furnace
crew
proper

METHODS

Num ber
of full-time
furnaces
active dur­
ing the year

Cm
Oi

56

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

The ore bridge eliminates considerable locomotive crane and switch­
ing labor, but the cost of installing and operation is so great that only
the larger plants use them. The dock labor in this plant corresponds
to the ore-unloading labor in an inland plant, but there are differences
as regards productivity which should be noted. The existence of the
dock requires the operation of an ore bridge and thus forces the plant
to a high productivity level in the subsequent handling of the ore, but
as far as ore unloading itself is concerned a plant with dock facilities
is probably under a handicap with reference to productivity. Unload­
ing ore from a vessel is much more efficient in labor time than unload­
ing from railroad cars by hand or with locomotive cranes. However,
an inland plant using a car dumper in connection with an ore bridge
would probably show a considerably higher productivity in ore
handling than the lakeside plant with a dock, because the man-hours
per ton on a car dumper would run lower than the man-hours per ton
on the docks. Yet in one sense this is not a fair comparison, for the
ore delivered at the inland plant (if it is ore shipped from Minnesota)
has already been unloaded at the docks and then reloaded into cars,
but with labor not charged to the blast furnace. Therefore, the
unloading which does take place at an inland plant is the second one,
and the first one is not counted in labor time.
It is difficult to compare blast furnaces operating under different
conditions. For purposes of comparison it would be desirable to
eliminate the ore unloading as a process in blast-furnace operation
and treat it as a part of the delivery of the raw materials, beginning
the blast-furnace operation with the stocking and charging. In actual
practice this is not possible because the blast-furnace plants take
charge of the ore when it is delivered in the yard or at the dock, and
the labor of unloading is in most cases mixed up with all the other
labor in the plant. As far as ore unloading is concerned blast-furnace
plants can be divided into three groups: (1) Lakeside plants which
have their ore delivered at a dock, (2) inland northern plants which
have the ore delivered in cars from which it must be removed to the
stock piles, and (3) southern plants which can have the ore delivered
regularly throughout the year, and so can unload many of their cars
directly into the charging bins of the furnace. Each of these groups
of plants has its own problem of ore handling, and it is not easy to
compare one group with any of the other groups. It is obvious that
the southern plants have the decided advantage in that they have to
handle the ore only once instead of twice.
ANALYSIS OF PRODUCTIVITY CHANGES IN INDIVIDUAL PLANTS

The influence of various factors in causing changes in productivity
can best be brought out by the analysis of individual plant histories.
Varieties and extremes of productivity changes in individual plants
are completely hidden in the general averages for the districts and
for the industry. The relation in the industry as a whole between
output per man-hour and output per stack-day or reduction in labor
time can best be understood through an examination of the relation­
ship between these factors in individual cases.
The labor productivity record of each plant covered in this study
is shown in Table A. In addition to productivity figures, the table
furnishes data on production, full-time furnaces active, output per
stack-day, consumption of raw materials, and plant equipment—in




METHODS OF INCREASING PRODUCTIVITY

57

short, all available data explaining the trend in productivity for each
plant. Thus the changes in productivity may be studied in relation
to the more important factors influencing them.
Particular attention is called to the column showing the average
number of full-time furnaces active during the year, which measures
the regularity of operation. Regular operation is essential for good
productivity, since a furnace can not maintain good performance
when alternately blown in and blown out at frequent intervals.
The steady flow of materials through the stacks and the best daily
output depend upon regular operation, and proper labor economy
is impossible without the routine of steady production. "A plant
having several furnaces is much more economically operated when
all its furnaces are active.
In the case of materials consumption the individual plant schedules
are much more important than the combined averages for an under­
standing of the changes in the industry. The relation between the
output per stack-day and the increased use of scrap in the furnace
burden, for example, can be studied much more easily from the
history of an individual plant.
A very significant item in Table A is tne enumeration of important
changes in plant equipment as shown in the last column. Only
through case studies of individual plants can the effect of such
detailed changes be analyzed.
In the table the productivity of all labor at the plant has been
subdivided into two parts— productivity of the “ furnace crew” and
productivity of “ all other” labor. This subdivision into “ furnace
crew” and “ all other” has been made on as uniform a basis as possi­
ble, but minor labor groups are classified differently in various plants,
and in some cases it has been necessary to make a somewhat arbi­
trary reclassification of the labor divisions furnished by the plant.
The two labor groups used in this study, however, include substan­
tially the same labor groups in all plants, and the minor inclusions
and exclusions in most of them do not materially affect the com­
parisons.
PLANTS MAKING EXTREME INCREASES IN PRODUCTIVITY

Plant No. 12 (p. 77).
From 1911 to 1926 this plant made one of the best productivity
records in the industry, reducing the man-hours of labor required to
produce a ton of pig iron from 6.67 in 1911 to 1.89 in 1926. Even
more striking is the fact that by far the greater part of the increase
in productivity took place since 1919, for in that year it still required
5.82 man-hours of labor per ton of product. The output per manhour in 1926 was slightly more than three times as much as it was
in 1919.
The factors which were instrumental in causing this increase in
productivity are clearly shown in the data. The sizes of the two
stacks remained about the same throughout the period 1911 to 1919,
the decline in output per stack-day during the war years being due
primarily to the poor quality of the coke available for use at that
time. The stacks were enlarged considerably in the rebuilding of
1919-20, so that the daily output in 1920 was about 25 per cent
greater than in 1919. Since this rebuilding there have been no
5421°— 29------- 5




58

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

important changes in the size of the stacks, practically the entire
increase in daily output since 1920 being the result of improved
furnace operation. The general increase in efficiency of operation
is evident from the data on coke consumption. The poor quality
of the coke used during the war is shown by the high consumption
per ton of product, 2,386 pounds per ton in 1917. The rebuilding
of the stacks brought about a reduction to 1,973 pounds per ton in
1920, and in 1925 the low record of 1,808 pounds was reached. This
low consumption of coke was accompanied by a steadily increasing
daily production of pig iron. On the labor side there were two
important changes— the installation of the pig machine in 1916-17,
and the introduction of the universal 8-hour day in the beginning
of 1924. The effect of the former on man-hours per stack-day is
obscured by the increase in general labor which took place during
the war. The exceptionally large increase in productivity from 1923
to 1924 can be attributed to the reorganization of the labor crews
upon the introduction of the 8-hour day.
This plant is very efficiently operated; in 1926 it ranked third in
productivity in the entire industry, and in 1924 and 1925 it ranked
second.
Plant No. 59 (p. 97).
This southern one-furnace plant reduced its labor requirements per
ton of iron from 14.69 hours in 1917 to 6.40 hours in 1924, an even
more rapid rate of increase in productivity than that shown by
Plant No. 12. However, it is noticeable that the productivity of
Plant No. 59 at the time of its closing down in 1924 had just reached
the point at which Plant No. 12 started out in 1911— that is, about
6J^ hours of labor per ton. The stack w^as mechanically filled, but
sand-cast, in the first period 1917 to 1920; there were no improvements
of importance during that time, and the productivity varied directly
with the output per stack-day. The extremely high rate of con­
sumption of materials is evidence of the lean ores and poor quality
of coke in use at this plant. In 1921 the stack was rebuilt and con­
siderably enlarged, and a pig machine was installed at the same time.
Practically the whole of 1922 was spent in getting the plant equipment
to operate properly, so no results of the change are apparent. In
1923 however, the daily output of the stack rose to 182 tons and the
labor force was greatly reduced by the pig machine, with the result
that productivity was almost doubled as compared to the record of
1920. The improved operating efficiency of the new stack is evident
in the data on coke consumption for 1922-1924.
Plant No. 17 (p. 79).
This plant shows the most striking increase in productivity in the
whole industry. In 1918, as a hand-filled, sand-cast plant, it required
9% man-hours of labor to produce a ton of pig iron. Many changes
took place before the next record was available— a pig machine was
installed at the end of 1918, one stack was abandoned in 1921, and
the other was rebuilt in 1922. The first year of operation with the
new stack (1923) show^s a very poor efficiency record, but even so the
output per man-hour was approximately 50 per cent higher than in
1918. In 1924 the stack was rebuilt again on much larger lines and
at the same time a skip hoist was installed. The results in that year




METHODS OF INCREASING PRODUCTIVITY

59

were rather indifferent, but in 1925 the full effect of the improve­
ments is evident. Productivity was nearly three times greater than
in 1923 and the output per stack-day rose to 432.3 tons. In the last
two years there have been a further increase in stack-day output and a
corresponding increase in productivity. For the first six months of
1927 it required only 2.06 man-hours of labor to produce a ton of
pig iron, as contrasted with the 9.67 hours of 1918. The change in
productivity is accompanied by a decline in the consumption of iron
ore from 4,420 pounds per ton of product in 1923 to 3,821 pounds in
1927 and also by a corresponding decline in coke from 2,462 pounds
to 1,859 pounds and in flux from 1,196 pounds to 874 pounds.
Plant No. 21 (p. 81).

The productivity record at this plant is particularly interesting
because the plant was mechanically filled and machine cast from the
beginning. Its performance in 1919-20 was poor all around. Pro­
ductivity was at a low level, varying from 7.14 hours per ton in 1919
to 8.61 hours in 1920, and the high consumption of ore and coke is
evidence of low operating efficiency. In 1921-22 the stack was
rebuilt and practically doubled in size. The one-month operation in
1922 was too short to furnish any significant data, but in 1923 the
full effects of the rebuilding became apparent. Stack-day output
increased to 448 tons and productivity was practically doubled,
from 0.116 ton per man-hour in 1920 to 0.224 ton in 1923.
In 1925 the stack was relined and its size slightly increased, but the
tremendous increase in productivity since 1923 must be explained on
other grounds. The explanation is to be found in the introduction
of the 8-hour day. This led to the reorganization of the labor force
and the reduction in men which caused the man-hours per ton to
drop from 4.47 hours in 1923 to 2.19 hours in 1926. Between 1920
and 1926 productivity at this plant was increased four times, from
8.61 man-hours per ton to 2.19 hours.
Plant No. 50 (p. 93).

This plant furnishes another illustration of extremely rapid increase
in productivity in a short time. It was mechanically filled and sandcast during 1917 and 1918 when records first become available. The
man-hours per ton varied from 7.13 in 1917 to 7.90 in 1918. In
the following year the stack was increased in size by about onethird and by 1923 productivity had increased to almost double this
amount. The pig machine installed at the end of 1923 showed its
influence on labor time in 1924 when the man-hours per ton were
reduced from 4.56 to 3.08 in one year. The best productivity record
made by this plant was 2.47 hours per ton in 1925. The improved
operating efficiency of the new stack is shown by the coke consumption
which was reduced from 2,507 pounds per ton in 1918 to 2,101 pounds
in 1923.
Plant No. 33 (p. 86).

The continuity of the record for this plant makes the data
unusually important. This is a case where productivity remained
practically stationary for 10 years, and then much more than doubled
itself in 7 years. During the pre-war years 1911 to 1914 the manhours per ton varied from 5.99 to 7.13; while in 1917 to 1920, with a




60

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

slightly higher output per stack-day, the variation was from 5.01 to
7.41 hours. The latter figure, however, may be disregarded for it
contains some relining-labor hours. Between 1920 and 1922 the
output per stack-day was increased somewhat, but the important
factor influencing productivity at this time was the cut in labor crews
after the depression of 1921; the man-hours per ton dropped frcm
6.59 in 1920 to 3.81 in 1922. In 1923 the 8-hour day was introduced,
in 1924 the stack was rebuilt and the pig machine installed, and in
the following year the man-hours per ton fell to 2.69. The remark­
able increase in productivity at this plant in the last 7 years is shown
by the reduction in man-hours per ton from 6.59 in 1920 to 2.41
in 1927.
Plant No. 20 (p. 80).

This plant is quite unique in that it was hand filled and machine
cast for many years. During the war years productivity was low,
the labor requirements per ton of product being 6.14 hours in 1917
and 7.39 hours in 1918. The rebuilding of 1919 did not change the
size of the stack but labor efficiency was increased, for the manhours per ton fell to 5.47. In the next few years productivity steadily
increased with only a slight increase in stack-day output. Then
three important changes occurred at about the same time— the
8-hour day was introduced toward the end of 1923, the stack was
relined and enlarged in 1924, and a skip hoist was installed while the
stack was down for relining. The results became obvious in the
following year when the output per stack-day increased to 418 tons
and the output per man-hour rose from 0.207 ton to 0.345 ton.
There was a noticeable decline in general operating efficiency in 1926,
but a complete recovery took place in the first half of 1927 when
productivity reached the high point— 0.393 ton per man-hour or
2.55 man-hours per ton. The low coke consumption shown in the
data for 1925 and 1927 gives evidence of high smelting efficiency
during those years.
Plant No. 34 (p. 86).

In the pre-war years 1911 to 1914 plant No. 34 had a fairly good
productivity record for a hand-filled, sand-cast plant. The figures
for 1912 and 1914 must be discounted for the relining labor hours are
included in the totals; the man-hours per ton in 1911 were 7.66 and
in 1913, 8.21. During the war productivity declined to very low
levels, reaching 11.02 hours per ton in 1918.* The pig machine
installed in 1919 began to show results in productivity in the following
year. While the stack was being rebuilt in 1921 a new trestle and
bins were added. Two years later a skip hoist was installed on this
stack, and a new stack of much larger size was put in operation.
In 1925 the old stack was abandoned. These improvements led to
the establishment of a liigh-productivity record in 1923 of 5 manhours per ton. Two years later the output per stack-day had more
than doubled but productivity had not increased in proportion,
which means that the economies of two-furnace operation aided in
establishing the record of 1923. In 1926 the man-hours per ton were
reduced to 2.98.




METHODS OF INCREASING PRODUCTIVITY

61

Plant No. 54 (p. 95).
This small Pennsylvania blast furnace, hand filled and sand cast,
required 14.65 man-hours of labor to produce a ton of pig iron in 1911.
Since that year its increase in productivity has been both steady and
rapid. The stack was slightly enlarged in the rebuilding of 1915,
which accounts for the improved productivity in 1918. A later
relining made a further slight increase in the size of the stack, but the
steady increase in productivity in this plant must be attributed largely
to the reduction in the number of men required to operate the furnace.
Mechanical filling, installed in 1921, reduced the labor time per ton
from 9.71 hours in 1920 to 7.21 hours in 1922. The data for 1921 are
for such a short time of operation that the figures may be disregarded.
The pig machine does not appear to have had much effect on the
productivity in 1923, but this is because the saving of labor in this
direction is obscured by increases in other labor groups. In 1926 this
plant required 5.81 man-hours of labor to produce a ton of pig iron.
Plant No. 3 (p. 72).
This plant made an exceptionally good productivity record through­
out the period 1911-1927. It has always had some of the largest
stacks in the merchant-furnace industry and has always ranked near
the top in output per man-hour and output per stack-day. Pro­
ductivity increased from an output of 0.18 ton per man-hour in
1911 to 0.63 ton in the first six months of 1927, which is equivalent
to a reduction in labor time from 5.48 man-hours per ton to 1.59
man-hours per ton. A new and larger stack was built in 1919 and
another one was added in 1925, but this alone is not responsible for
the increased output per stack-day. The steady improvement in
productivity is accompanied by the d e c l i n i n g consumption of ore,
coke, and flux, and the increase in the use of scrap accounts for part
of the increase in stack-day output. - The productivity data for 1919
must be discounted because in that particular year the rebuilding
labor is included in the total man-hours.
PLANTS SHOWING MODERATE INCREASES IN PRODUCTIVITY

Plant No. 53 (p. 94).
The productivity record for this plant is of special interest because
it took place entirely through changes in labor time. There were
no data available on output per stack-day in years prior to 1919, but
from that year down to 1924 there was no upward trend in daily
output, the figures actually declining from 207.9 tons in 1919 to
204.2 tons in 1924. Yet during this same interval the man-hours
per ton decreased from 8.08 to 4.63. Probably the larger part
of the labor-saving was due to the installation of the skip hoist
in 1921, which resulted in a reduction in labor time from 8.46 hours
per ton to 6.29 hours.
Plant No. 31 (p. 85).
The changes in labor productivity in this plant have been almost
wholly determined by three factors— (1) the alternation between one
and two furnace operation, (2) changes in output per stack-day, and
(3) the installation of a pig machine in 1924. The productivity
record is interesting because of the wide fluctuations from year to




62

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

year. Much the larger part of the increase in productivity has
occurred in the last three years. The pig machine undoubtedly is
responsible for this, although a slightly increased output per stackday accompanied by decreased consumption of ore and coke gives
evidence of improved efficiency in operation.
Plant No. 23 (p. 82).

The stack at this plant was completely rebuilt in 1923. It is a
very efficient plant with reference to both productivity and operating
practice. The output per man-hour increased from 0.329 ton in
1923 to 0.526 ton in 1926, largely as a result of an increase in output
per stack-day from 253.4 tons to 376.8 tons. The unusual feature of
the increased daily output is that it has come about through the use
of scrap and improved operating efficiency and not through any
enlargement of the stack. The data on consumption of materials
bring out the striking decline in ore, coke, and flux and the great
increase in scrap.
Plant No. 52 (p. 94).

For the period 1911 to 1916, inclusive, this plant showed little
change in productivity, the output per man-hour varying between
0.085 and 0.095 ton. The rebuilding of 1917 enlarged the stack
slightly, and the productivity increased correspondingly in the fol­
lowing four years. Mechanical filling was installed in 1921-22 with
the result that man-hours per ton decreased from 9.89 hours in 1920
to 6.22 hours in 1923. The productivity in recent years has been
somewhat lower, partly due to a lower output per stack-day.
Plant No. 46 (p. 91).

This is another plant in which the output per stack-day has had no
important part in the increased, productivity. Although the daily
output has fluctuated quite widely over the period there has been no
upward trend, the output in 1911 being 281 tons and in 1926, 270
tons. The one important labor-saving device installed was the pig
machine, but the results of this are not apparent in any one year.
However, this machine undoubtedly had considerable influence in
reducing the man-hours per ton from the previous best record of 7.47
hours in 1911 to the high record of 4.82 in 1924. It is noticeable that
this plant nearly always made its best record in years of partial
operation. This was due to the practice of running for only a few
months with skeleton crews and then doing a good deal of the auxil­
iary iron and materials handling after the stack was shut down
PLANTS SHOWING CONSTANT OR DECLINING PRODUCTIVITY

Plant No. 30 (p. 84).

Productivity at this plant increased slightly from 1914 to 1926
but not enough to show any distinct upward trend. As a matter of
fact the output per man-hour did not increase so much as did the
output per stack-day, which rose from 297 tons in 1914 to 354.6 tons
in 1926. The effect of the pig machine is seen in the data for 1927,
when the best productivity record was made. The influence of this
machine on productivit}r would probably show to much better
advantage were data for the whole year 1927 available. The decline




METHODS OF INCREASING PRODUCTIVITY

63

in operating efficiency during the war is shown by the rise in consump­
tion of coke, and the improvements in recent years are marked by the
steady fall in pounds of coke consumed per ton. Some facts to
be noted in explaining the stack-day output of recent years are the
fall in consumption of ore, increased use of scrap, and complete
elimination of flux.
Plant No. 14 (p. 77).

The decline in productivity shown at this plant from 5.48 hours
per ton in 1911 to 7 hours per ton in 1926 is only apparent for the
latter was not a year of typical operation. Barring the 1912 data,
which show unaccountably low productivity, the average for the
pre-war period would be 5.47 hours per ton while the best recent
record was that in 1924— 4.57 hours per ton. This can not be called
a very marked improvement but at least it does not show a decline
in productivity. Data for 1918 and 1921 must be discounted because
the relining-labor hours are included in the totals. It is clear that
the increase in productivity has been largely due to the installation
of the pig machine in the beginning of 1917, for this immediately
caused a reduction in labor time from 5.46 hours per ton to 4.8 hours.
The higher output per stack-day in the following years does not
appear to have had much influence on productivity for productivity
has never since reached the high mark set in 1917.
Plant No. 32 (p. 85).
This was a modern plant in the beginning, which fact partially
accounts for the very small increase in productivity over the period
covered. The output per stack-da}7 declined from 356.6 tons in 1917
to 323.1 tons in 1924. From 1917 to 1922 productivity fluctuated
closely in accordance with output per stack-day, but in the last two
years of operation daily output declined while productivity increased.
This was due almost entirely to the introduction in September, 1923,
of the 8-hour day in place of the old 10-hour and 12-hour systems.
The full effect of the change is shown by comparing the data for 1922
and 1924; labor time was reduced from 3.27 hours per ton to 2.66
hours.
Plant No. 73 (p. 101).
This is a case of a sharp decline in productivity followed by a com­
plete recovery of the lost ground though with very little net advance
for the period. The year 1911 was one of full operation and good
output and the daily average production of 98 tons was the highest
with one exception up to 1923. Also man-hours per ton in 1911,
9.39, represent the highest record of productivity prior to 1923.
In recent years, 1925 to 1927, the output per stack-day was increased
steadily and the man-hours per ton declined in proportion. The year
1923 is the only exceptional one in the whole period; for some reason
the labor crews were very short that year and productivity reached a
level which has not been attained since.




CHAPTER 5.— GENERAL CONCLUSIONS

This bulletin is devoted to the measurement and analysis of pro­
ductivity changes from 1911 to 1927 in merchant blast-furnace plants.
It is impossible, however, to fully understand the productivity changes
in those plants unless such changes are considered in relation to the
development of the entire pig-iron industry. The annual production
of pig iron has greatly increased during the period studied, but the
total output of strictly merchant plants has not materially changed.
In other words, the “ steel works” branch of the industry has been
rapidly expanding and the proportion of the total pig iron manu­
factured in merchant plants has steadily declined. It may be helpful,
therefore, to review briefly the historical and the present relation of
merchant furnaces to the industry as a whole in so far as it concerns
productivity.
At one time all pig iron was produced in merchant furnaces which
were generally located near ore banks, coal seams, or limestone beds.
In a few exceptional cases forges or puddling and rolling mills were
operated in connection with blast furnaces during the years before
the Bessemer process caused a revolution in the entire iron and steel
industry. Such early integration as existed was not important from
a productivity point of view, however, as the “ continuous process”
of using blast furnace metal for further manufacture while still in
molten condition was impossible with the earlier technique. Before
the expansion of the steel industry pig iron was generally produced
by individual smelters in isolated plants where the output was sold
for further manufacture.
The transition from the old decentralized condition of the industry
to the present large scale integrated operation has been both steady
and rapid. The number of stacks has been cut in half since 1860
while their total capacity has increased tenfold. To an increasing
extent production has been concentrated in greater batteries of
furnaces in steel plants and the number of merchant producers has
steadily declined.
Throughout the history of pig-iron manufacture since the early
stacks the essential principles of smelting have remained unchanged.
Modifications have been made in the rapidity and flexibility of mate­
rial handling, the character of auxiliary equipment, and the size of
the producing unit rather than with the fundamentals of smelting.
Thus it remains practical, where the data are available, to compare
conditions under which a ton of pig iron was produced in the early
blast furnaces with those in later periods.
The progress which has been made in the blast-furnace industry
since 1880 is divided into two distinct stages:
1. The drive to increase tonnage at any cost to meet the mounting
requirements of the steel industry. This drive has been reflected in
the practice of merchant producers as well as of steel works producers.
2. The effort to reduce costs per ton of iron which has followed the
attainment of large tonnages and the tapering off of rate of growth
in iron and steel production. This effort to reduce costs has been
particularly noticeable since the depression of 1921,
04




GENERAL CONCLUSIONS

65

During the first stage iron makers enlarged their stacks and resorted
to hard driving by means of a greater volume of blast heated to higher
temperatures in order to increase production. With this increase in
output, crews were inflated in plants without labor-saving machinery
to aid in caring for the increased product and greater volume of raw
materials.
During recent years the primary emphasis in making pig iron has
been shifted from increase in production to the reduction of costs.
Since the war pig-iron prices have been steadily declining and rigid
economies in furnace operation have taken place. The high wage
rates in many plants forced the development of mechanical methods
of charging and casting in order that the number of men required
per furnace might be reduced. Of course furnace men have gone
ahead enlarging stacks and driving more rapidly, making it possible
for fewer and fewer furnaces to turn out the total output of iron.
This concentration of production has brought lower costs and has
been accompanied by a keen competition among merchant producers,
intensified by the increasing supply of iron coming from integrated
“ steel works” furnaces. This has helped to bring about the recent
improvements in productivity but decreasing profits have brought
renewed pressure for still lower costs and further improvement is
to be expected.
It is worth noting at this point that a blast furnace is not merely
a smelter of iron ores in the manufacture of pig iron; it is a gas pro­
ducer and a slag producer as well. Both gas and slag were formerly
wasted at all plants. Slag may now be sold for road ballast, cement
manufacture, and other uses, while blast-furnace gas is caught,
washed, and used in furnishing power not only for the operation of
blowing engines and other auxiliary equipment for the blast-furnace
department but also for steel mills and industrial concerns. Not
ordinarily rich enough to be used as fuel without further treatment,
surplus blast-furnace gas is commonly wasted by nonintegrated
merchant plants although it is possible to mix it with coke-oven gas
to obtain a satisfactory fuel. An increasing number of merchant
producers of pig iron now operate by-product coke plants as an
essential part of their plant layout, furnishing gas for local, industrial,
or municipal purposes. This integration between coking and smelt­
ing creates several “ joint products” — pig iron, slag, tar, benzol,
toluol, etc. In extreme cases it is often difficult to determine whether
pig iron is a primary product or a by-product. However, it may be
stated that the blast-furnace industry has attained a higher level of
productivity by utilizing its by-products and developing joint prod­
ucts than in the days when the sale of pig iron was the only possible
source of income to iron makers.
The use of scrap in the blast furnace, a recent development since
the war, has increased output per day and the yield of iron per ton
of metal bearing materials in the furnace burden. This is a very
important development which has influenced recent progress in
daily output very materially. Some conservative makers catering
to a discriminating foundry trade willing to pay high prices for good
product may not use scrap. The average merchant maker, how­
ever, finds it advantageous to charge as much of it as good furnace
practice and the current price situation will permit.




66

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

Merchant blast-furnace plants which have continued to operate
in competition with “ steel works” furnaces may be classified as
follows: 1
1. Old plants that can no longer be operated at a profit but the
dismantling or abandoning of which would result in almost a com­
plete loss of capital. Thus they are operated as long as they will
run without repair, in order to liquidate as much of the investment
as possible. Of course, these plants will gradually drop out of the
industry from time to time as their equipment becomes unusable.
2. Plants which have been included as merchant furnaces in this
study but are actually owned and operated by steel companies con­
suming pig iron in further manufacture.
3. Integrated merchant plants operated in conjunction with coke
plants which sell by-products, and coke-oven gas for local, industrial,
or municipal purposes.
4. Isolated nonintegrated plants protected by geographical loca­
tion or grade of product from severe competition by other producers;
for example, plants producing special grades of iron such as highphosphorus iron or those located near a particular market at great
distance from other producers.
The migration of merchant-iron makers westward and the decline
of old producing districts in the East or South (outside the Bir­
mingham district) have been described in an earlier chapter.
Inability of old districts to survive has meant hardship not only for
stockholders and owners, but whole communities have sometimes
virtually disappeared. In such localities the workers have had no
alternative other than migration not merely to new communities
but to new industries, since progress in productivity among the
remaining plants has meant that fewer stacks and fewer workmen
can without difficulty turn out the product formerly made by the
industry with the larger number of furnaces. The effect of increased
productivity on employment in pig-iron manufacturing has taken
this form, primarily causing permanent shut-downs and displace­
ment of entire furnace crews rather than the laying-off of men for a
short time by an operating plant.
The trend in the industry is toward concentration of employment
in large plants controlled by fewer and fewer employers and the
centralized control of the production of merchant iron ii_ integrated
steel-works plants and a limited number of semiintegrated or other­
wise advantageously situated merchant plants. This centraliza­
tion means greater stability of employment and higher productivity
in the industry as a whole.
Increasing production of merchant iron by steel-works stacks and
the diminishing number of merchant furnaces does not at all imply
the disappearance of the merchant producer. It does mean, however,
that the independently operated merchant plants are coming to be
dependent upon some kind of integrated operation. This integra­
tion has led to steadier employment in better equipped and more
highly productive plants located in the large industrial centers.
Standardization of pig-iron specifications would also aid the mer­
chant makers in maintaining regular production.
i Former merchant plants, now acquired by adjacent steel mills, have mq,intained continuous existence
but to-day are no longer a part of the merchant pig-iron industry.







APPENDIXES

67




APPENDIX 1.— GENERAL TABLES
LABOR PRODUCTIVITY, OUTPUT PER STACK-DAY, CONSUMPTION
OF MATERIALS CHARGED, AND CHANGES IN EQUIPMENT, IN
MERCHANT BLAST FURNACES, BY PLANTS AND YEARS, 1911 TO 1927

Table A contains all plants covered by the bureau in this study.
The years are shown in reverse order, that is, 1927 to 1911 as the later
years are of more importance. Data for 1927 cover the first 6 months
only. The average full-time furnaces active have been computed on
that basis. Only those plants visited after July 1, 1927, have fur­
nished data for that year. In practically all cases the description
of equipment applies to one stack in a plant in any one year. How­
ever, in a few plants having more than one stack the change in equip­
ment, particularly the pig machine, applies to all stacks.
When figures do not appear in the table for any year from 1911 up
to the last year for which data aie shown, it is because data were not
obtainable or the plant was not in operation. In the case of a few
new plants entering the industry after 1911 the figures for the first
year shown cover their first year of operation. Footnotes show
the plants which have been idle since the last year for which
data are reported.
The first column of the table shows in round-number classification
the output of pig iron of the plant in each year; exact data are not
given because this might lead to identification of the plant, but the
production groups are small enough to give a close approximation
of the actual figures. The next column shows the average number of
full-time stacks which were active throughout the year. If a stack
ran 365 days a year it will be listed as 1 full-time furnace, while if 1
stack in a 2-stack plant ran 300 days and the other 150 days, the total
for the plant would be 450 days divided by 365 or 1.2 full-time
furnaces. The data in this column are independent of the number
of stacks in the plant, thus 1 full-time furnace may mean that one
stack ran all year or that two stacks operated part of a year each,
or even that three or four stacks were in operation in the course of the
year but that their total stack-days approximated only 365.
The next three columns show the output per man-hour and the
three succeeding columns the man-hours per ton of output. The
output per man-hour is obtained by dividing the total annual pro­
duction of pig iron in gross tons by the total annual man-hours of
labor; the man-hours per ton of product are obtained by doing just
the reverse— dividing the total annual man-hours of labor by the
total annual production of pig iron. The former shows what fraction
of a ton of pig iron can be produced by one man-hour of labor, while
the latter shows the number of man-hours of labor required to produce
a ton of pig iron in this particular plant. For purposes of these com­
putations the total man-hours of labor have been divided into two
parts— the hours worked by the furnace crew proper and the hours
worked by all men outside the furnace crew. The furnace crew has
been defined for these purposes to include all labor directly con-




69

70

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

cerned with the operation of the stack itself, beginning with the charging
labor and ending with the casting labor. In the case of a modern skipfilled machine-cast plant, the furnace crew would begin with larrymen
and skipmen and possibly a few laborers in the stock house, and
would include all men in the cast-house such as foremen, keepers,
keepers’ helpers, stove tenders, water tenders, blowers, mechanical men
permanent^ attached to the furnace, etc. The blowing engineers and
oilers, the boiler-house labor, and the pump-house crew, while directly
auxiliary to the operation of the stack, are excluded from the furnace
crew proper, not so much for logical reasons but in a great majority of
the plants in the industry these groups could not be separated from
the general or miscellaneous labor. The pig-machine labor has been
included as part of the furnace crew. In some plants it was not
possible to make any segregation of the total labor into furnace crew
and “ all other” labor.
In the hand-filled sand-cast plants the same line of division has been
followed, although sometimes the dividing line has been a little more
difficult to draw. On the charging side, it is necessary to include in
the furnace crew all bottom fillers and their helpers, but to exclude all
transportation or delivery of material from stock piles to bins. On
the casting side, the furnace crew would include the sand cutters, the
pig breakers, and the iron carriers who load the iron into cars for
delivery to the yard. In some cases it has been rather difficult to
maintain the proper dividing line and the furnace-crew hours represent
only a fair approximation.
The next column shows the average output of pig iron per stack-day
of operation, and is obtained by dividing the total annual production
by the total number of days the stack was in blast during the year.
This figure should be used in connection with the productivity figure.
The following four columns show the consumption of materials in
the plant, expressed in terms of pounds per ton of pig iron produced.
The figures are obtained by reducing the annual consumption of ore,
scrap, coke, and limestone or dolomite to pounds, and then dividing
the total by the number of tons of pig iron produced. For purposes
of the table, ore is defined to include all flue dust that is purchased
as well as the ore itself; scrap includes not only pure iron or steel
scrap, but also cinder, scale, borings, turnings, pyrites, and all other
such material rich in iron; coke includes coal, if any such is used, but
the amount of coal used in the industry is negligible; flux includes all
material used for fluxing the ore, but it consists ordinarily of limestone,
with occasionally the addition of some dolomite or phosphorous rock.
The next column shows the per cent of pig iron output which was
machine cast. In most cases, once the pig machine was introduced,
this becomes 100 per cent, though there are some important excep­
tions. The iron which is not machine cast may be either sandcast or
run as hot metal to a foundry or open hearth. This last situation is
exceptional, and exists in only two or three plants; as a general rule,
it may be assumed that the metal which is not machine cast is sandcast.
The last column shows technical improvements which have taken
place during the period. This is designed to cover all the more im­
portant changes which may have affected productivity. It includes
the installation of skip hoists, pig machines, the building of a new
stack or the relining of an old one, the abandonment of stack, etc.




T a b l e A .— Labor productivity , production, output per stack-day, consumption of materials charged, and changes in equipment, in merchant

blast furnaces, by plants and by years, 1911 to 1927
PLANT NO. 1
Consumption of materials per
gross ton of pig iron produced

Average labor productivity

Year

450-475
525-550
275-300
500-525
400-425
200-225
475-500

1914.........................

225-250

2.0

Furnace
crew
labor

2.9

0.838
.742
.781
.872
.835
.809
.843

1.8

0)

2.5
1.4
2.7

2.0
1.0

All
other
labor

Man-hours per gross ton
of pig iron produced

Total
labor

Furnace
crew
labor

All
other
labor

1. 083
1.140
.981
.940
.910
.948

0. 497
.440
.464
.462
.442
.428
.446

1.193
1. 347
1 . 280
1.147
1.197
1. 236
1.186

0.818
.923
.877
1.019
1.064
1. 099
1. 054

2.0 12

0)

.243

0)

4.115

1 . 222

0)

Iron
ore

Scrap

Coke

Flux

Per
cent of
produc­
tion ma­
chine
cast

Changes in stack, and charging
and casting equipment

Total
labor

2. 271
2.157
2.166
2 . 262
2. 334
2. 241

Gross
tons
Pounds Pounds Pounds Pounds
617.0
4, 377
132
2,070
862
578.7
159
4, 377
2,031
824
531.9
4,278
228
2,141
876
508.3
177
4, 222
1,958
889
557.3
134
4, 211
1 , 882
838
574.4
4, 153
125
1, 942
962
464. 7
1,934
5, 083
73
1,159
333.4

(2)

(2)

(2)

(2)

100
100
100
100
100
100
100

Abandoned.
Relined in 1919.

100

Mechancially filled; pig machine.

Remodeled; relined.

TABLES

PLANT NO. 2
1926......... ................

275-300

2.3

1.152

0. 524

0. 360

0. 868

1. 909

2. 777

345.6

4, 202

165

2,315

(2)

86

1924.........................
1923......... ................

350-375
425-450

3.0
3.7

.663
.579

.433
.421

.262
.244

1. 509
1. 726

2.312
2. 376

3. 821
4. 102

326.0
330. 8

4, 460
4,162

120

2, 434
2,415

(2)

62
39

1921_______ ______
1920______________
1 9 1 9 ......................
1918.........................

100-125
325-350
300-325
425-450

1.0

.202

. 120
. 168
. 187

3. 388
2. 439
1. 887
2. 033

4. 947
3. 502
2. 880
3. 322

8. 335

3.5
3.0
4.0

.295
.410
.530
.492

5. 941
4. 767
5. 355

284. 8
265.6
291. 7
295. 2

4, 769
4, 861
4, 791
4, 823

(2)
(2)
(2)
(2)

2, 905
3,071
2, 751
2, 794

(2)
(2)
(2)
(2)

1914...................... ..

400-425

3.7

.552

0)

(l)

1.917

0)

302.9

4,652

(2)

2,869

(2)

1 Detail not available.
2 N ot reported.




.286
.347
.301

.210

(0

233

1.— GENERAL

1926.........................
1925.........................
1924.........................
1923.........................
1922.........................
1921........................
1920....................... ..

Gross tons of pig iron
produced per man-hour

Aver­
age
output
per
stackday

APPENDIX

Average
Produc­
full-time
tion in
furnaces
thousands
active
of gross
during
tons
year

Pig machine.

Mechanically filled; sand cast.

T a b l e A . — Labor productivity, production, output per stack-day, consumption of materials charged, and changes in equipment , in merchant

^

blast furnaces, by plants and by years, 1911 to 1927— Continued
PLANT NO. 3

1914......... ................
1913-..................... .
1912
1911....................... ..

150-175
250-275
200-225
150-175




1.5

2.0
1.3

1.0

1.9
1.4

2.0
2.0
1. 2

1.9
1. 5

1.0

1.060
.969
.890
.714
.889
.526
0)
0)
0)
0)
0)

0)
0)
0)
0)

All
other
labor

Total
labor

1. 552
1. 400
1. 205
.997
1 . 060
. 782
0)
0)
C1)
0)
0)

0. 630
.573
.512
.416
.456
.314
.340
.315
. 197
.264
.282

0)
0)
(0
0)

.172
. 196
. 220
. 182

(0

0. 644
.714
.830
1. 003
.943
1. 279
0)
0)
0)
0)
0)

1. 587
1. 746
1. 954
2.403
2. 194
3. 181
2. 943
3. 173
5. 070
3. 784
3. 551

Gross
tons
657.9
648.7
596. 7
524.1
477.5
509.3
525. 5
476.7
399.8
397.4
408.1

0)
0)
0)
(0

0)
0)
0)
0)

5.819
5. 099
4, 549
5. 483

477.8
353.9
397.7
417.5

0.943
1. 032
1.125
1. 400
1. 251
1.902
0)
0)
0)
0)

Iron
ore

Scrap

Coke

Flux

Per
cent of
produc­
tion ma chine
cast

Pounds Pounds Pounds Pounds
(2)
(2)
(2)
(2)
741
437
1, 792
3, 821
862
249
1, 872
4, 072
744
403
1,902
3, 774
896
363
2,100
3, 804
921
376
2,068
3, 954
941
63
2, 148
4,518
9
2,206
1, 077
4,514
965
2 , 220
28
4, 610
970
9
2, 216
4, 679
871
13
2,158
4, 702
4, 554
4, 675
4, 536
4,437

73
4
43

2, 422
2, 428
2, 230
2,388

1,156
1, 203

1,10 2 >
1,194

100
100
100
100
100
100
100
100
100
100
100
100
100
100
100

Changes in stack, and charging
and casting equipment

New furnace built.

Do.

Mechanically filled; pig machine.

FURNACES

225-250
450-475
425-450
275-300
325-350
225-250
175-200
325-350
175-200
275-300
275-300

Furnace
crew
labor

Aver­
age
Man-hours per gross ton
output
of pig iron produced
per
stackday
All
Furnace
Total
other
crew
labor
labor
labor

BLAST

1927 3.......................
1926............. ............
1925_______ _____ _
1924._____ _______
1923______________
1922_____________
1921._____ _______
1920..................... ..
1919.................... __
1918.______ ______
1917______________

2.0
2.0
2.0

Gross tons of pig iron
produced per man-hour

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

JZfQ

PLANT NO. 4
100-125
275-300
275-300
250-275
300-325
175-200
25- 50
300-325
225-250

1917.........................

400-425

1914 .........................
1912_.......................

(2)
4,140
4,019
4,028
4, 075
4,072
4,128
4,198
4,108

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

(2)
2,004
1,986

2. 486
2. 434
4. 108
4. 6>0
5. 278
4.216

564.0
527.3
617.8
549.2
517.7
416.0
351. 2
389. 3
373. 0

0)

3. 071

376.8

3,972

0)

0)

4. 612

283.9

0)

0)

4.503

251.0

(0
0)

0)
0. 599
.639
.510
.532
0)
0)
0)
0)

0. 572
.445
.476
.402
.411
.243
.214
. 189
.237

2.9

(0

0)

.326

0)

175-200

1.9

0)

0)

.217

225-250

2.6

(0

0)

.222

1.0

1.5
1.3
1.3
1.7

1.2

0.4

2 .1
1.8

0)
1. 731
1 . 868
1. 907
1. 795
0)
0)

0)
0. 578
.535
.524
.557
0)
0)
(»)
0)

CO
1. 669
1. 565
1. 962
1. 877
0)
0)
0)
0)

1. 749
2. 246

2.100

2,108
2, 084
2,034

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

(2)
< 32
« 27
* 26
^ 33
4 11
^8
4 35

(2)

2,022

(2)

<25

Rebuilt in 1916.

4,476

(2)

2, 332

(2)

« 34

Rebuilt.

4,196

(2)

2 , 366

(2)

8 27

Mechanically filled; pig machine.

2 ,1 1 2
2, 072

2 , 068

4 44

Abandoned.
Rebuilt.
Relined.

1.6

125-150
350-375
325-350
150-175
300-325
200-225
50- 75

1919.........................

175-200

1.4

0)

1913.........................
1912_.......................
1911,.......................

175-200
125-150
150-175

1.5

0) '
0)
0)

1.9

2.0
1.0
2.0
1 .2
.5

1 .1
1.3

0. 366
.377
.414
.284
0)
0)
0)

0. 281
.290
.295
.215
.318
.235
. 181

2. 736
2.651
2.416
3. 517
0)
0)
0)

3. 560
3. 450
3. 390
4. 641
3.141
4. 248
5. 512

498.9
506.2
457.7
451.3
444.6
‘450. 0
395.4

3, 576
3, 470
3, 683
3, 555
3, 667
3,900
4, 424

362.2

4,621

320.8
351.7
341.8

4,411
4,639
4,491

0)

. 137

0)

0)

7. 276

0)

.161
.148
. 158

0)
0)
0)

t1)
0)
0)

6. 226
6. 742
6. 330

0)
0)

1 Detail not available.
* Production not shown as machine cast, used molten.




0. 824
.799
.975
1.124
0)
0)
0)

1,613
1, 663
1,803
1, 773
1, 848
1,870
2,178

806
777
831
750
784
961
1, 203

100
100
100
100
100
100
100

Relined.

(2)

2,280

1,107

100

Rebuilt; relined in 1915.

(2)
(2)
(2)

(2)
(2)
(2)

(2)
(2)
(2)

100
100
100

Relined.
Mechanically filled; pig mac

484
475
363
517
437
352
16

Rebuilt.

TABLES

1. 213
1. 252
1 . 026
.890
0)
0)
0)

1927 3.......................
1926........................
1925....... ..................
1924......... ...............
1923 _ .......................
1922. ................... ..
1921........................

1.— GENERAL

PLANT NO. 5

APPENDIX

1927 *.......................
1926..........................
1925........................1924........................
1923 _ ....................
1922. .......................
1921...................... .
1920_ .......................
1919__.....................

a N ot reported.
8 First 6 months only.
* Production not shown as machine cast, is partly used molten or sand cast.

00

T a b l e A . — Labor 'productivity, production , output per stack-day , consumption of materials charged, and changes in equipment , in merchant

blast furnacest by plants and by years, 1911 to 1927 — Continued
PLANT NO. 6

125-150
225-250
275-300
225-250
300-325
150-175
100-125
300-325
250-275
250-275
200-225
75-100
275-300
200-225
225-250

2.0
1.8
2 .2
2.0

2.5
1.4

1.0
2.6
2.5

2.8
2.3
2.9
2.9

2.0
2.5

Furnace
crew
labor

1 , 216
1 . 006
.924
0)
0)
0)
0)
.597
.556
.444
.469
.529
.549
.498
.436

All
other
labor

0. 610
.393
.475
0)
0)
0)
0)
. 288
.218
.209
.204
.255
.271

.20 1
.239

Total
labor

0.406
.283
.314
.251
.248
.241
. 143
. 194
. 157
. 142
. 142
. 172
. 181
. 143
. 154

Man-hours per gross ton
of pig iron produced

Furnace
crew
labor

0. 822
.994

1 . 082
0)
(*)
0)
0)
1. 675
1.799
2. 251
2. 134
1. 891
1 . 822
2. 009
2. 291

All
other
labor

Total
labor

1.640
2. 543
2.104
0)
0)
0)
0)
3. 472
4. 579
4. 773
4. 905
3. 927
3. 693
4. 985
4.192

2. 463
3. 536
3.187
3. 982
4. 033
4. 155
7. 002
5. 147
6. 379
7. 023
7. 039
5. 818
5. 514
G. 994
6. 484

Aver­
age
output
per
stackday

Iron
ore

Scrap

Coke

Flux

Per
cent of
produc­
tion ma­
chine
cast

Gross
tons
Pounds Pounds Pounds Pounds
408.5
(2)
(2)
(2)
(2)
359.1
3, 943
1,952
23
860
341.7
4,086
896
29
2,071
317.2
4, 368
1,051
2 , 268
76
325.4
1,004
4, 325
58
2. 244
322. 5
4,173
44
1,039
2, 234
312.6
4, 267
36
2 , 181
1,0 21
4, 341
319.8
2
,
367
1,089
30
279. 6
4, 359
2, 499
1, 077
101
253.4
4, 384
2,619
1,100
26
261.6
4, 274
2, 393
1, 039
29
285. 2
934
4, 097
11
(2)
285.2
2,140
(2)
(2)
(2)
862
286.8
4, 191
8
2 ,120
4,213
2,243
1, 024
270.2
47

100
100
100
100
100
100
100
100
100
100
100




2.0
1.9

2.0
1.9

1.8
1 .2

0. 848
.816
0)
0)
0)
.736

0. 515
.424

0)
0)

.308

0. 321
.279
.270
.250
.231
.217

1.179
1.226
0)
0)
0)
1.359

1. 940
2. 358
0)
0)
C1)
3.249

3.119
3. 584
3. 703
3. 999
4. 322
4. 607

410.0
392.8
363.1
375.5
346.8
350.3

(2)
3,618
3, 774
3, 718
4, 234
4,231

(2)
372
237
262
45
103

(2)
2, 042
2,146
2, 088
2, 209
2,148

(2)
993

1 , 1 11
999
1,030
1, 030 |

D o.
D o.
Relined pig machine.

100
100
100
100
100
100

FURNACES

125-150
250-275
250-275
250-275
225-250
150-175

Relined.
D o.

Rebuilt.
Mechanically filled; sand cast.

PLANT NO. 7
1927 3.......................
1926.................
1925..........................
1924..........................
1923..........................
1922..........................

Changes in stack, and charging
and casting equipment

BLAST

1927 3.......................
1926______ ______ _
1925______________
1924________ _____
1923..........................
1922 _ .....................
1921 _ ...................
19206-_ ...................
1919 6. . . .................
1918 «____________
1917 8____________
1916 7____________
1915______________
1914
_ ___
1913______ ______ _

Gross tons of pig iron
produced per man-hour

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

1921......................... Under 25
1920.........................
200-225
1919.........................
175-200
200-225
1918.................. ...
1917.........................
225-250

.2
1.8
1 .6
2.0
2.0

0)
0)
0)
0)

0)
0)
0)
0)

1913______________
1912______________
1911______ _______

1.7

1.8
1 .2

.523
.544
.440

175-200
175-200
125-150

.616

.227

.155
. 151
. 128
. 153
. 166

(!)
0)
0)
0)
1. 624

.326
.332
.267

.201
.206
.166

1.914
1.837
2. 272

6.444
6. 633

4.405

7. 793
6. 554
6. 029

375.5
317.0
304.3
297.9
314.0

4,390
4, 451
(2)
(2)
(2)

3.067
3. 016
3.750

4. 981
4. 853
6. 023

291. 5
289.5
318.5

(2)
(2)
(2)

0)
0)
0)
0)

22
22
(2)
(2)
(2)

2, 050
2,407
(2)
(2)
(2)

1,131
1, 239
(2)
(2)
(2)

100
100
100
100
100

(2)
(2)
(2)

(2)
(2)
(2)

(2)
(2)
(2)

100
100
100

6 Fiscal year M a y 1 to Apr. 30.

Do.
Rebuilt in 1914.

Mechanically filled;
rebuilt.

7 Jan. 1 to Apr. 30 only.

100-125
50- 75
75-100
150-175

0.7
.4
.4

1 .1

0. 520
. 522
.375
0)

19 1 4 ...................
1913______________

100-125
200-225

1.0
2.0

0)
0)

1. 223
1.227
1.135
0)

0)
0)

0. 365
.366
.263
.294
. 170
. 162

1. 921
1. 915
2. 669
0)

(0
0)

0.818
.815
.881
0)

2. 739
2. 731
3. 804
3. 407

441.1
453.5
566.3
382.0

3, 750
3, 837
4,090
4,137

(0
0)

5. 886
6.171

314.3
288.2

(2)
(2)

482
197
104
28
(2)
(2)

2,
2,
2,
2,

239
297
290
301

•(2)
(2)

(2)
(2)
(2)
(2)

100
100
100
100

(2)
(2)

Mechanically filled; pig machine;
relined in 1918 and 1922.
Sand cast; method of charging not
reported.

PLANT NO. 9
75-100
175-200
150-175
125-150

1 .1
1.0
1.0

0. 988
.910
.984
.930

0. 790
.785
.800
.762

0. 439
.421
.441
.419

1.099
1 . 016
1. 075

1. 265
1.274
1. 250
1.312

2. 277
2. 375
2 . 266
2. 388

404.7
380.9
431.7
430.0

4, 041
4,316
4,171
4,458

255
278
251
405

2,024
2, 218
1,938
2, 079

632
632
515
544

100
100
100
100

1 9 2 2 .......................

125-150

1.0

.784

.642

.353

1. 276

1.557

2. 833

378.1

4,122

115

1,895

737

100

1920.........................
1919.........................
1918..........................

250-275
175-200
175-200

2.0

.883
.728
.629

.724
.597
.515

.398
.328
.283

1.132
1. 373
1. 590

1.381
1.676
1.941

2.513
3.049
3. 531

350.1
308.0
286.0

4, 081
(2)
(2)

48
(2)
(2)

2 , 006

806
(2)
(2)

100
100
100

1.3

1.7
1.9

1 Detail not available.




3 Not reported.

(2)
(2)

3 First 6 months only.

Rebuilt in 1923.

Rebuilt.
Mechanically filled;
rebuilt.

TABLES

1 . 012

1927 a.......................
1926______________
1925______________
1924______________

1.— GENERAL

1926.........................
1925______________
1924________ _____
1923______________

APPENDIX

PLANT NO. 8

P L A N T N O . 108
T a b le A .— Labor productivity, production, output per stack-day, consumption of materials charged, and changes in equipment, in merchant
blast furnaces, by plants and by years, 1911 to 1927 — Continued

1918— ...................

225-250

1.8

1914 9...................
1913
.............
1912 »____________
1911
.................

125-150
175-200
100-125
125-150

1.3
1.7

1.0
1.0

Gross tons of pig iron
produced per man-hour

Furnace
crew
labor

0)
0)
0)
0)
0)

All
other
labor

Total
labor

0)

0 .112

(*)
0)
0)
0)

.117
. 120
.087
.119

Aver­
age
Man-hours per gross ton
output
of pig iron produced
per
stackday
Furnace
All
Total
other
crew
labor
labor
labor

0)
0)
0)
0)
0)

0)

8.920

C1)
0)
0)
0)

8. 523
8. 303
11.434
8. 382




0.3
.9

.2
1 .1

3.4
1.5
4.7

0. 295
.214
.218
.148
.146
.134
.141

0. 267
.206
.225
.153
.139
.115
.128

0.140
. 105
. I ll
.075
.071
.062
.067

3. 385
4.664
4. 586
6. 744
6.830
7.451
7.082

3. 748
4.845
4. 436
6. 523
7. 215
8. 694
7. 792

NO.

7.133
9. 509
9. 021
13. 267
14. 045
16.146
14.874

193.0
171.1
206.5
127.6
136.0
141.0
120.7

Coke

Flux

Pounds Pounds Pounds Pounds
2, 214
930
3, 459
190
4, 500
4, 303
4, 211
4, 288

100

Rebuilt.

42
106
166
90

2,732
2,512
2,514
2, 748

1,347
1,130
1,223
1,318

100
100
100
100

Mechanically filled; pig machine.

289
125
92
132
426
379
361

2, 498
2, 657
2,614
3, 558
2,911
2, 798
3,082

(2)
(2)
(2)
(2)
(2)
(2)

100

11
3, 954
4, 552
4, 075
4, 608
3, 526
3, 828
4,299

0

61

100
100
79
85
81

Rebuilt; idle since 1924.
Remodeled.
Abandoned.
Rebuilt; hand filled; sand cast;
mechanically filled; pig machine.

FURNACES

1924........................ Under 25
1923.........................
50- 75
1922..... ..............
Under 25
1921....... ..................
25- 50
150-175
1920_.......................
1919..... ....................
75-100
1918........................
200-225

287.6
316.2
312.8
374.2

Scrap

Changes in stack, and charging
and casting equipment

BLAST

PLANT

Gross
tons
345.5

Iron
ore

Per
cent of
produc­
tion ma­
chine
cast

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

PLANT NO. 12
225-250
200-225
200-225
175-200
125-150
25- 50
175-200
100-125
150-175
150-175

1.7
1.4
1.5

1914..........................
1913..........................
1912__.....................
1911..........................

75-100
150-175
100-125
75-100

1.0
2.0

1.6
1 .1
.4

1.6
1 .2
2.0
2.0

1.4
.9

0
0
0)
0
0
0)
0)
0)
0)
0)

0
0
0
0
0)
0
0
0)
0)
0)

0.529
.478
.449
.343
.290
.249
.231
.172
.171
.168

0
0
0)
0
0)
0)
0)
0)
0)

0
0)
0
0

0)
0
0)
0)

. 149
. 162
. 152
.150

0)
( 1)
(1)
0)

0)
0)
0)
0)
0)
0)
0)
0)
0)
0)
0)
(1)
0)

1. 890
2.093
2.227
2. 917
3. 447
4.011
4.327
5.824
5. 846
5. 959

396.7
391.1
366.5
330.7
324.8
311.7
323.6
241.4
213.2
232.8

4, 090
4,030
4,050
(2)

6. 697

266. 6
229! 8
24o! 8
249.3

(2)
(2)
(2)

6.171
6*. 588
6.667

0

PLANT
225-250
175-200
125-150
150-175
150-175

1 .2
1.0
.9

1.0
1.0

0

0. 766
.720
.674
.786

0)
1 .12 2
1.032
.975
.977

0.465
.455
.424
.398
.436

0)
1.305
1. 390
1. 484
1.272

0

.891
.969
1.026
1.024

2.149
2.197
2.358
2. 510
2.296

PLANT

520.5
503.3
464.1
462.6
460.3

NO.

0
(2)
(2)
(2)

1 , 820
1,808
1, 887
2,103
2,240
1,972
1,973
2,174
2,341
2,386

726
750
865
(2)
(2)
1,165
(2)
(2)
(2)
(2)

100
100
100
100
100
100
100
100
97
51

2 391
2 292
2 425
2, 250

m)
\
V)
\)

(2)
(2)

1,990
1,932
1,960
1,997
1,909

1,196
1,196
1,288
1,252
1,331

* 88
* 74

\/

0
4k 0

(2)

(2)

4,467
4, 296
4,384
4,245
4,229

(2)
(2)

13

0

<84
4 79

4 88

0.4

0.423

0. 216

0.143

2.362

4.635

6.997

300.8

4, 260

<*>

2,218

1, 277

100

75-100
200-225

.6

.516
.497

.380
.388

.219
.218

1.938

2.010

2.630
2.578

4. 568
4. 588

354.5
341.0

4,308
4,426

0
0

2,124
2,119

1,191
1,328

100
100

1921..........................
1920..........................
1919.........................
1918_........................
1917— .....................

50- 75
175-200
200-225
175-200
175-200

.342
.426
.421
.?59
.429

.325
.403
.398
.340
.405

.167
.207
.205
.175
.208

2.924
2.345
2.376
2.782
2.333

3.073
2.480
2.512
2.942
2.467

5.997
4. 825
4. 888
5. 724
4.800

395.9
347.8
.353. 5
285.5
300.0

4,406
4,386

0
0
0
0
0

1,995
2,155

1,192
1,409

100
100
100
100
100

1914..........................
1913..........................
1912_........................
1911..........................

150-175
200-225
125-150
25- 50

.376
.335
.361
0)

.356
.403
.307
0)

.183
.183
.166
.182

2.656
2.988
2.770
0)

2.807
2.480
3.255

5.463
5.467
6.025
5.483

284.4
286.7
286.0
289.0

4,411
4,375
4,337
4,406

1 Detail not available.

.5

1.6
2.0
1.4
.5

s N ot reported.
* Production not shown as machine cast, used molten.




0

0

4, 296
4,442

0
0

2

0

0

0

2,174
2,138

1, 644
1,463

2,375
2, 297
2,173
2,143

1,530
l) 401
l) 230
1,118

Relined.
Do.
Relined; pig machine.

Hand filled; sand cast.

8 Merchant furnace 1911 to 1918, inclusive. Integrated with steel plant 1919 to 1927, inclusive.
» Fiscal year.

TABLES

25- 50

1.7
1.7
1.7

Mechanically filled; pig machine.

14

1924..........................
1923..........................

1.6

Pig machine installed in 1918.

Mechanically filled; sand cast.

0

1926........................

1.7

Remodeled.

1.— GENERAL

1926.
1925.
1924.
1923
1922.

NO.

0

4, 296

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

APPENDIX

1926........................
1925_.......................
1924..........................
1923........................
1922.........................
1921..........................
1920..........................
1919_.......................
1918_.......................
1917.........................

•<!

T a b l e A . — Labor productivity, production, output per stack-day, consumption of materials charged, and changes in equipment , in merchant

^

blast furnaces , by plants and by years , 1911 to 1927— Continued

PLANT

NO.

15

50- 75
175-200
175-200
75-100
75-100
50- 75
Under 25
150-175
100-125
150-175
150-175

1.0
2.0
2. 0
0. 9

1 .1
.6

.l

1. 9

1. 6
2. 0
1.9

Furnace
crew
labor

0. 310
. 263
. 259
. 273
. 239
. 265
. 137
. 189
. 180
. 188
0)

All
other
labor

Total
labor

0. 306
i 421
.439
.285
. 303
.273
. 121
. 177
. 157
. 169
0)

0.154
. 162
. 163
. 139
. 133
. 134
.064
.091
.084
.089
. 106

Aver­
age
Man-hours per gross ton
output
of pig iron produced
per
stackday
All
Furnace
Total
crew
other
labor
labor
labor

3. 226
3. 803
3. 855
3. 665
4.190
3. 777
7.318
5. 290
5. 542
5.313
0)

3.271
2 . 378
2, 275
3.512
3. 304
3. 667
8, 279
5. 656
6. 384
5. 911
0)

6.497
6.181
6.130
7.177
7.494
7. 444
15. 597
10. 946
11. 926
11. 224
9. 457

NO.

Scrap

Coke

Flux

Pounds Pounds Pounds Pounds
181
2, 699
5, 237
210
2, 930
5, 772
260
2,970
5,918
2
217
4
2, 994
6, 003
578
6,124
3, 300
502
3, 328
6, C30
11
780
3, 376
5, 649
3,310
730
63
5, 755
54
3, 398
526
5, 938
5, 824
2
3, 228
446
3, 204
750
43
5, 701

Rebuilt.

Relined.

Hand filled; sand cast.

16

1926.

75-100

0.7

0. 854

0. 685

0. 380

1.171

1. 461

2. 632

392.3

4, 070

73

2,282

(2)

100

1924.
1923 _
1922.
1921.
1920.
1919_
1918.

50- 75
125-150
50- 75
Under 25
125-150
100-J125
150-175

.3
.7

1.105
0)
C1)
0)
C1)
C1)
0)

.429
i 1)
(x)
C1)
(*)
(x)
0)

.309
.280
.371
.332
.246
.269
.272

.905
0)
(»)
0)
0)
C1)
C1)

2. 329
0)
C1)
0)
(»)
«

3.233
3. 566
2. 697
3.016
4. 066
3. 717
3.672

512.0
493.4
613.0
513.1
438.3
455.7
452.3

3,913
3, 792
(3)
4,084
3, 922
(2)
(2)

199
249
(2)
170
242
(2)
(2)

1 , 996
2,120

912
900
(2)
965
1,055
(2)
(2)

100
100
100
100
100
100
100




.2
1

.

.9

.6
1 .0

Changes in stack, and charging
and casting equipment

(2)

2 ,10 1
2,092
(2)
(2)

Relined.

FURNACES

PLANT

Gross
tons
316.2
250.5
247.2
278.2
237.3
256.5
218.1
223.3
212.5
209.8
229.5

Iron
ore

Per
cent of
produc­
tion ma­
chine
cast

BLAST

1927 3
1926
1925
1924
1923
1922
1921
1920
1919
1918
1917

Gross tons of pig iron
produced per man-hour

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

1917........................
1916_.......................
1915_.......................
1914 .........................
1913 ..................... 1912-......................
1911__.....................

175-200
100-125
125-150
125-150
125-150
125-150
100-125

1 .0

.7
.9

1 .0
.9
.9
.9

C1)
0)
C1)
C1)
C1)
C1)
C1)

C1)
(*)
C1)
C1)
C1)
C1)
C1)

. 314
.294
.313
.274
.308
.299
.313

(l)
0)
(l)
«

3.180
3. 404
3.197
3. 653
3. 252
3. 340
3. 200

(l>
C1)
C1)
0)
(l)
C1)
«

0)
O

PLANT
75-100
150-175
150-175
50- 75
50- 75

1.0
1 .0
1.0

1918-.......................

100-125

1.7

.4
.7

1. 562
1. 507
1.372
«
G)

0.706
.673
.615
0)
0)

0. 486
.465
.425

0. 640
.664
.729

. 154

0)

(l)

.103

«

.222

•

NO.
492.2
474.6
432.3
335. 2
265.0

3, 821
3,860
4, 043
4,144
4, 420

9. 666

176.7

(2)

C1)

.5

1 .0
.5
1.5

1.8

0.509
.455
.429
.471
.422
.383
. 532
. 149
.171
. 156
C1)

0. 390
. 278
.326
.361
.392
.287
.334
. 184
.203
.213
(l)

1 Detail not available.

0.221
. 173
. 185
.204
.203
. 164
.205
.082
.093
.090

.1 1 1

2.197 | 3.599
2. 330 ' 3.064
2.124
2. 774
2. 369
2. 551
2.613
3. 484
1. 879
2. 998
6. 705
5. 442
5.856
4. 937
6. 409
4. 692
C1)
C1)

4. 530
5. 796
5. 395
4.898
4. 919
6.097
4. 877
12.147
10. 793

1 1 .1 0 1
9.009

252.4
233.1

210.8
233.0
226.5
205.4
243.8
215.1
233.7
194.3
215.9

* N ot reported.

(2)
(2)
1,064
(2)
(2)
(2)
(2)

100
100
100
100
100
100
100

343
325
242
159
376

1,859
1, 901
2, 047
2 , 211
2, 462

874
831
755
918
1,196

100
100
100
100
100

(2)

(2)

Mechanically filled; pig machine.

(2)

6

Rebuilt; mechanically filled.
Abandoned in 1921; remodeled in
1922.
Hand filled; sand cast; pig ma­
chine.

18
5,667
5, 564
5, 864
6, 061
5, 916

6,001
5, 658
5, 582

6,102
6,171
5, 690

2, 990
3, 072
32 I 3,228
16
2 . 888
4
3, 028
3, 290
16
3, 002
18
3, 446
13
3, 602
3,828
20
3,444

11

468 !
392 1
502
282
600
533
591
786
524
831
739

Relined.

Mechanically filled.
Rebuilt.

TABLES.




1.9
1.4

2.0
2.0
2.0
1 .2

NO.

(2)
(2)
2,024
(2)
(2)
(2)
(2)

1.— GENERAL

75-100
100-125
150-175
150-175
150-175
75-100
25- 50
75-100
25- 50
100-125
125-150

1
1.964 1 2.566

(2)
(2)
108
(2)
(2)
(2)
(2)

17

1. 416
2. 056
2.149
1.486
1. 625
2. 354
* 4. 509
C1)
6. 474
(l)

PLANT
1927 3.......................
1926 .......................
1925______________
1924........... .............
1923_ ______ ______
1922________ _____
1921 ................ ....
1920-.....................
1919_.......................
1918 .......................
1917_ .......................

(2)
(2)
3, 882
(2)
(2)
(2)
(2)

APPENDIX

1927 *.......................
1926........................
1925_ .....................
1924 .......................
1923_ .......................

489.5
445.9
450.9
382.4
389.0
385.3
385.0

Rebuilt; hand filled; sand cast.

* First 6 months only.

•<!
CO

T a b l e A . — Labor productivity , production , output per stack-day, consumption of materials charged, and changes in equipment, in merchant

blast furnaces, by plants and by years ,

PLANT

NO.

L0

1914..........................
1913..........................

50- 75
75-100

.5

1.0
.6
.3
.9
.7
.3
.7

1.0
1.0
1.0
.8

0.707
.727
.708
.679
.334
.338
.237
.232
.270
0)
0)

0)

.297

0. 713

.668
.813
.877
.518
.562
.411
.421
.441
0)
0)

0)

.399

Total
labor

0.355
.348
.379
.383
.203

.2 1 1
.150
.150
.167
. 147
.167
. 161
. 170

Furnace
crew
labor

1.415
1. 375
1.412
1. 472
2. 992
2.963
4. 222
4. 305
3. 704
0)
(’)

0)
3. 369

All
other
labor

Total
labor

1.402
1.498
1.229
1.140
1.932
1. 779
2.431
2.377
2.267
0)

2.817
2.873
2.642
2 . 612
4. 924
4. 741
6.653
6. 682
5. 971
6. 785

(0
0)
2. 507

6.001

Gross
tons
414.8
432.5
387.1
367.2
344.8
336.5
321.3
314.0
333.2
342.5
352.9

6.209
5.876

317.2
274.3

50-75
75-100
150-175
75-100
125-150
75-100
75-100




1.0
.6
1 .0
.8
1.0
.8
.7

1.289
1.226
1. 250
.606
.526
.471
0)

0. 565
.427
.477
.314
.356
.409
0)

0. 393
.317
.345
.207

.2 1 2
.219
.178

0. 776
.816
.800
1,651
1.900

2 .12 1

C1)

1. 770
2.342
2.099
3.187
2.808
2.445
0)

NO.

2.546
3.157
2.898
4.837
4. 708
4.566
5.613

412.0
378.0
418.0
346.0
377.0
356.0
367.0

Iron
ore

Scrap

Coke

Flux

Pounds Pounds Pounds Pounds
2,180
932
4,455
206
2 ,110
2 11
4,303
983
4,426
103
2,285
1,060
2,173
4,319
1,093
143
3,956
327
2,300
1,245
244
1,068
4,115
2,196
4,657
2,516
1,537
(2)
4,516
2,543
1,185
(2)
2,334
992
4, 563
(2)
2, 272
4,415
1,048
(2)
2,236
905
4,413
(2)
(2)
(2)

(2)
(*)

(2)
(2)

(2)
(2)

2,015
2,167
2,060
2,265
2 , 210
2, 233
2,209

925
1,084
1,033
1,068

Per
cent of
produc­
tion ma­
chine
cast

100
100
100
100
100
100
100
100
100
100
100

Changes in stack, and charing
and casting equipment

Rebuilt.
Mechanically filled.

Pig machine installed in 1915.
Hand filled; sand cast.

FURNACES

PLANT
1927*.
1926...
1925__.
1924...
1923...
1922...
1921...

Aver­
age
output
per
stackday

20
3,622
3,147
3,293
3,848
3,770
3,940
4,254

645
851
627
435
676
517
237

1.10 2
1,107
1,205

100
100
100
100
100
100
100

BLAST

50- 75
150-175
75-100
25- 50
100-125
75-100
25- 50
75-100
100-125
100-125
125-150

All
other
labor

Man-hours per gross ton
of pig iron produced

PRODUCTIVITY— MERCHANT

1927 >.......................
1926..........................
1925..........................
1924.........................
1923..........................
1 9 2 2 .......................
1921........................
1920..........................
1 9 1 9 .......................
1918.........................
1917..........................

Furnace
crew
labor

LABOR

Year

Gross tons of pig iron
produced per man-hour

00

0

19
Consumption of materials per
gross ton of pig iron produced

Average labor productivity
Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

Jo 1927— Continued

Relined, mechanically filled.

1920..........................
1 9 1 8 .......................
1917..........................

100-125
100-125
125-150

1.0
1.0
1.0

0)

0)
C1)
0)

0)

0)

0.183
. 135
.163

0)
0)
0)

0)
0)
0)

0.7

1 . 202

.6
.8
7
’. 1

1.119

.686

1 .0 1 1

.620

1920
.............
1919..........................

50- 75
50- 75

.8

.

.7

0)
(0

0. 736
'

0)

0)

0)
C1)
0)
0)

0.456
.425
.384
.224
.227
. 116
.140

0. 833
.893
.988

0)
(0
0)
0)

1. 359
1. 458
1.612

0)
0)
0)
0)

1920. ______ ______
1918....................
1917.........................

100-125
100-125
100-125

1.0
1.0

1913.........................
1912............. ............
1911........................

100-125
100-125
25- 50

.8
1.0

* Detail not available.




1.0
.8
.7
.7

.9

.4

0. 294
.326
.229
.327
.312

0
0)

21
2,040
(*)
1, 994 1 (2)
2, 018 ; (2)
2 .1 2 1
(2)
2, 356
(2)

100
100
100
100
100

2,451
2,386

(2)
(2)

100
100

Mechanically filled; pig machine.

325 ! 2,120
336 ; 2,091
363 ! 2,123
2,245
314
2,224
161

999
1,077
1,077
3,3 79
1,219

4 48
444
100
100
100

Relined.

Remodeled.

486. 2
505.8
504.6
448.0
340.6

3,922
4,234
3, 992
3,839
4, 232

234
128
172
125
(2)

8. 605

242.8
243.7

4,778
4,487

35

7.141

N O .

11

7.374
5. 830

324.0
296.0
370.0

4,153
3,947
4,498

347
340
57

2,481
2,340
2,390

1,326
1,118
1, 239

100
100
100

5. 011
4. 851
6. 562

335.0
330.0
337.0

4,321
4,254
4,496

163
175
71

2,264
2,340
2,292

1,277
1,219
1,301

100
100
100

0)
0)

.155
.136
.172

0)
0)
2. 500

0)
3.330

.519
.501
.522

.324
.350
.215

.200

1.926
1.997
1.915

3.085
2.854
4.647

* fir st 6 months only.

Relined.
Rebuilt.

22

6. 464

0)
0

* N ot reported.

Hand filled; pig machine.

0

C1)
0)

.206
.152

3,958
4,151

386. 0 1 3,897
392. 0 . 3,883
381. 0 ! 3,671
4,043
431.0
4,140
419.0

0)
0)
0)
0)

.300

Rebuilt in 1919.

100
100

3. 401
3. 066
4. 364
3. 055
3.203

0)

.400

100

1,109
995

0)
0)
0)
0)

0)

0)
0)
0)

(l)
0)
0)

1,098

2,387
2, 217

Mechanically filled; pig machine.

TABLES

0.9

2, 245

452
166

1.— GENERAL

125-150
125-150
100-125
100-125
100-125

468

2.193
2. 351
2 . 600
4. 466
4.412

P L A N T
1926................. ........
1 9 2 5 . .............. ..
1924______ _______
1923_______ ______
1922.........................

NO.

4,030

APPENDIX

100-125
100-125
150-175
100-125
Under 25

315. 0
366.0

7. 391
6.140

PLAN T
1926..........................
1925.........................
1924..........................
1923......................
1922..........................

341.0

5.472

* Production not shown as machine cast is used molten.

00

T a b l e A . — Labor productivity, production, output per stack-dayconsum ption of materials charged, and changes in equipment , in merchant

QO

blast furnaces , by plants and by years , 1911 to 1927— Continued

PLANT

NO.

1 9 2 6 ..................
1925................. ........
1924______________
1923______________

125-150
75-100
50- 75
25- 50

1.0
.8
.6
.5

Furnace
crew
labor

1. 353

1.12 0
1.197
.847

Man-hours per gross ton
of pig iron produced

All
other
labor

Total
labor

Furnace
crew
labor

All
other
labor

Total
labor

0.861
.713
.762
.539

0. 526
.436
.466
.329

0.739
.893
.835
1.181

1.161
1. 403
1.312
1. 855

1.900
2. 295
2.347
3.037

PLANT
0)
0)
0)
0)

(2)
(2)
(2)
(2)

0)
0)

C1)
C1)

0. 268
.131

.2 1 1
.222

0)
0)
0)
0)

0)
0)
0)
0

3.729
7.645
4. 744
4. 508

PLANT
1926.........................
1925______________
1 9 2 4 .....................
1 9 2 3 .......................
1920..................... -

1.0

125-150
125-150
100-125
125-150

.8
1.0

75-100

.8




.9

C1)
0)
0)
0)

0)
0)
0)
0)

.383

.586

0. 536
.473
.389
.459
.232

0)
0)
0)
0)
2. 610

NO.
(2)
(2)
(2)

NO.

Scrap

Coke

P ounds Pounds Pounds Pounds
912
585
1,821
3, 212
1 ,1 2 2
452
2,173
3, 373
1,0 12
473
2,172
3, 530
1,183
2 , 201
4,113
16

4,341
(2)
3,994
(2)

Rebuilt; mechanically filled; pig
machine.

114
(2)
150
(2)

2, 471
(2)
2,327
(2)

(2)
1,149
(2)

100
100
100
100

1,2 10

(2)
(2)
(2)
(2)

100
100
100
100

Remodeled in 1922.

100

Mechanically filled; pig machine.

Idle since 1923.
Mechanically filled; pig machine.

25

0)

368.3
374.8
408.9
356.0

3,909
3, 909
4,001
3, 976

(2)
(2)
(2)
(2)

2,008
2,070
2,113
2 , 218

1.707

4.318

286.4

4,079

(2)

2,391

1.866

100
100
100
100

24

2.116
2. 570
2.179

0
0)
0)

Flux

Changes in stack, and charging
and casting equipment

Relined.

FURNACES

25- 50
Under 25
125-150
100-125

Gross
tons
376.8
323.6
320.7
253.4

Iron
ore

Per
cent of
produc­
tion ma­
chine
cast

BLAST

1 9 2 3 .......................
1921.........................
1920______________
1919........................

Aver­
age
output
per
stackday

PRODUCTIVITY— MERCHANT

Year

Gross tons of pig iron
produced per man-hour

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity
Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

23

P L A N T
1927 3 _ _ _ .......................
1926
.................

50- 75
125-150

1 .0 11

1.0
1.0

.971

0.710
.659

0.417
.393

0.989
1.030

1.408
1.517

N O .

2.397
2. 547

PLANT

.5

1.0
.1
1.0
1 .2
1. 6
1.0
1.4

.8
.6

0.751
.412
.534
.741

0.393

.559
.458
. 505
.474
.480
.393
.598
.498

.221

.216
.280
.278
. 181

.200
.209
. 198
.224
.171
.198

.202

2. 543
4. 630
3. 574
3. 592

3. 874
7. 054
5. 445
4.942

360.5
185.0
332.7
360.7

2,858
3, 297
2,925
3,111

757
896
909
811

2,124
3, 075
2,275
2, 214

(2)
(2)
(2)
(2)

.159
. 130
.143
. 145
. 140
.143
.133
.142

1.789
2.183
1.979
2.109
2. 084
2. 543
1. 673
2.006

4. 518
5. 512
4. 998
4. 790
5.053
4. 470
5. 855
5. 058

6. 307

249.9
223. 9
237.3
205.5
226.1
208.6
206.0

3,546
3, 651
3, 235
3,344
3,862
3, 689
3,907
4, 070

332
408
614
540
119
240
262
96

2, 250
2, 227
2,487
2, 562
2, 547
2, 062
2, 524
2 , 622

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

7. 695

6. 977
6. 899
7,137
7. 014
7. 527
7.064

1913.
1912.
1911.

75-100
75-100
75-100




0.8
.6
.5
.7
.5
.5

.8
.6
.7

1.0
.7

.6
.6

Also pig ma­
chine and skip hoist installed.

Rebuilt.

Hand filled; sand cast.

.

0.631
0)
0)
0)
.381
.365
.361
.355
.291
.291

0)
0)
0)

1 Detail not available.

0.672
0)
0)
0)
.642
.655
.443
.456
.309
.456

0.326
.321
.278
.241
.239
.234
.199
.150
.178

1.585
0)
0)
0)
2. 625
2. 741
2. 769
2.813
3. 439
3.431

0)
0)
0)

.152
.172
.168

0)
0)
0)

.200

NO.

28

1.488
0)
0)
0)
1.558
1.526
2 . 260
2.193
3. 231
2.195

3.072
3.117
3. 601
4.150
4.183
4. 267
5.028
5.007
6. 670
5. 625

454.4
441.5
444. 4
402.4
416.0
398.5
394.4
396. 7
324. 5
318.3

3, 768
3, 734
3, 703
3, 683
3, 588
3, 658
3, 732
3, 772
3, 934
3, 801

421
419
390
401
426
444
430
421
450
444

1,985
2, 092
2, 053
2, 253
2,138
2, 251
2,283
2, 220
2,489
2,439

1,084
1,138
1,310
1,501
1,478

0)
0)
0)

6. 561

319.6
359.7
360.2

(2)
3, 833
(2)

(2)
336
(2)

(2)
2,233
( 2)

(2)
1,301
(2)

* N ot reported.

5. 833
6.136

1,046
1,066
1 , 068
1,035

100
100
35

Pig machine.
Rebuilt.

1,0 10

TABLES

125-150
75-100
75-100
100-125
75-100
50- 75
100-125
75-100
75-100
100-125

100
100 Relined.
100
100* Rebuilt in 1922.

1

PLANT
1926.
1925.
1924.
1923
1922.
1921.
1920.
1919.
1918
1917.

2 12 .1

Mechanically filled; pig machine.

27

1.331
2. 424
1.871
1.350

0. 258
.142
.184

100
100

815
977

1.— GENERAL

1921 .................... Under 25
1920 .................
75-100
1919 __________
100-125
1918 .................
100-125
1917 ____________
75-100
100-125
1916______________
1915 ____________
50- 75
1914_ .....................
25- 50

1.0

(i°)

NO.

2,095
2, 214

4,489
4, 252

APPENDIX

125-150
1926..........................
1925______ ______ _ Under 25
1924................ .......
50- 75
1923______________
125-150

383.0
366.1

26

Do.

Hand filled; sand cast.

Plant operated less than 18 days during the year.

00
CO

T a b l e A * — Labor productivity , production, output per stack-day, consumption of materials charged, and changes in equipment , in merchant

QO

blast furnaces, by plants and by years, 1911 to 1927— Continued

PLANT

NO.

1914 ®.......................
1913 *........... ...........
1912«____________

100-125
125-150
100-125

0.8
1.0
.9

Furnace
crew
labor

All
other
labor

Total
labor

(9
0)
(9

0)
(9
(9

0.231
.242
.219

Man-hours per gross ton
of pig iron produced

Furnace
crew
labor

(9
(9
(9

All
other
labor

0)
(9
(9




2.0 !
2.0 1
1.9

2. 0
2.0
1. 7
.4
1.9

1.8
2.4
3.0
2. 7
2. 2

2.0

(9
(9
(9
0)

0)
0)
(9
(9
(9
0)
(9
0)
(9
(9

(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9

0.152
. 130
. 135
. 144
. 139
. 149
. 137
. 125
. 112
.098
. 123
. 136
. 137
.127

(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9

(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9
(9

Scrap

Coke

Flux

Changes in stack, and charging
and casting equipment

Gross
tons
4. 336
368.0
4.130 i 360.0
347. 0
4. 570

NO.

6.597
7. 669
7. 403
6. 956
7. 204
6.711
7. 307
8. 019
8.940
10.180
8.136
7. 328
7. 280
7. 891

380.5
354. 6
315.8
321. 9
319. 1
337.8
337.8
273.2
277. 5
209.4
248. 1
283.6
270.8
297.0

Pounds Pounds Pounds Pounds
4,133
2,103
212
1,2 12
4,316
| 2,282
1,174
(2)
3, 857
333
2,186
1. 271

< 100

4 100
< 100

Pig machine; hand filled.

30
5, 564
5, 598
5,748
5,858

6,120
6,044
5, 967
6, 205
6, 241

6,100

6,115
5, 956
6, 308
5, 593

379
432
405
414
321
316
255

222

215
305
269
228

211
184

2 , 682
2 , 680
2, 784
2,984
3, 032
2 , 886
2,712
3, 204
3, 228
3, 362
3, 202
2,890
3, 074
2, 874

(2)
(2)

20

100
31

Pig machine.
Relined.

40
181

211
258
567
553
925
903
564
260
437

Do.
Do.
Do.
Do.
Rebuilt.
Do.
Mechanically filled;

BLAST FURNACES

I

125-150
250-275
200-225
225-250
225-250
200-225
50- 75
175-200
175-200
175-200
250-275
275-300
200-225
200-225

Iron
ore

Per
cent of
produc­
tion m a­
chine
cast

Total
labor

PLANT
1927 3____________
1926..........................
1925
1924
1923
1922
1921
1920
1919
1918
1917
1916
1915
1914

Aver­
age
output
per
stackday

PRODUCTIVITY— MERCHANT

Year

Gross tons of pig iron
produced per man-hour

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity
Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

29“

PLANT NO. 31
25- 50
50- 75
50- 75
50- 75
50- 75
25- 50
Under 25
50- 75
50- 75
100-125
125-150
75-100
50- 75
50- 75
50- 75
75-100
50- 75

1.0
1.0
1.0
1.0
1.0
.6
.1

1.0

1.2
1.7
2.0
1.6
1.0
1.0
1.0
1.3
1.0

0. 504
.529
.477
.425
.425
.483
.398
.467
.451
.478
.513
.434
.419
.439
.409
.452
.379

0. 331
.319
.290
.248
.193

.212
. 176
.152
.148
. 187
.204
.184
.172
. 185
.175
.190
.148

0.200
.199
.181
.157
. 133
.147

.122
.115

.111
.134
.146
.129

. 122

. 130
. 123
.134
.106

3. 023
3.131
3.443
4. 032
5.188
4.712
5. 683
6. 575
6. 764
5. 348
4. 901
5. 435
5. 826
5.418
5.716
5. 266
6. 753

1. 982
1. 892
2. 096
2. 355
2. 353
2. 072
2. 510
2.143
2. 217
2.091
1.948
2.305
2.386
2. 277
2.443
2.211
2.639

5.005
5.023
5. 539
6. 387
7. 542
6. 784
8.192
8. 718
8.981
7.439
6. 851
7. 740

.

8 212
7. 695
8.158
7.477
9. 392

1 Detail not available.
* N ot reported.




0.898
.730
.627
.677
.631
.611
.635

.686

0.646
.692
.597
.639
.572
.571
.606
.599

0. 376
.355
.306
.329
.300
. 295
.310
.320

1.114
1.371
1.595
1.478
1.585
1. 638
1. 576
1.458

®Fiscal year.
* First 6 months only.

1.547
1.445
1.676
1.564
1.749
1. 752
1.650
1. 670

2 . 662
2.816
3. 270
3. 043
3. 334
3. 390
3. 225
3.128

323.1
336.1
318.5
347.1
340.3
319.9
337.6
356.6

242
316
18
(2)

100
100
100
82

22

157
683
573
403
724
412
(2)

Relined.
Relined; pig machine.
Relined.

D o.
Do.
Do.
Do.

0
(2)
(2)
224
486

Do.
Mechanically filled; sand cast.

32
2,197
2,948
4,231
4,189
4, 328
3,886
4, 269
4, 229

1, 552
974
255
244
(2)

211

(2)
30

2,035
2,142
2,466
2, 354
2,311
2,286
2,108
2,005

952
1,055
1, 351
1,445
1, 248
1, 272
1, 384

1,20 1

100
100
100
100
100
100
100
100

Idle since 1924.

Mechanically filled; pig machine.

11 Merchant furnace plant 1911-1916, inclusive; integrated with steel plant 1917.
* Production not shown as machine cast is used molten.

TABLES

25- 50
100-125
25- 50
50- 75
75-100
100-125
100-125
100-125

1924.
1923
1922
1921.
1920
1919.
1918
1917.

NO.

2.836
2, 804
3,024
3,168
3, 022
3,134
3, 386
3, 300
3,406
3,188
2, 978
3,042
3, 205
2, 996
3,168
3, 256
3, 484

1.— GENERAL

PLANT

206.4
203.7
182.8
177.2
181.0
177.2
163.0
171.7
164.8
171.6
175. 7
167.4
179.4
192.4
181.8
164.8
158.1

APPENDIX

1927
1926.
1925.
1924.
1923.
1922.
1921.
1920.
1919.
1918.
1917.
1916.
1915
1914
1913
1912
1911.

00

O*

T able

A . — Labor productivity, production, output per stack-day, consumption of materials charged, and changes in equipment, in merchant
blast furnaces, by plants and by years , 1911 to 1927— Continued

PLANT

NO.

75-100
75-100
75-100
75-100

1914______________
1913______________
1912______________
1911.........................

50502550-

75
75
50
75

.7

1.0
.5
.9

1.0
.9
.9

.8
.9
.5

1.0

Total
labor

Furnace
crew
labor

All
other
labor

Total
labor

Iron
ore

Scrap

Coke

0.415
.341
.371
.284
.266
. 263

1.091
1.359
1. 394
2. 063
2. 395
2.412

1.319
1.573
1.298
1.453
1.365
1.394

2.410
2. 932
2. 692
3. 516
3. 760
3. 806

Gross
tons
359.0
325.0
321.0
303. 0
308. 0
303.0

.449
. 527
.428
.627

.152
. 164
. 135

.200

4. 365
4. 202
5. 077
3. 412

2. 229
1.898
2. 335
1.595

6. 594
6. 100
7. 412
5.006

264.0
253. 0
245. 0
258. 0

4, 639
4,101
4,128
3, 824

41 !
127 i
170 |
174

.481
.524
.440
.464

. 145
. 167
. 140
. 148

4. 795
4. 077
4. 855
4. 597

2. 078
1.910
2. 274
2.153

6.873
5.987
7.129
6. 750

203. 0
221 . 0
227. 0
198.0

3, 956
4,180
4, 075
4, 325

64 1 2,290
74
2, 492
85
2, 344
634 1 2,156
I

0.917
.736
.717
.485
.418
.415

0. 758
.636
.771

.229
.238
. 197
.293
.209
.245
.206
.218

.688
.733
.717

PLANT

NO.

Flux

Pounds Pounds Pounds Pounds
4,243
305
668
2,000
4,126
259
2 , 262
670
4,216
176
2 , 262
767
4, 446
136
815
2,316
4, 209
193
2, 300
1 , 010
4, 341
143
2, 334
1,149
2,308
2,302
2,302
2, 296

Per
cent of
produc­
tion m a­
chine
cast

100
100
100
33

1,192
945
874 '
1,167
921

Rebuilt.

1,10 2
’ 916
1,068

Mechanically filled; sand cast.

34

100-125
25- 50

0.7
.3

0. 685
.577

0.659
.687

0. 336
.314

1.460
1. 732

1. 518
1. 456

2.978
3.188

442.7
439.9

3,518
3, 548

58
54

1,898
1, 945

694
773

100
100

1923.........................
1922........................
1921..........................

75-100
Under 25
25- 50

1 .2
.1

.368
.394
.352

.437
.309
.279

.200

2.714
2. 539
2. 843

2.286
3.232
3. 586

5.000
5. 772
6. 428

197.1
213.6
219.9

3, 839
3, 407
3,815

226
197
119

3,055
2,671
2,615

1,176
1, 072
1,006

100
100
100




.173
.156

Rebuilt; pig machine.

Relined.

1926______ _____ __
1925....... ..................

.5

Changes in stack, and chargin
and casting equipment

Abandoned.
New furnace; mechanically filled.
Rebuilt.

FURNACES

1920........................
1919............. ..........
1918.........................
1917_____ _____ _

0.6
1.0
1.0

All
other
labor

Aver­
age
output
per
stackday

BLAST

25- 50
100-125
100-125
75-100
100-125
50- 75

Furnace
crew
labor

Man-hours per gross ton
of pig iron produced

PRODUCTIVITY— MERCHANT

1927 8__...................
1926______________
1925.........................
1924______________
1923________ _____
1922_______ ______

Gross tons of pig iron
produced per man-hour

LABOR

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

33
Consumption of materials per
gross ton of pig iron produced

Average labor productivity

QC

1920.
1919.
1918
1917.

50Under
5050--

75
25
75
75

1914.
1913.
1912
1911.

25502550-

50
75
50
75

.268
.217

(2)

0

0)

(2)
(2)
(2)
(2)

0

0
0
0)
0

.205
. 169

0
0

00
0)
0

.116
.095
.091
.097

..090
122

. 104
.131 !

3. 735
4. 609

(9

0
0
0)
0
0

4. 891
5. 925

0
0

0)
0
0)

0

8. 626
10. 534
11.012
10.313

171.4
171.1
(2)
(2)

9. 565
8. 208
11.168
7. 659

(2)

PLANT
25- 50

0.3

75-100
100-125

.9

1.0

0)
0

0. 247

0)
0)
0.249 ;

0.198
. 100
. 125

0)
0)
4. 045

1920______________
1919....... ..................
1918______ _____ __
1917..........................

75-100
50- 75
50- 75
75-100

.8
.6

.8
.8
.3

.9

1.0




50- 75
100-125

0.8
.8

0
0
0
0

0
0
0
0

0
0
0
0

Relined.
Do.
Hand filled; sand cast.

35

5. 041

370.0

4,137

40

2,042

1,116

100

0

10 . 021
8. 030

267.0
287. 0

3, 860
3, 985

394
298

2, 342
2, 367

1,172
1,107

100
100

3. 985

NO.

Rebuilt 1920; idle'since 1923; aban­
doned in 1927.
Pig machine; method of charging
not reported.

36

0. 427
.430
. 445
.309

1.077

.620

0. 789
.828
0)
.614

1.120
0
1 . 612

1 . 268
1 . 120
0)
1 . 628

2. 345
2. 328
2.245
3.240

334.9
317. 9
329.6
260.5

3, 575
3, 250
2,516
3, 338

392
768
1,245
703

2, 084
2,119
2, 047
2, 364

724
737
757
916

100
100
100
100

.554
.288
.299
.279

.601
.552
.496
.475

.288
. 189
.187
.176

1.805
3. 477
3. 345
3. 580

1. 665
1.811
2.017
2.103

3. 470
5. 288
5. 362
5.683

257.3
241.0
217.7
213.5

3,846
3, 620
3, 510
2,782

459
730
788
1, 467

2,613
2, 652
2, 497
2, 588

1,382
1, 472
1,351
1, 241

100
100
100
76

Pig machine; hand filled, sand
cast.

435
349

1, 878
2,014

820
999

100
100

Mechanically filled; pig machine.

0. 929
.893

0

PLANT
1927
...................
1926..........................

0
0
0
0

Pig machine.

0

1.185
.740

0.451
.282

i Detail not available.

0. 327
.204

0.844
1.351

2. 217
3. 551

NO.

3. 061
4.902

459. 7
401.0

2 N ot reported.

Relined; mechanically filled.

TABLES

0.9

0
0
0

1.— GENERAL

100-125
75-100
75-100
Under 25

100
100

1, 263

0
0
0

0

PLANT
1926______________
1925______________
1924______________
1923______________

2, 584

0
0
0

0
0
0

NO.

370

0
0
0

APPENDIX

1923 — ...................
1918.........................
1 9 1 7 --....................

3,098

37
3,241
3, 544

8 First 6 months only.

00
^1

T a b le

A .— Labor 'productivity, production, output per stack-day, consumption of materials charged, and changes in equipment, in merchant
blast furnaces, by plants and by years,
Zo 1927 — C ontinu ed

PLANT

NO.

1927 3 _ _ _ ............... ..
1926..... ................
1925______________
1924______________
1923______________

50- 75
100-125
75-100
25- 50
25- 50

1.0
1.0
.9
.4
.5

Furnace
crew
labor

0. 525
.543
.546
.400
.407

All
other
labor

0. 339
.352
.373
.263
.247

Total
labor

0. 206
.214

.222
. 159
.154

Man-hours per gross ton
of pig iron produced

Furnace
crew
labor

1.906
1. 841
1.830
2. 503
2. 455

All
other
labor

Total
labor

2.947
2. 837
2 . 682
3. 800
4.054

4.851
4. 678
4.513
6.303
6.509

Aver­
age
output
per
stackday

Gross
tons
289.6
299.9
299.8
219.5
223.1

Iron
ore

Scrap

Coke

Flux

Pounds Pounds Pounds Pounds
4
4,800 i
3, 200
1,828
2
3, 082
4,525 1
1, 637
3,186
1,398
4,776 1
5,210
3, 931
1,891
5,103 |
3, 385
2,000

Changes in stack, and charing
and casting equipment

Relined.
Mechanically filled; sand cast.

1

PLANT

1.0
.8
.8
1.0
.2
.8
.6
.8
.6

0. 212

W

0.391
.381
.407
.400
.422
.428
.372
.402
.367
0)

.202

2.427
2. 250
2. 462
0)

0. 466
. 451
.466
.458
.467
.473
.412
.444
.406

.207
. 217
.213

.222
.225
. 196

.2 1 1
. 193

2.157
2. 215
2.147
2.185
2. 423

2 ,1 1 2

39

2. 490
2. 725
0)

4. 713
4. 841
4. 605
4. 688
4.507
4.451
5.113
4.739
5.187
4. 960

278.2
268.4
241.6
255.1
263.5
261.0
249. 7
260. 1
241.7
285.2

2,802
2, 484
2,807
2,876
2, 760
2,489
2,636
2, 531
2,536
2 , 536

916
1,129
936
685
885
1,191
1,026
1,133
1,232
1,149

2, 331
2, 598
2, 499
2,417
2, 492
2, 485
2,515
2, 473
2, 685
2,516

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

2. 556

2 . 626
2.459
2.503
2. 367
2.338

2.686

1915

. .

100-125

1.0

0)

0)

.214

0)

0)

4. 684

282.4

2 ,374

1,230

2, 544

(2)

1912

.................

50- 75
50- 75

.5

0)
0)

0)
0)

. 144
.095

C1)
0)

0)
0)

6. 967

294.7
249.8

(2)
(2)

(2)
(2)

(2)
(2)

(2)
(2)

.........




.7

10. 535

100
100
100
100
100
100
100
100
100
100

Relined.

Do.
Pig machine in 1916.

Rebuilt; mechanically filled.
Hand filled; sand cast.

FURNACES

0.4

NO.

BLAST

25- 50
75-100
50- 75
1924_ ....................
75-100
1923______________
75-100
1922....... ..................
1921_ ___________ Under 25
50- 75
1920______________
50- 75
1919______________
50- 75
1918- ............ ..........
50- 75
1917_______ ______

1926________ _____

10 11 .......

Per
cent of
produc­
tion ma­
chine
cast

PRODUCTIVITY— MERCHANT

Year

Gross tons of pig iron
produced per man-hour

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity
Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

38

jm

PLANT NO. 40
1927 a.......................
1926.........................
1925.........................
1924_ .................
1923.........................

1.0
.6
.8
1.0
1.0

50- 75
50- 75
50- 75
100-125
75-100

0.350
.345
.248
.318
.292

0. 255
0.147
. 251 . . 145
. 181
. 105
.231
.134
.2 12
.123

2. 857
2. 900
4. 025
3.144
3.427

3. 929
3.989
5. 535
4. 324
4.713

6. 786
6. 889
9. 560
7.468
8.139

322. 7
317.9
229.1
293. 3
269.1

3,763
4,312
4,941
4, 614
5, 275

473
388
311
414
208

2 , 808
3,143
3, 586
3,111
3, 786

1,165
1,160
1,351
1,172
1,626

Relined.
Mechanically filled; sand cast.

CO

PLANT
50- 75
100-125
100-125

0.5

1919_......................
1918-.................... ..
1917-................

50- 75
75-100
75-100

41

0. 497
.440
.403

0.180
. 166
. 159

3. 536
3. 736
3. 798

2.014
2. 273
2.484

5. 550
6.009
6. 282

329.7
293.0
290.9

4, 081
4,213
4,182

(2)
(2)
(2)

2,0 11
2,179

1,138
1,124
1.243

.5
.9

. 180

.108

.8

.239

.270
.303
.334

5. 560
4.948
4.181

3. 707
3. 299
2.990

9. 267
8. 247
7.171

286. 0
260.6
289.0

4, 202
4, 274
4, 334

(2)
(2)
0)

1,994
2,458
2,207

1,292
1,496
1.243

.202

.1 2 1
.139

PLANT

NO.

1,720

Idle since 1925.
Relined in 1921.

Hand filled; sand cast; relined.

4 2

100-125
50- 75

1.0
.6

0. 695
.541

0. 363
.283

0. 239
.186

1. 438
1. 848

2. 754
3. 540

4.192
5.388

283.4
247.0

(3)
(2)

0)
0)

0)
0)

0)
0)

100
100

1923.........................

50- 75

.8

.202

.257

.113

4. 943

3.884

8.827

230.8

(2)

0)

0)

0)

100

Relined; skip hoist installed in
1924.
Rebuilt in 1922.

1920........... ..............
1919______________
1918-.......................
1917-.......................

25- 50
50— 75
50- 75
50- 75

.8
1.0
0)

0)
0)
0)
0)

0)
0)
0)
0)

.072
.085
.082
.075

0)
0)
0)
0)

0)
0)
0)
0)

13. 941
11.819
12.186
13. 245

169.9
194. 6
189.4
0)

(2)
(2)
(2)
(2)

0)
0)
0)
0)

0)
0)
0)
0)

0)
0)
0)
0)

100
100
100
100

Rebuilt; pig machine.

1914_ ______ ______
1913............. ............
1912_______ ______
1911..........................

50505050-

(2)
(2)
(2)
(2)

0)
0)
0)
0)

0)
0)
0)
0)

.093
.092
. 119
.124

0)
0)
0)
0)

0)
0)
0)
0)

10. 720
10. 849
8. 383
8. 066

(2)
(2)
(2)
(2)

(2)
(2)
0)
0)

0)
0)
0)
0)

0)
0)
0)
0)




75
75
75
75

.9

1 Detail not available.

(2)
0)
(2)
0)

a N ot reported.

Hand filled; sand cast.

8 First 6 months only.

TABLES

1926-.....................
1925.........................

1.— GENERAL

0. 283
.268
.263

1.0
1.0

APPENDIX

1925.........................
1924__....................
1923.........................

NO.

T a b l e A . — Labor 'productivity, production, output per stack-day, consumption of materials charged, and changes in equipment, in merchant

>0

blast furnaces, by plants and by years, 1911 to 1927— Continued

PLANT

N O . 43

Gross tons of pig iron
produced per man-hour

Furnace
crew
labor

All
other
labor

Total
labor

0.406
.429
.364
.421
.324
. 365
.266
.269
.259

0.317
.291
.261
.313
.233
.281
.281
.259
.286

0.178
.173
.152
. 180
. 136
.159
.137
. 132
. 136

Aver­
age
Man-hours per gross ton
output
of pig iron produced
per
stackday
Furnace
All
Total
crew
other
labor
labor
labor

Gross
tons
25- 50
1925..........................
50- 75
1924.........................
25- 50
1923_____ _____ _
1922______________
75-100
1921......... .............. Under 25
25- 50
1920................. ........
1919.........................
50- 75
75-100
1918..........................
1917..........................
75-100

0.3
.7
.7

1.0

(i°)

.6
.9

1.0
.9

2.461
2. 330
2, 745
2.372
3. 083
2. 739
3. 757
3. 722
3. 859

3.153
3. 441
3. 826
3.197
4. 286
3. 560
3. 563
3. 863
3. 491

5.614
5. 772
6. 571
5.569
7.369
6. 299
7. 320
7.585
7.351

3,033

0)

6. 792

280.3

3,987

0)

9.104

203.9

0)

0)

0.145

0)

0)

1917

100-125

1.0

0)

0)

.147

0)

1913

25- 50

.6

0)

0)

.1 1 0

0)




Flux

Idle since 1925.
Relined.

New furnace, mechanically filled;
sand cast.

N O . 44
281.6

0 .2

Coke

Pounds Pounds Pounds Pounds
3,414
9
1,767
4,661
3,147
1,644
4, 583
16
204
4, 829
3, 309
1, 557
4, 771
3,086
3,121
887
5, 320
2,907
1, 024
4
4, 782
904
3, 006
4, 723
2, 947
1,516
4, 809
4,422
1,366
2, 536

6.904

Under 25

1923.........................

236.1
192.4
220.9
169.5
217.7
204.3
206.3
252.5

Scrap

Changes in stack, and charging
and casting equipment

0

327

2,195

(2)

99

2,181

(2)

(*)

(*)

(2)

100

Relined in 1919; pig machine in
stalled in 1920; furnace aban­
doned in 1924.

Method of charging not reported;
sand cast.

BLAST FURNACES

PLANT

220.8

Iron
ore

Per
cent of
produc­
tion ma­
chine
cast

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

PLANT NO. 45
1926.........................
1925.........................
1924.........................
1923.........................

75-100
100-125
50- 75
50- 75

0.9

1920..........................

75-100

.8

1914..................... ..

75-100

1 .0

1.0
.6
.6

0)
0
0)
0
0.377

0

0)
0
0
0
0. 592

(0

0.259
.288
.255
.224

0)
0)
0
0

.230

2. 651

.188

0

0)
0)
0
0)
1.689

0

3. 856
3. 471
3. 923
4.459

298.2
276.8
293.3
287.5

3,947
3,904
3,916
3,873

0
0
0
0

2,076
2, 309
2,234
2,263

0
0
0
0

100
100
100
100

Relined.

4.340

267.6

4,146

0

2,344

0

100

Relined and pig machine installed
in 1918.

5.311

216.7

75-100
75-100
75-100
75-100
75-100
50- 75
50- 75
25- 50
75-100
25- 50

.2
.6
.1
.9

.8
1.0
.9

1.0
.6
.7
.4

.8
.5

0.442
.435
.460
.360
.396

0. 367
.390
.379
.374
.412

.315
.300
.319
.300
. 297
.272
. 217
. 187
. 198
.223

.327
.312
.332
.312
.309
.314
.325
. 281
.297
.334

0. 200

.202

2.727
2.566
2.641
2. 670
2.429

4. 991
4. 865
4. 815
5. 447
4.954

270.0
291.9
144.3
298.1
281.8

3,985
3,951
3,994
3,824
3,689

.
.
.
.
.
.
.
.
.
.

3. 175
3. 332
3.132
3. 337
3. 369
3. 677
4. 603
5. 337
5. 048
4. 479

3.054
3.204
3. 011
3.209
3.240
3.186
3.074
3. 564
3.372
2.992

6.229
6. 536
6.141
6.545
6. 608
6. 863
7. 677
8.901
8.420
7.471

283.8
262.6
279.4
264.9
259.7
245.6
275.1
235.9
249.4
281.1

3,976
3, 868
3, 985
3, 860
3, 868
3,967
3, 580
3, 821
3, 774

161
153
163
153
151
146
130

112
119
134

PLANT
1926.
1925.
1924.
1923.
1922.
1921.
1920.
1919.
1918.

Under 25
25- 50
25- 50
50- 75
Under 25
Under 25
25- 50
50- 75
75-100




0 .1
1.0
.9

1.0
.2
.2
1.0
.9

2.0

0
0)
0
0
0
0)
0
0
0

1 Detail not available.

0
0
0)
0
0
0
0
0
0

46

2. 264
2. 300
2.174
2.777
2. 525

. 206
.208
.184

0.115
. 122
.096
. 122
.117
. 119
. 112
.099
.089

0
0
0
0
0
0
0
0
(0

0
0
0
0
0
0
0
0
0

2 Not reported.

NO.

8. 693
8.191
10.450
8. 218
8. 567
8. 371
8. 960
10.096
11. 285

124.2
133.1
132.6
155.8
148.9
155.1
130.0
155.1
132. 9

Hand filled; sand cast.

0

0

201
323
370
181
383
139
392
314
390
367
340

611

661
656

0

2 , 206
2 , 212
2,170
2,216
2,316

1,080
1,136
1,149
1,080

2, 225
2, 248
2,229
2,288
2, 280
2,380
2,390
2, 541
2,366

1.185 ‘
1, 279
1,234

0

1,0 12

0

1,216
1, 389
1, 254
1,404
1,512

0

100
100
100
100
100

Abandoned in 1927.

100
100
100
100
100
75

Pig machine.
Rebuilt.
Mechanically filled; sand cast.

47
5, 604
5, 609

0

4, 995
5,342

0
0
0

4,406

2, 663
2, 489

0

2, 424
2,426

0
0
0

1, 508

3,631
3, 772

0

3,155
3, 386

0
0
0

2,836

0
0
0
0
0
0
0
0
0

TABLES

1920.........................
1 9 1 9 .......................
1918..........................
1917..........................
1916.........................
1915________ _____
1914______________
1913......... ............ ..
1912________ _____
1911................. ........

0.5
.3

0

1.— GENERAL

1926..........................
25- 50
1925..........................
25- 50
1924......... ................ Under 25
1923......... ................
50- 75
1922......... ................ Under 25

NO.

0

APPENDIX

PLANT

0

Relined.

Do.
Rebuilt.
Hand filled; sand cast; mechan­
ically filled.

10 Plant operated less than 18 days during the year.

CO

T a b l e A . — Labor 'productivity , production , output per stack-day , consumption of materials charged , and changes in equipment, in merchant

O

blast furnaces, by plants and by years, 1911 to 1927— Continued

P L A N T N O . 48

Year

Gross tons of pig iron
produced per man-hour

Furnace
crew
labor

Aver­
age
output
per
stackday

Man-hours per gross ton
of pig iron produced

All
other
labor

Total
labor

Furnace
crew
labor

0)

0 . 201

0)

All
other
labor

Total
labor

0)

4.985

Gross
tons
247.0

Iron
ore

Scrap

Coke

Flux

Per
cent of
produc­
tion ma­
chine
cast

Changes in stack, and charging
and casting equipment

Pou nds Pounds Pounds Pounds
4,182
2, 348
1,127
(2)

0.4

1 9 2 3 ...

50- 75

.7

0. 274

0.313

0.146

3. 645

3.196

6. 841

250.0

4,294

(2)

2, 493

883

1918____
1917____

75-100
50- 75

.9
.7

. 284
0)

.365

3. 523

(0

2.740
0)

6. 264
8. 702

300.0
248.0

4, 256
4, 357

(2)
(2)

2 , 212

(0

.160
. 115

1,026.
1,093

1914____
1913____
1912.........................
1911____

50- 75
25- 50
75-100
50- 75

.7
.5

. 275
.283
. 293
.249

.401
.425
.431
.362

. 163
.168
. 174
.148

3. 636
3. 529
3. 416
4. 012

2. 496
2. 352
2. 320
2 . 761

6.132
5. 952
5. 736
6. 773

244.0
252.0
266.0
258.0

4,415
4, 346
4, 325
4, 310

(2)
(2)
(2)
(2)

2,331
2,482
2,374
2,280

1 , 210
1, 098
1, ©39
1,026

Hand filled; sand cast.

3, 335
3, 227

1,855
1, 684

Idle since 1&23.
Relined.

3,018
3,182
3,103
3, 219

1 , 012
1, 460
1, 568

1.0
.7

0)

PLANT
50- 75
25- 50

1923
1922
1920
1919
1918
1917

_

.........

50Under
5050-




75
25
75
75

0.7

.6
.8
.2
.7

1.0

NO.

2,306

Relined.
Do.

49

0.291
. 288

0. 320
.311

0.152
. 150

3. 439
3. 470

3.127
3. 211

6. 566
6. 681

207.6

2 10 .1

4,722
4, 621

.301
. 280
. 251
.261

.290
.298
. 266
.283

. 148
. 144
. 129
.137

3. 320
3. 570
3.989
3. 774

3. 445
3. 358
3. 765
3. 540

6. 765
6.928
7. 753
7.314

229.5
213.5
186.4
186.0

4, 883
4,308
4, 305
4,372

2
18

1,0 12
Relined; mechanically filled; sand
cast.

FURNACES

25- 50

BLAST

1926......................

PRODUCTIVITY— MERCHANT

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

PLANT NO. 50
1926.........................
1925.........................
1924.........................
1923.........................

75-100
75-100
25- 50
50- 75

0.9
.9
.5
.7

1918.........................
1917..........................

25- 50
50- 75

.9

1.0

0.735
.767
.599
.319

0.800
.859
.709
.703

0)
0)

0)
0)

0.383
.405
.325
.219
. 127
.140

1. 360
1.303
1. 669
3.136

0)
(0

1.250
1.164
1.410
1.423

2.610
2.468
3. 080
4.559

262.1
259.4
215.2
212.5

3,996
(2)
(2)
4,041

170
(2)

0)
0)

7.896
7.133

145.5
151.3

4,084
3,916

52
72

NO.

38

2,149
(2)
(2)

2 ,10 1

820
(2)
(2)
1,151

2,507
2,383

1, 230
1,198

100
100
100
13

Mechanically filled; sand cast.

51

25- 50

0.9

0.587

504

0. 271,

1. 705

1.984

3.689 ■ 262.8

3, 624

2,028

965

100

1925..........................
1924..........................
1923..........................

25- 50
25- 50
50- 75

.5
.4
.7

.564
.437
.366

344
294
171

.214
.176
.117

1. 772
2. 289
2. 732

2.900
3.398
5.843

4. 672
5. 687
8. 575

248.3
248.1
209.0

3,804
4,081
4,059

2,076
2 , 228
2,295

1,062
1,053
1 , 281

100

.352
.333

129

(2)
.093
.123

.10 2
.111

2.837
3.004
0)
0)
0)

(J)
7.754
0)
0)

(2)
10. 758
8,132
9. 798
9.031

195.9
189.1
223.7
192.6
192.7

2,148
2, 659
2, 715
3,100
4,193

1,980
1,680
1, 559
1,046

2,593
2,586
2,408
2,494
2,475

1, 532
1,478
1,396
1,420
1,398

.117

2, 546

5.983

.10 2

8. 528

(0
(0
0)

223.9
201.4
208.3
215.7

4,169
3,998
3,349
4,229

92
103
692
(2)

2,426
2,433
2, 342
2,357

1,434
1,519
1,443
1,373

.7
.7
1 . 0-

0)
0)
0)

1914.......................
1913..........................
1912..........................
1911..........................

1=0
.8
1.0
1.0

(0
0)
0)

75-100
50- 75
75-100
75-100

.393

» Detail not available.

167

.131
.136

(0
0

0)
i1)

9. 817
7. 650
7.335

1 N ot reported.

Relined.

Do.

Mechanically filled; sand cast.

* First 6 months only.

TABLES




.3

1.0

Pig machine.

I.— GENERAL

1927*........................

1921.......................... Under 25
1920........................
50- 57
1919..........................
50- 75
1918.........................
50- 75
1917..........................
50- 75

Pig machine; rebuilt in 1919.

APPENDIX

PLANT

00

CD

00

T a b le

A.— Labor

'productivity, production, output per stack-day, consumption of materials charged, and changes in equipment, in merchant
blast furnaces , by plants and by years , 1911 to 1927 — Continued

PLANT

NO.

1920
1919
1918
1917
1916

25- 50
50- 75
75-100
25- 50
50- 75

.5

1915
1914
1913
1912
1911.

5050505050-

75
75
75
75
75

.1
.7

.2

1.0
1.0
.4
1.0

1.0

Total
labor

Furnace
All
crew | other
labor
labor

0
0)
0)
0)
0)
0)
0)
0
0)

0)
0)
0)
0)
0)

6. 730
8. 086

. 101
.099
. 113
. 109
.095

0)
0)
0)
0)
0)

9. 891

0)
0)
0)
0)
0)

.088
.089
.087
.085
.090

0)
0)
0)
0)
0)

7.968

6. 216
7. 999

10.100
8. 872
9.191
10. 494
11. 355
11.193
11. 494
11. 722

1 1 .1 2 2

PLANT
1924
1923.
1922.

50- 75
50- 75
25- 50




0.8
.7
.5

0. 389
.354
.353

0. 486
.441
.440

0. 216
.196

.200

2.570
2.826
2.832

2.061
2 . 266
2. 271

Scrap

Coke

Flux

Changes in stack, and charging
and casting equipment

Total
labor

0.149
. 124
.126
. 158
. 125

0)

Iron
ore

Per
cent of
produc­
tion ma­
chine
cast

Gross
tons
242.1
197.9
192.0
224.8
172.5
218.4
196.0
221.9
205.8
182.4

(2)
(2)
(2)
(2)
(2)

3, 209
3,145
2, 890
2, 792
2, 717

190.2
174.9
172.2
168.0
168.1

(2)
(2)
(2)
(2)
(2)

2 , 680
2 , 861
3,012
3,028
3,094

NO.

4. 630
5.092
5.103

P ounds Pounds Pounds Pounds
2, 326
(2)
2, 670
(2)
3,482
(2)
2,853
(2)
3, 711
(2)

204. 2
212 . 1
235. 2

Relined.
Skip hoist installed in 1921.

Rebuilt.

Hand filled; sand cast.

53
4,140
4,025
4,131

(2)
(2)
(2)

2,000
2,391
2,414

2,372
1,378
1, 555

Relined; idle since 1924.

FURNACES

0.9
.9

All
other
labor

Aver­
age
output
per
stackday

BLAST

75-100
50- 75
Under 25
50- 75
Under 25

Furnace
crew
labor

Man-hours per gross ton
of pig iron produced

PRODUCTIVITY— MERCHANT

1926
1925
1924
1923
1922

Gross tons of pig iron
produced per man-hour

LABOR

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

52
Consumption of materials per
gross ton of pig iron produced

Average labor productivity

CO

1921.......................... Under 25
1920..........................
75-100
25- 50
1919..........................
1918..........................
50- 75
50- 75
1917..........................
1912........................

50- 75

.3
(2)
(2)

.286
.213
.223
.238
.234

.357
.266
.278
.297
.291

.159
.118
.124
.132
.130

3.491
4. 697
4.486
4.197
4. 273

2.799
3. 766
3.597
3. 365
3.420

6.290
8.464
8.082
7. 562
7.693

203.5
212.7
207.9
(2)
(2)

(2)
(2)
(2)
(2)
(2)

(2)

.177

.245

.103

5.655

4. 075

9. 730

(2)

(2)

1.0
.5

(’)
(2)
(2)
(2)
(2)

«
(2)
(2)
(2)
(2)

(2)
(2)
(2)
(2)
(2)

Mechanically filled.

(2)

(2)

Hand filled; sand cast.

PLANT NO. 54

1914_ ....................
1913- ___________
1912______________
1911______________

1.0
1.0
.8

25252525-

50
50
50
50

.5
.3
.9
.9

.8

.7

0. 472
.399
.425
.392
.304
.354
. 174
. 186
. 164

0. 271
.230
.244
.225
.255
.296
.253
.270
. 237

0.172
.146
.155
.143
. 139
. 161
. 103
. no
.097

2 .12 1

. 148
. 139
. 127
.115

.215

.088
.083
.075
.068

6. 756

.202
. 185
.167

2. 503
2. 354
2.551
3,285
2.828
5. 747
5. 365

6 .122
7.169
7.850

8. 673

3.687
4,353
4,093
4,435
3, 922
3. 377
3. 960
3. 697
4. 218
4.655
4. 940
5. 409
5. 976

5.808
6.856

100
100
100
100

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

2,486
2,522
2,610
2,862
2,836
2,900
2,818
2, 742
3,020

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

11. 410
12.109
13. 259
14.648

134.7
129.2
140. 2
138.1

(2)
(2)
(2)
(2)

(2)
(2)
(2)
(*)

3,186
3, 264
3, 052
2,648

(2)
(2)
(2)
(2)

1.357
1,118
1,142
1,413

165.3
162.6

3,700
3, 561
3,477
3,288
3, 358
3, 409
3, 620
3,593

2,920
2,400
2,408
2,430
2,168
2, 242
2, 786

100
100
100
100
100
100
100
100

7. 207

6. 205

Relined; pig machine.
Mechanically filled.
Rebuilt in 1915.

Hand filled; sand cast.

PLANT NO. 55

.9
.9

0. 326
.385
.328
.307
.372
.377
.302
.309

0.173
.162
.146
.135
.163
.161
.141
.145

2.709
3. 583
3.818
4.163
3. 460
3. 556
3. 757
3. 668

3.066
2. 598
3. 048
3. 258
2. 689
2.652
3.313
3.235

5. 775
6.181
6. 866
7. 421
6.149
6.208
7.069
6.903

2,666

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

50- 75

.9

.225

.255

.120

4. 443

3. 918

8. 360

157.0

3,615

1,286

2,588

(2)

100

25- 50
50- 75

.8
1.0

.239
.232

.271
.263

.127
.123

4.186
4. 319

3. 691
3.809

7. 877
8.128

160.0
147.3

4,075
3,956

1,940
1,696

3,102
2,620

(2)
(2)

100
100

50- 75
25- 50
25- 50
50- 75
50- 75
75-100
50- 75
50- 75

0.9
.4
.7

1917........................
1913.........................
1912.........................




176.4
212.3
191.2
183.9
204.9

0. 369
.279
.262
.240
.289
.281
.266
.273

1926.........................
1925........................
1924. ....................
1923_.......................
1922_.......................
1921________ _____
1920........................
1919........................

1.0
.9

1.0

1 Detail not available.

212.6

1,12 2
1,142
1 , 272
1 , 272

3 N ot reported.

Relined.

TABLES

9. 707
9. 062
10.340

217.7
176.5
196.1
159.0
167.6
178.0
167.0
178.9
165.7

6. 447
6. 986

1.— GENERAL

1.0
1.0
1.0
.6

APPENDIX

1926-.......................
75-100
50- 75
1925-.......................
1924__....................
50- 75
1923..........................
25- 50
1922, ______ ______
25- 50
1921.......................... Under 25
1920-.....................
50- 75
1919....................... ..
50- 75
1918-.......................
50- 75

Relined in 1918.

Hand filled; pig machine.

CO

Cm

T a b l e A . — Labor 'productivity, production , output per stack-day, consumption of materials charged, and changes in equipment , in merchant

blast furnaces, by plants and by years , 1911 to 1927— Continued
PLANT NO. 56

1927 3.......................
1926.........................

0.8

50- 75
25- 50

.3

Gross tons of pig iron
produced per man-hour

Furnace
crew
labor

1. 437
1.194

Man-hours per gross ton
of pig iron produced

All
other
labor

Total
labor

Furnace
crew
labor

All
other
labor

Total
labor

0.587
.544

0.417
.374

0. 696
.837

1.705
1.838

2.400
2. 676

Aver­
age
output
per
stackday

Gross
tons
495.4
411.0

PLANT NO.

Iron
ore

Scrap

Coke

Flux

P ounds Pounds Pounds Pounds
264
1,709
381
3,557
542
4, 278
121
1,922

0.550

0. 389

0.229

1.818

2.574

4.392

209.5

4,164

1,315

2,497

(2)

1. 0

. 261
.277
. 272
.247

. 153
. 162
. 159
.144
.130
.155

2.704
2.548
2.604

3. 827
3. 607
3. 686
4. 057
4. 510
3. 790

6.531
6.156
6. 290
6. 923
7.696
6.467

199.7
195. 0
190.8
184.9
194.9
(2)

4,178
4, 348

1,236
1,315
(2)
(2)
(2)
(2)

2,499
2,537
(2)
(2)
(3)

(2)
(2)
(2)
(2)

0

.370
.392
.384
.350
.314
.374

1914_....................... Under 25

0

.307

.217

.127

3. 255

4. 607

7.863

(2)

(2)

0

.300

.2 1 1

.123

3.381

4.780

8.160

0

0

1912..........................




50- 75

.4

.222
.264

2.866

3.186
2. 677

0
(2)
(2)
(2)

0

0
0

0

(3)

0

0

0

0

Helmed and skip hoist installed
in 1924.

Rebuilt.

Hand filled; sand cast.

FURNACES

0.9

1.0

Mechanically filled; pig machine.

BLAST

50- 75

.3
.1

100
100

Changes in stack, and charging
and casting equipment

57

50- 75
1923
1922 ....................... Under 25
1921 ................... Under 25
50- 75
1920-.......................
25- 50
1919-.......................
1918-.......................
50- 75

1926 .......................

Per
cent of
produc­
tion ma­
chine
cast

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

PLANT NO. 58
1926.
1925.
1924.

50- 75
25- 50
Under 25

0.7
.5

.1

0.518
.467
.462

0.347
.348
.333

0.208
.199
.194

1. 931
2.143
2.162

2 . 881
2. 872
3.000

4. 813
5.015
5.162.

261.0
235.2
238.6

5,092
5,363
5,107

38
188

3, 050
3,351
2,949

524
569
829

100
100
100

100
100
100

Mechanically filled; pig machine.

PLANT NO. 59
50- 75
50- 75
25- 50

1920.
1919.
1918.
1917.

25252525-

50
50
50
50

0.9

1.0
.6
.8
.7

1.0
.9

0.156
.161
.107

2.654
2.570
4.133

3. 745
3.629
5.174

6.399
6.198
9. 307

180.9
182.1
136.6

3, 412
4, 296
4,449

1,216
551
777

2,704
2, 742
3,154

1,248
1,340
1,548

.191
. 160
.181
.151

.153
.135
.153
.124

.085
.073
.083
.068

5.232
6. 240
5. 530
6.634

6.527
7.433
6. 556
8. 055

11. 759
13. 673
12 . 086
14. 689

137.0
117.3
132.4
108.6

4, 352
4,269
4,404
4, 464

956
1,187
981
903

3, 597
3, 590
3,547
3,808

1, 624
2,025
1, 727
1 , 868

3,132

(2)
0)
0)
0)
(2)
(2)

3,155
2, 949
2 , 766
3,078
2,654
2, 928

0)
0)
0)
0)
0)
0)

0)
0)
0)

0)
0)
0)

Idle since 1924.
Pig machine; rebuilt in 1921.

Mechanically filled; sand cast.

PLANT NO. 60
1924
1923

Under 25
25- 50

1921
1920
1919

Under 25
25- 50
Under 25

1917

50- 75

0.5
.7

0. 223
.239

0.184
. 197

.4

, 235
.244
.237

. 194

1.0
.2
1.0

0.101
.108
.106

.201

. 110

. 196

.107

.224

.123

4. 488
4.191

5.424
5.066

9.912
9. 257

4. 263
4. 102
4.220

5.152
4.958
5.100

9.415
9.060
9.321

4.463

8.156

122.1
130.7

4,957
4, 906

2,849
3, 013

134.4
135.9
129.8

4, 540
4, 574
4, 238

3,168
3,136
3,127

Idle since 1924.
Relined.

Hand filled; sand cast.

PLANT NO. 61
25- 50
1920_.......................
25- 50
1919-.......................
1918........................
25- 50
1917.........................
50- 75
1916........................
25- 50
1915-....................... Under 25
1913-.......................
1912..........................
1911..........................

25- 50
50- 75
50- 75




0.6
.6
.7

1.0
.8
.3
.7

1.0
1.0

0)
0)
0)
0)
0)
0)

0)
(0
0)
0)
0)
0)

0.134
. 155
.131
.146
.171
.129

0)
0)
0)
0)
0)
0)

0)
0)
0)
0)
0)
0)

7. 477
6. 446
7. 636
6. 856
5. 843
7. 764

134. 8
162.0
141.4
155.1
173.5
184.6

2,827
3, 221
3,129
3,096
2,858
2,547

0)
0)
0)

0)
0)
0)

.151
.151
.164

0)
0)
0)

0)
0)
0)

6. 609

163.4
158.1
169.0

0)
0)
0)

1 Detail not available.

6.602
6.105

2 Not reported.

903
580
676
708
851
1,315

0)
0)
0)

TABLES

0. 267
.276
.193

1.— GENERAL

0.377
.389
.242

APPENDIX

1924.
1923.
1922.

Relined; idle since 1920.

Hand filled; sand cast.

3 First 6 months only.

co

-<r

T a b l e A . — Labor productivity, production , output per stack-day , consumption of materials charged , and changes in equipment , in merchant

blast furnaces, by plants and by years,

to 1927— Continued

CD

00

PLANT NO. 62

1913.
1912.
1911_

Aver­
age
Man-hours per gross ton
output
of pig iron produced
per
stackday
I Tntni Furnace
All
Total
other |
crew
other
labor
labor
laDor ; labor
labor

Gross tons of pig iron
produced per man-hour

Furnace
crew
labor

50- 75

(’)

0)

0)

50- 75

(2)
(2)
(2)
(2)

0)
0)
0)
0)

0)
0)
0)
0)

25- 50
25- 50
Under 25

0. 079

0)

.069

0)
0)
0)
0)

.082 !
.052
.051 i

Gross
tons

0)

12. 690

(2)

0)
0)
0)
0)

14. 535
12.141
19. 051
19. 528

(»)
(2)
(2)
(2)

Iron
ore

Scrap

Coke

Flux

Per
cent of
produc­
tion ma­
chine
cast

Changes in stack, and charging
and casting equipment

Pounds Pounds Pounds Pounds

(2)

(2)

(2)

(2)

(l)
(2)
(2)
(2)

(2)
(2)
(2)
(2)

(2)
(2)
(2)
(2)

(2)
(2)
(2)
(2)

3,164
3, 554

(2)
(2)

Rebuilt in 1920; idle since.
Hand filled; sand cast.

Skip hoist and pig machine in­
stalled in 1920. Furnace aban­
doned in f927.

Hand filled; sand cast.

BLAST

PLANT NO. 63
0.3

1.0

0.166
.255

0.171
.264

0.084
. 130

6. 035
3. 921

5. 837
3. 792

11.873
7.713

125.1
155.0

4, 525
4,903

PLANT NO. 64
1920.
1919.

25- 50
Under 25

1917.

25- 50




0.8
.3

0. 270
.242

0.155
.138

.241

.138

0. 098

3. 699
4.136

6.461
7.225

10.160
11.361

140.8
145.2

4,608
3, 649

3,266
3,348

(2)
(2)

Idle since 1920.

7.251

11.403

149.1

4,375

3,374

(2)

Relined; hand filled; sand cast.

FURNACES

1919........................ Under 25
1917..........................
50- 75

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active ^
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

PLANT NO. 65
1923.........................
25- 50
1922......................... Under 25

0.6
.2

0.140
.149

0. 220
.236

0.085
.091

7.169
6.699

4.544
4.246

11.713
10.945

136.2
145.7

4,467
4, 684

2,899
3,069

(2)
(2)

1920.........................
1919.........................

25- 50
50- 75

.9

1.0

.141
.145

.223
.228

.086
.089

7.084
6.913

4. 491
4. 382

11. 575
11.294

139.9
147.1

4, 592
4,480

3, 329
3,297

(2)
(2)

Relined in 1918.

1917.........................

25- 50

.8

.146

.231

.090

6.831

4. 330

11.161

143.0

4, 323

3,145

(2)

Hand filled; sand cast.

Idle since 1923.

50252525Under
25Under
Under
Under
252525Under
25-

1 .0
1.0
1.0

75
50
50
50
25
50
25
25
25
50
50
50
25
50

.7

.2
.6
.6

0. 503
.460
.408
.350
.412
.312
.244

.5

.2 1 2

.8

.194
.286
.263
.270
. 120
. 141

.9
.9
.9
.5
.9

0. 386
.362
.336
.287
.418
.310
.227
.180
.157
.252
.296
.326
. 227
.265

0. 218
. 203
.184
. 158
.207
.155
.118
.097
.087
. 134
. 139
. 148
.078
.092

1.988
2.172
2.448
2. 858
2.428
3. 210
4.106
4. 723
5.156
3.495
3. 809
3. 706
8. 329
7.110

2 592
3 760
2 980
3 480
2.390
3. 227
4. 402
5.545
6. 365
3.974
3. 378
3, 066
4.414
3. 768

4. 581
4.932
5. 429
6. 338
4. 819
6.436
8. 508
10 . 268
11. 521
7.469
7.187
6.772 1
12.743 1
10.879

1920..........................

25- 50

(s)

0)

0)

0.117

<*)

(*)

25- 50
1923..........................
1922.......................... Under 25
1920........................
1919.........................
1918..........................




25- 50
25- 50
25- 50

0.6
.1

0. 203

.9

.214
.145

1.0
.8

.2 0 1
.1 2 1

148. 7
112.5

100.8
93.1
81.1
96.0

88.2
90.8
72.0
89.0

NO.

8. 542

PLAN T

120.0
120.8

(2)
( 2)
(2)
(2)
( 2)
( 2)
( 2)
( 2)
(2)
( 2)
( 2)
( 2)
( 2)
( 2)

(2)
( 2)
( 2)
( 2)
( 2)
( 2)
( 2)
( 2)
(2)
(2)
(2)
(2)
(2)
(2)

( 2)
( 2)
( 2)
(2)
(2)
(2)
(2)
( 2)
(2)
( 2)
(2)
(2)
( 2)
(2)

(2)

(2)

(2)

(2)

Mechanically filled; sand cast;
idle since 1920; abandoned in
1925.

Relined.

Do
Mechanically filled.
Hand filled; sand cast.

67

(2)

NO.

(2)
(2)
(2)
( 2)
(2)
(2)
(2)
( 2)
(2)
(2)
(2)
(2)
(2)
(2)

68

0.276
.273

0.117
.116

4.917
4.982

3.619
3. 667

8. 536
8.649

198.7
131.0

4, 818
4, 854

2,800
2,615

(2)
(2)

Idle since 1923.
Rebuilt.

.291
.197
.165

.124
.083
.070

4.664
6.902
8.236

3.433
5.081
6.063

8.097
11.983
14. 299

140.2
85.0
90.0

4,415
3,844
4,399

2,564
(2)
3,801

(2)
(2)
(2)

Hand filled; sand cast.

1 Detail not available.

* N ot reported.

Relined.

TABLES

PLANT

142.7
133.6

1.— GENERAL

1926..........................
1925....................... ..
1924............... ..........
1923.........................
1922.........................
1921....................... ..
1920....................... ..
1919................. .
1 9 1 8 .......................
1917....... ..................
1 9 1 6 ......................
1915______________
1914.........................
1913.........................

APPENDIX

PLANT NO. 66

T a b l e A . — Labor productivity, production, output per stack-day, consumption of materials charged, and changes in equipment, in merchant

blast furnaces, by plants and by years, 1911 to 1927— Continued

O

o

PLANT NO. 69

Average
Produc­
full-time
tion of
furnaces
thousands
acti ve
of gross
during
tons
year

Gross tons of pig iron
produced per man-hour

Furnace
crew
labor

Man-hours per gross ton
of pig iron produced

All
other
labor

Total
labor

Furnace
crew
labor

All
other
labor

Total
labor

Aver­
age
output
per
stackday

Iron
ore

Scrap

Coke

Flux

Per
cent of
produc­
tion ma­
chine
cast

Changes in stack, and charging
and casting equipment

0.9.

0.117

0.139

0.063

8.544

7. 218

15.762

Gross
tons
115. 2

1919 .....................

25- 50

.9

. Ill

. 131

.060

9.015

7. 615

16.630

109.1

5,006

3, 686

(2)

1917..........................

25- 50

1.0

.109

.129

.059

9. 200

7. 772

16.972

109.1

5, 701

3, 858

(2)

Hand filled; sand cast.

(2)
(2)
(2)
(2)

(2)
(2)
(2)
(2)

Idle since 1921; relined in 1923.

Pounds Pounds Pounds Pou nds
4, 879
3, 531
(2)

Relined in 1918 and 1921; idle
since 1920.

PLANT NO. 70
1921
1920
1919
1918

.............

2525Under
25-

50
50
25
50

0.6
1.0
.7
.9

0)
0)
0)
0)

0)
0)
0)
0)

0.108
. 091
.083
.083

0)
0)
0)
0)

0)
0)
0)
0)

9.301
10.961
11.980
12.090

122.8
110.8
96.0
90.1

(2)
(2)
(2)
(2)

Hand filled; sand cast.

PLANT NO. 71
1923........................ Under 25
1922........................ Under 25

0.5
.3

0)
0)

( 1)
0)

0. 069
.077

0)
0)

0)
0)

14. 405
12. 913

77.7
86.9

5,3 31
4, 726

3, 023
2, 659

2, 460
2,126

1920......................... Under 25
1919___................... Under 25
1918........................
25- 50
1917..........................
25- 50

.8
1.0
.8

0)
0)
0)
0)

0)
0)
(l)
0)

.072
.079
.085
.082

0)
0)
( 1)
0)

0)
0)
0
0)

13. 920
12. 637
11. 700
12 . 208

80.0
85.5
93.7
91.6

4,
4,
4,
4,

3, 047
2, 935
2, 672
2, 736

2, 023
1, 720
1, 586




.4

621
442
437
596

1,886

Idle since 1923.

H and filled; sand cast.

FURNACES

25- 50

BLAST

1920 .......................

PRODUCTIVITY— MERCHANT

Year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

PLANT NO. 72
1926_.......................

25- 50

0.6

0. 446 | 0.468

0. 229

2. 240

2.135

4.376

174.3

PLANT NO.
Under 25
Under 25
Under 25

1923..

25- 50
25Under
2525-

50
25
50
50

1914.
1913.
1912..
1911..

25252525-

50
50
50
50

.2
.2

1.0
.5
1.0
.9

0.103
. 183

0)
.221
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

0. 333
.312

0.122
.115
.112

5.170
5. 456

3. 210

.375

.139

4. 535

0)

(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)

.070
.070
.094
.082

.102
.107

0)

0
0)
0)
0)
0)
0
0)
0

8.169

124.0
119.7
116.6

2. 663

7.199

104.1

0
0
0)
0
0
0
0
0)

12. 785
11. 947
14.194

102.2
88.6

0

14. 220
10. 604
12.157
9. 812
9. 385

80.4
87.9

89.5
81.9
95.0
98.0

2, 029

791

100

j Mechanically

filled; pig machine.

73

(2)
(2)
(2)
(2)
(2)
(2)
(2)
0
0
0
0
0

Relined.

H and filled; sand cast.

PLANT NO. 74
1922.
1921.
1920.

Under 25
Under 25
25- 50

0 .1
.2
1.0

0
0
0)

0
0
0

0.138
. 139
.081

0)
0)
0

0
0
0

7. 222
7.173

12 . 276

106.6
116.8
75.9

0
0
0

0
0
0

0
0
0

0
0
0

Idle since 1922.
Mechanically filled.
Hand filled; sand cast.

0
0
0

0
0
0

0
0
0

Idle since 1922.

PLANT NO. 75
1922
1921
1920

Under 25
Under 25
Under 25




0.3

.1
1.2

0
0
0

i Detail not available.

0)
0
0

0.105
.082

0
0
0

0)
0
0

9. 509
12.169
12. 385

70.0
54.2
52.9

0
0
0

Hand filled, sand cast.

• First 6 months only.

1.----------------------------------------------------------------------------------------------------------

1920..
1919..
1918..
1917..

0.9

347

APPENDIX

1927 3
1926..
1925..

3,488

O

T a b l e A . — Labor productivity, production, output per stack-day, consumption of materials charged, and changes in equipment , in merchant

^

blast furnaces, by plants and by years , 1911 to 1927— Continued

^

PLANT NO. 76
Consumption of materials per
gross ton of pig iron produced

1924.........................
1923.........................

Under 25
25- 50

0.4

.6

Gross tons of pig iron
produced per man-hour

Furnace
crew
labor

0)

All
other
labor

0)
0)

Total
labor

0. 121
.106

Man-hours per gross ton
of pig iron produced

Furnace
crew
labor

All
other
labor

0)
0)

0)
0)

25
25
25
25

0.4
.9
.5

.8

0.133
. 132
. 122
. 124

0. 251
. 248
. 229
. 233

0. 087
.086
.079
.081

7. 494
7. 591

8. 220
8.080

3.982
4. 034
4. 368
4. 294

8. 233
9. 471

11.
11.
12.
12.

Under 25




0.4

0)

0)

0.086

0)

0)

Coke

Flux

Gross
toils
Pounds Pounds Pounds
131. 2 j
(2)
(2)
(2)
114. 0 | (2)
(2)
(2)
I

NO.

476
625
588
374

71.9
75. 7
80.4
79.1

NO.

11. 574

119. 2

Pounds
(2)
(2)

Idle since 1924.
Hand filled; sand cast.

77
4,945 ________
4,545 !________
4,471 1 ..........
4,798 ________

3,159
2, 749
2, 832
2, 879

(2)
(2)
(2)
(2)

Idle since 1921.

(2)

Hand filled; sand cast; idle since
1923.

Hand filled; sand cast.

78
(2)

(?)

FURNACES

PLANT
1923.........................

Scrap

Changes in stack, and charging
and casting equipment

BLAST

Under
Under
Under
Under

Iron
ore

Per
cent of
produc­
tion ma­
chine
cast

Total
labor

PLANT
1921.........................
1920..................... 1919.........................
1818........... ..............

; Aver­
age
output
per
stacki day

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion of
furnaces
thousands
active
of gross
during
tons
year

LABOR

1
Average labor productivity

PLANT NO. 79
1920.......................... Under 25

0.4

0

0)

0.079

(0

0)

12. 734

76.0

0

0

0

0

0

Hand filled; sand cast; idle
1920.

sin
ce

PLANT NO. 80
1920....................... . Under 25

0

0)

0. 214

i Detail not available.

0)

0

4.667

0

0

0

J N ot reported.

100

Pig machine; method of charging
not reported; idle since 1920;
abandoned in 1925.

APPENDIX
1.— GENERAL
TABLES




0

LABOR PRODUCTIVITY, PRODUCTION, CASTING, IN MERCHANT
BLAST FURNACES, BY YEARS AND BY PLANTS, 1911 TO 1927

In Table B all plants covered in this study are classified by years;
in each year are included all plants having productivity data available
for that year; the plants are listed in the order of their productivity
record, from the highest to the lowest. The data included in this
table are the same as those in Table A except that data covering con­
sumption of material are omitted from Table B. For explanation of
items see explanation of Table A, page 69.
B .— Labor productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927

T a b le

1927 (FIRST SIX MONTHS)
Average labor productivity

Plant
N o.

Produc­
tion in
thou­
sands of
tons

3_
4_
17
9_
26.
56.
33.

6_
20

19.
37
7..
5_
51.
18.
38.
31.
15.
30.
40.
73.

225-250
100-125
75-100
75-100
50- 75
50- 75
25- 50
125-150
50- 75
50- 75
50- 75
125-150
125-150
25- 50
75-100
50- 75
25- 50
50- 75
125-150
50- 75
Under 25

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

Fur­
nace
crew
labor

All
other
labor

0. 943

0. 644

.640

.989
.696
1.091
.822
.776
1.415
.844
1. 179
.824
1.705
1.964
1.906
1.982
3. 226

1.416
1. 265
1.408
1.705
1.319
1.640
1. 770
1.402
2. 217
1.940
2. 736
1.984
2. 566
2.947
3. 023
3. 271

2.857
5.170

2.0 1.060
1.0 0)
1.0 1. 562
1.1 .988
1.0 1.011

All
other
labor

1. 552
.

C
71)06 I

1.0
1.0
1.0

1. 437
.917
1.216
1.289
.707
1.185
.848
1.213
.587
.509
.525
.504
.310

. 790
.710
. 587
.758
.610
. 565
.713
.451
.515
.366
.504
.300
.339
.331
.306

.9

.350
. 193

.255
.333

2.0
1.0
1.0
.8
2.0
1.6
.9
1.9

2.0
1.0

Method of—

0)

0)

Total
labor

0. 630
.572
.486
.439
.417
.417
.415
.406
.393
. 355
.327
.321
. 2S1
.271

.221
.206
.200
. 154
. 152
. 147
. 122

0)
1.012

0)

Total
labor

Aver­
age
out­
put
per
stackday
(gross
tons)

Charging

Casting

Machine.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Sand.
Do.
Machine.
Sand.
Machine.
Sand.
Do.

3.929
2. 999

1. 587
1.749
2. 056
2. 277
2. 397
2. 400
2.410
2. 463
2. 546
2.817
3. 061
3. 119
3. 560
3. 689
4. 530
4. 851
5. 005
6.497
6. 597
6.786
8.169

657.9
564.0
492.2
404.7
383.0
495.4
359. 0
408.5
412.0
414.8
459.7
410.0
498.9
262.8
252.4
289.6
206.4
316.2
380.5
222.7
124.0

Mechanical ___ do______
___ do______
____ do__........
____ do______
..d o ______
_.do______
____ do______
____ do.......... .
____ do______
____ do______
____ do______
.........do______
____ d o ...........
____ do.......... .
____ d o ...........
____ do______
H and______
Mechanical.
____ do______
H and______

0.714

1.746

648.7
368.3
396.7
376.8
617.0
474.6
520.5
486.2
527.3
334.9
380.9
366.1
262.1
392.3
411.0

Mechanical. Machine.
____ do_______
Do.
____ do.............
Do.
____ do_______
Do.
____ d o ............
Do.
____ d o ...........
Do.
____ do............
Do.
.........do_______
Do.
____ do.............
Do.
_____do............
Do.
____ d o ............
Do.
____ do.............
Do.
____ do_______
Do.
____ do_______
Do.
.........do.............
Da

0)

0)

1926
3______
25

12
23
1 ______
17
13

21
4______
36
9............
26
50
16
56

450-475
125-150
225-250
125-150
450-475
150-175
225-250
100-125
275-300
100-125
175-200
125-150
75-100
75-100
25- 50

2.0
1.0
1.7

1.0
2.0
1.0
1 .2
.7
1.5
.9
1.3

1.0
.9
.7
.3

1 Detail not available.

104




0.969
0)
0)
1.353
.838
1.507

(0
1 . 202
1. 731
.929
.910
.971
.735
.854
1.194

1.400
0)
0)
.861
1 . 222
.673
0)
.736
.599
.789
.785
.659
.800
.685
.544

0. 573
.536
.529
.526
.497
.465
.465
.456
.445
.427
.421
.393
.383
.380
.374

1.032
0)
0)
.739
1.193
.664
0)
.833
.578
1.077
1.099
1.030
1.360
1.171
.837

1.866
0)

1. 890
1.900

1.161
.818 2.0 12
1.486 2.149
2.149
0)
1.359 2.193
1.669 2.246
1 . 268 2. 345
1. 274 2. 375
1. 517 2. 547
1.250 2.610
1.461 2. 632
1.838 1 2.676

105

APPENDIX 1.— GENERAL TABLES

B . — Labor 'productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927 — Continued

T a b le

1 9 2 6 — Continued
Average labor productivity

Plant
N o.

8............
2 ............

Produc­
tion in
thou­
sands of
gross
tons

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

Gross tons of pig
iron produced per
man-hour

Fur­
nace
crew
labor

All
other
labor

Total
labor

1.223
.524

0.365
.360

1.921

.868

0.818
1.909

.668

.348
.341
.336
.326
.317
.294
.290
.283
.279
.259
.258
.239
.229
.229
.218
.214

1.375
1. 359
1.460
1. 585
.816

1. 498
1. 573
1. 518
1.488
2.342

100-125
275-300

0.7
2.3

0. 520
1.152

150-175
100-125
100-125
125-150
20
75-100
22
125-150
5 . .........
350-375
6 ...........
225-250
7_____ _
250-275
45
75-100
27
125-150
42
100-125
72
25- 50
57
50- 75
50- 75
66
38
100-125
39
25- 50
58
50- 75
37
100-125
48_____
25- 50
46
25- 50
31
50- 75
55 _
50- 75
18
100-125
54
75-100
1 5 ____
175-200
52
75-100
40
50- 75
14
25- 50
30
250-275
73
Under 25
Under 25
47

1.0
1.0

.727
.736

19
33
34
28

.7

.686

.8
.6

.631
1.226

.9
1.9

1.8
1.9
.9

1.0
1.0
.6
.9

1.0
1.0

.4
.7

.8
.4
.5

1.0
.9
1.4

1.0
2.0
.9

.6
.4

2.0
.2
.1

0

1. 252
1.006
.816
0)
.751
.695
.446
.550
.503
.543
.466
.518
.740
0)
.442
.529
.369
.455
.472
.263
0)
.345
.423

0

.183

0

.636
.659
.672
.427
0)
.377
.393
.424
0)
.393
.363
.468
.389
.386
.352
.391
.347
.282

0

.367
.319
.326
.278
.271
.421
0)
.251
.216
0)
.312
0)

.2 12
.208
.204

.201
.200
.199
. 173
.173
.172
.162
.149
.145
.143
.130
.115
.115

Method of—

Aver­
age
Man-hours per gross
out­
ton of pig iron pro­
put
duced
per
stackday
Fur­
(gross
All
nace
Total tons)
other
crew
labor
labor
labor

0

.799
.994
1.226

0

1.331
1.438
2. 240
1.818
1.988
1.841
2.157
1.931
1. 351

0

2. 264
1.892
2. 709
2.197

2 .12 1

3.803
0)
2.900
2.362

0

5.456

0

0

2.651
2.543
2.358
0)
2.543
2.754
2.135
2. 574
2.592
2. 837
2. 556
2.881
3. 551
0)
2.727
3.131
3.066
3.599
3. 687
2.378

0

3.989
4.635
<l)
3. 210
0)

2.739

2 . 777
2.873
2. 932
2.978
3. 072
3.157
3.401
3.450
3. 536
3. 584
3. 856
3.874
4.192
4.376
4. 392
4. 581
4. 678
4.713
4.813
4. 902
4.985
4. 991
5.023
5. 775
5.796
5.808
6.181
6. 730
6.889
6.997
7.669
8. 666
8.693

Charging

Casting

Mechanical. Machine.
441.1
345.6 ------- do---------- Sand and
machine.
432.5 .........do............
Machine.
Do.
325.0 ____ _do............
Do.
442.7 ____ d o ............
Do.
454.4 H and_______
Do.
378.0 Mechanical _
Do.
386.0 ____ do---------506.2 ____ do............
Do.
Do.
359.1 ____ do............
Do.
392.8 - - . - . d o ............
Do.
298.2 H and_______
Do.
360.5 Mechanical.
Do.
283.4 ____ do_______
Do.
174.3 ____ do_______
209.5 I.........do_______ Sand.
Do.
142. 7 ____ do............
Do.
299.9 _____d o „ .........
278.2 ____ do............ Machine.
Do.
261.0 - . . . - d o ............
Do.
401.0 ____ do........ __
247.0 H and_______ Sand.
270.0 Mechanical. Machine.
Do.
203.7 ____ do______
Do.
176. 4 Hand Mechanical. Sand.
233.1
217.7 _____do______ Machine.
250.5 H an d ............. Sand.
Mechanical.
Do.
242.1
Do.
317.9 _____do______
300.8 H and............. Machine.
354. 6 Mechanical. Sand.
Do.
119.7 H and_______
Do.
124.2 Hand a n d
I mechanical.

1925
3 ______

12
4 ______
25
13
9______
1 - .........
23
36

21
17
50
19
33
8 ______

20
22
28
6 ...........
34
5______
45
7...........

425-450
200-225
275-300
125-150
175-200
150-175
525-550
75-100
75-100
100-125
150-175
75-100
75-100
100-125
50- 75
150-175
125-150
75-100
275-300
25- 50
325-350
100-125
250-275

2.0

0. 890

1.4
1.3
.9

0
1.868
0)

1.0
1.0
2.5

.8
.8
.6
1.0
.9

.6
1.0
.4

1.0
1.0
.6
2 .2
.3

2.0
1.0
2.0

.766
.984
.742

1.12 0
.893
1.119
1.372
.767
.708
.717
.522
1.250
0)
0)
.924
.577
1.026
0)

0

1 Detail not available.

5 4 2 1 °— 29--------8




1.205
0)
.639
0)

1.12 2

.800
1.083
.713
.828

.686
.615
.859
.813
.771
1.227
.477

0
0

.475
.687
.414
0)

0

0.512
.478
.476
.473
.455
.441
.440
.436
.430
.425
.425
.405
.379
.371
.366
.345
.326
.321
.314
.314
.295
.288
.270

1.124

0

.535

0

1.305
1.016
1.347
.893

1.12 0
.893
.729
1,303
1.412
1.394
1.915
.800

0
0

1.082
1.732
.975

0
0

0. 830

0

1.565

0

.891
1.250
.923
1.403
1.208
1.458
1.625
1,164
1.229
1.298
.815
2.099

0
0)
2.104
1.456
2.416
0)
0

1.954 596.7
2.093 ; 391.1
2.100 ! 617.8
2.116 I 374.8
2.197 ! 503.3
2.266 I 431.7
2. 271 578. 7
2. 295 323.6
2. 328 317.9
2.351 505.8
2.354 432.3
2. 468 259.4
2. 642 387.1
2. 692 321.0
2. 731 453.5
2.898 -418.0
3.066 392.0
3.117 441.5
3.187 341.7
3.188 439.9
3.390 457.7
3.471 276.8
3.703 363.1

Mechanical. ^ Maehine.
Do.
_____do______
Do.
- - . . . d o ______
Do.
.........d o______
Do.
.........do______
Do.
____ do______
.........do______
Do.
Do.
.........do............
Do.
.........do______
.........do______
Do.
Do.
_____d o______
Do.
____ d o______
.........do______
Do.
Do.
____ do______
Do.
_____do______
Do.
_____d o______
Do.
____ do______
H and_______
Do.
Mechanical.
Do.
Do.
.........do______
_____d o______
Do.
H and.............
D o.
Mechanical J
Do.

106
T

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

B . — Labor 'productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927— Continued

able

1 9 2 5 — Continued
Average labor productivity

Plant
N o.

38.........
51
39
46

Produc­
tion in
thou­
sands of
gross
tons

58
42
18
31
41
43
15
55
54
27
30
52
47

75-100
25- 50
75-100
25- 50
25- 50
25- 50
50- 75
150-175
50- 75
50- 75
25- 50
175-200
25- 50
50- 75
Under 25
200-225
50- 75
25- 50

73
40

Under 25
50- 75

66

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

0.9
.5

1.0
.3

1.0
.5

.6
2.0
1.0
.5
.3

2.0
.4

1.0
* .0
1.9
.9

Gross tons of pig
iron produced per
man-hour

Fur­
nace
crew
labor

All
other
labor

0.546
.564
.451
.435
.460
.467
.541
.429
.477
.283
.406
.259
.279
.399
.412

0.373
.344
.381
.390
.362
.348
.283
.326
.290
.497
.317
.439
.385
.230
.216
0)
0)

1.0

0
0)

.2
.8

.248

0

Total
labor

0.222

Method of—

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

1.830
1.772
2. 215
2. 300
2.172
2.143
1.848
2.330
2.096
3.536
2.461
3.855
3.583
2.503
2.424

All
other
labor

0

.12 2

0)

0
0

4.513
4. 672
4.841
4.865
4.932
5. 015
5. 388
5. 395
5. 539
5.550
5.614
6.130
6.181
6. 856
7.054
7. 403
8.086
8.191

0)
.181

.105

.1 1 2

0)
4. 025

0)
5. 535

8.893
9. 560

116.6
229.1

1.312
.877

2.147
2.157
2.227
2.246
2. 358
2. 388
2. 403
2.486
2. 570
2 . 600
2 . 612
2 . 662
3.080
3,233
3. 516
3.601
3.804
3.821

320.7
531.9
366.5
329.6
464.1
430.0
524.1
549.2
408.9
504.6
367.2
323.1
215.2
512.0
303.0
444.4
566.3
326.0

3.923
3.982
3. 999
4.364
4. 509
4. 568
4. 605
4.630
4,641
4,815
4.837
4.898
5.162
5.429
5.445
5.687
5.772

293.3
317.2
375.5
381.0
335.2
354.5
241.6
204.2
451.3
144.3
346.0
233.0
238.6

.214
.207
.206
.203
.199
.186
.185
.181
.180
.178
.163
.162
.146
.142
.135
.124

2.682
2.900

Total
labor

Aver­
age
out­
put
per
stackday
(gross
tons)

2 . 626
2.566
2.760
2.872
3.540
3.064
3.443
2.014
3.153
2.275
2.598
4. 353
4.630

0

299.8
248.3
268. 4
291.9
133.6
235.2
247.0

210.8
182.8
329.7

220.8
247. 2
212.3
176.5
185.0
315.8
197.9
133.1

Charging

Casting

Mechanical,
.........do______
.........do______
_____do............
.........d o______
.........do______
.........do............
.........do______
_____d o______
H an d _______
M echanicalHand ______
____ do______
Mechanical..
____ d o______
.........do______
_____do______
H a n d and
mechanical.
Hand
Mechanical _

Sand.
Machine.
D o.
Do.
Sand.
Machine.
Do.
Sand.
Machine.
Sand.
D o.
Do.
Machine.
Do.
D o.
Sand.
Do.
D o.
Do.
Do.

1924
23 .. .
1 _ .........

50- 75
275-300
200-225
75-100
125-150
125-150
275-300
250-275
100-125
150-175
25- 50
25- 50
25- 50
50- 75
75-100
75-100
75-100
350-375

0.6

6 _____

50- 75
225-250
250-275
100-125
22
17
50- 75
14
75-100
50- 75
39
50- 75
53
150-175
5 _.........
Under 25
46. .
75-100
20
18
150-175
Under
25
58
25- 50
66
27
50- 75
51------25- 50
43--------1I
50- 75

.6
2.0

7 _ .........

1.9

12
36
13
9 _ .........
3 _ .........
4 _ .........
25

21
19
32 . .
50 .
16
33
28

8
2 ______
45

1.4
1.5

.8

1.197
.781

0.762
1.140

0

0
0

1.5
1.3

(l)
.720
.930
.714
1.907

.8
.8

0
1 . 011

.3
.4
.5
.3
.7
.5
.4
3.0

.679
.898
.599
1.105
.485

.9

1.0

.8
.4

.6
.8
.8
1.0
.2
.8
2.0
.1
1.0
.5
.4
.7

0

.688
0

.375
.663

1.135
.433

(l)

0

0

0)

0
0

.516
.466
.389
.890
.460
.606
.471
.462
.408
.534
.437
.429

1 Detail not available.




1.032
.762
.997
.510
0)
.620
.877
.646
.709
.429

0
0
0

.380
.407
.486
.284
.379
.314
.361
.333
.336
.280
.294
.291

0.466
.464
.449
.445
.424
.419
.416
.402
.389
.384
.383
.376
.325
.309
.284
.278
.263
.262

0.835
1 . 280

.255
.251
.250
.229

0
0

.2 2 2
.219
.217
.216
.215
.208
.207
.204
.194
.184
.184
.176
.173

0
0

1. 390
1.075
1. 400
.524

0)

.988
1. 472
1.114
1. 669
.905
2.063

0

2.669
1. 509

0

.969
1.312
1.003
1. 962

0

1.612
1.140
1. 547
1. 410
2.329
1.453

0)

.881
2.312

il)

0

1.938
2.147
2. 570
1.124
2.174
1.651
2.124
2.162
2.448
1.871
2.289
2.330

2.630
2.459
2.061
3. 517
2.641
3.187
2.774
3.000
2.980
3. 574
3. 398
3. 441

0
0

0)

120.0
332.7
248.1
236.1

Mechanical. Machine.
.........do._......... v Do.
_____do_..........
Do.
____ do_..........
D o.
.........do_______
Do.
.........do_______
D o.
.........do_______
Do.
.........do_______
Do.
.........o d „ .........
D o.
.........do ............
Do.
.........do_______
Do.
.........do............
Do.
.........do_______
D o.
.........do_______
Do.
_____do_______ Sand.
H a n d ...........
Do.
Mechanical. Machine.
.........do_______ Sand and
machine.
H an d _______ Machine.
Mechanical.
Do.
.........do............
Do.
_____do_______
Do.
.........do______
Do.
H an d _______
Do.
Mechanical _
Do.
.........do_______ Sand.
.........do______ Machine.
.........do............
Do.
.........do............
Do.
.........do............ Sand.
_____do............ Machine.
.........do_______ Sand.
.........do_______ Machine.
.........do______ Sand.
_____do............
Do.

a Plant operated less than 18 days during the year.

107

APPENDIX 1.----GENERAL TABLES
T

B . — Labor 'productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927 — Continued

able

1 9 2 4 — Continued
Method of—

Average labor productivity

Plant
N o.

41
38_____
31
59
54
55
30

11
15
40
52
76
60
47

Produc­
tion in
thou­
sands of
gross
tons

100-125
25- 50
50- 75
50- 75
50- 75
25- 50
225-250
Under 25
75-100
100-125
Under 25
Under 25
Under 25
25- 50

.

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

1.0
.4

1.0
.9

1.0
.7

2.0

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

All
other
labor

Fur­
nace
crew
labor

All
other
labor

Total
labor

0.268
.400
.425
.377
.425
.262

0.440
.263
.248
.267
.244
.328

0.166
.159
.157
.156
.155
.146
.144
.140

3.736
2. 503
2.355
2. 654
2. 354
3. 818

2.273
3.800
4. 032
3. 745
4. 093
3.048

6.009
6.303
6.387
6. 399
6. 447

3. 385

3.748

0

6.956
7.133

.139
.134
.126

3. 665
3.144

3. 512
4.324

0
0

0
0

0

0

.3

.295

.267

.9

.273
.318

.285
.231

0
0)

0
0

1.0
.1
.4
.5
.9

Total
labor

0

.223

.184

.1 2 1
.10 1

4. 488

0

0

.096

0

6.866

7.177
7.468
7. 968
8. 233
5.424 9. 912
10. 450
0

Aver­
age
out­
put
per
stackday
(gross
tons)

Charging

293.0 H an d .............
219. 5 Mechanical.
177.2 .........do______
180.9 !.........do______
196.1 ____ d o ...........
191.2 H a n d ...........
321.9 Mechanical.
193.0 Hand and
mechanical.
278.2 H and_______
293.3
Mechanical.
192.0 .........d o ............
131.2 H and_______
1 2 2 .1 .........do............
132.6 Hand a n d
mechanical.

Casting

Sand.
Do.
Machine.
Do.
Do.
Do.
Sand.
Sand and
machine.
Sand.
Do.
Do.
Do.
Do.
Do.

1923
1 ...........
25
3______
4 ______
13 .
32

500-525
125-150
325-350
300-325
150-175
100-125
175-200
12
25- 50
23
100-125
22 .
300-325
5______
36......... Under 25
150-175
8 _ .........
125-150
16 .
25- 50
24
100-125
33
300-325
6 - .........
425-450
2 ______
28
7______
45_____

21
50
14
39

20_____
18 ,
19
27_____
34
35
53
46
59
41
52 .

66
17
38
57
49
43
48
4 4 ..

.

100-125
225-250
50- 75
100-125
50- 75
200-225
75-100
125-150
150-175
100-125
125-150
75-100
25- 50
50- 75
50- 75
50- 75
100-125
50- 75
25- 50
50- 75
25- 50
50- 75
50- 75
25- 50
50- 75
Under 25

2.7

1.0
2.0
1.7

1.0
.9

1.6

.5
.7

2.0
.3

1 .1
.7

0.872
0)
.889
1. 795
.674
.730

0

.847

0
0

.620

0
0
0

0. 981
0)
1.060
.532
.975
.692

0

.539

0
0

.614

0
0
0

0
1.0

.418

2.5
3.7

.579

.421

0

0
0
0
0

.7

1.8
.6
.7
.7
1.7

.8
1.0
2.0
.9

1.0
1 .2
.3
.7

.6
1.0
1.0
.7
.7
.7
.5

0

0
0

.319
.497
.458
.526
.422
.334
.741
.368

0

.354
.360
.389
.263
0)
.350

.733

0

.703
.388
.400
.356
.392
.518
.278
.437

0

.441
.374
.276
.403

0

.7
.7
.7

.407
.370
.291
.364
.274

.287
0)
.247
.261
.320
.261
.313

.2

0

0

1.0

0

0. 462
.459
.456
.411
.398
.355
.343
.329
.327
.318
.309
.294
.280
.268
.266
.248
.244
.241
.231
.224
.224
.219
.218
.213

.2 12
.203
.203

.202
.200
.198
.196
.184
.161
.159
.158
.158
.154
.154
.153
.152
.152
. 146
.145

1Detail not reported.




1.147

0

1.251
.557
1.484
1.371

0

1.181

0
0

1 . 612
Q

0
0

2.395

1. 019

0

.943
1.877
1 . 026
1. 445
0)
1.855

0
0
1 . 628
0
0
0

2.166
2.179
2.194
2.434
2.510
2.816
2.917
3.037
3.055
3.141
3.240
3.407
3.566
3. 729
3. 760
4.033
4.102

508.3
356.0
477.5
517.7
462.6
336.1
330. 7
253.4
431.0
444.6
260. 5
382.0
493.4

Mechanical.
____ do______
.........do_______
.........do______
.........d o ............
.........do______
_____d o ...........
____ do_______
.........do............
.........do............
.........do............
.........do_...........
.........do______
_____do______
0
308.0 _____do_______
325.4 _____d o ............
330.8 _____d o „ .........

0
1 . 726

1.365
0)
2.376

0
0
0)
0

3.136
2 . 010
2.185
1. 900
2. 369
2.992
1. 350
2. 714

0
0
0
0

1.423
2. 578
2. 503
2.808
2. 551
1.932
3. 592
2.286

4.150
4.322
4.459
4. 466
4. 559
4.588
4.688
4. 708
4. 919
4. 924
4.942
5. 000

402.4
346.8
287. 5
448.0
212.5
341.0
255.1
377.0
226.5
344.8
360.7
197.1

0
2 . 826
2. 777

0
2 . 266

5.041
5. 092
5.447
6.198
6.282
6.316
6. 338
6.474
6. 509
6. 531
6. 566
6.571
6.841
6.904

370.0

2. 570
3. 798

0

2.858

0

2. 455
2. 704
3. 439
2. 745
3.645
0)

2. 670
3. 629
2.484

0

3. 480
0)
4. 054
3. 827
3.127
3. 826
3.196

0

2 1 2 .1
298.1
182.1
290.9
224.8

120.8
265.0
223.1
199.7
207.6
192.4
250.0
281.6

Machine.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Sand.
Machine.
Sand and
machine.
H a n d ............ Sand.
Mechanical. Machine.
H and.............
Do.
Mechanical.
Do.
_____d o_.......... Sand.
H and............. Machine.
Mechanical.
Do.
H and.............
Do.
Mechanical. Sand.
H and_______ Machine.
Mechanical.
Do.
Hand and
Do.
mechanical.
Do.
( !)
Mechanical. Sand.
____ do______ Machine.
_____do______
Do.
H and............. Sand.
Do.
M echanical.
_____do______
Do.
H a n d .. __ . Machine.
Mechanical. Sand.
H and_______
Do.
Mechanical.
Do.
.........do______
Do.
H and_______
Do.
Machine.
(*)

* Not reported.

108

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

T a b l e B . — Labor productivity, production, output per stack-day and methods of

charging and casting in merchant blast furnaces in the United States, by years
and by plants , 1911 to 1927— Continued

1 9 2 3 — Continued
Average labor productivity

Plant
N o.

54
73
30
65_____
15
31
40
47...

68_____

Produc­
tion in
thou­
sands of
gross
tons

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

25- 50
25- 50
225-250
50- 75
75-100
50- 75
75-100
50- 75

0.6
.8
2.0
1.0
1 .1
1.0
1.0
1.0

0.392
.240
.239
.425
.292
0)

.307
.303
.193

.6

.203
.366
. 202
.239

11

255050252550-

78
65
71

Under 25
25- 50
Under 25

51
42.........
60
76

50
75
75
50
50
75

.7

.8
.7

.6
.9
.4

Gross tons of pig
iron produced per
man-hour
Fur­
nace
crew
labor

.2 2 1
0)

0

.214

0

.6

.140

.3

0

All
other
labor

0.225
.375

Total
labor

Method of—

Aver­
age
Man-hours per gross
out­
ton of pig iron pro­
put
duced
per
stackday
Fur­
All
(gross
nace
Total
other
tons)
crew
labor
labor
labor
2.551
4. 535

.2 12
0

0.143
. 139
.139
.135
. 133
. 133
.123
. 122

0

0

.276
. 171
.257
. 197
( 1)
.206

. 117
.117
. 113
.108
.106
.105

4. 917
2. 732
4. 943
4.191
0)
4. 664

3.619
5. 843
3.884
5. 066
0)
4.845

0)
.220
0)

.086
.085
.069

0)
7.169

11. 574
0)
4. 544 11. 713
14.405
0

0

0

4.163
4.190
2. 353
3.427

0

4.435
2.663

0

3. 258
3. 304
5.188
4.713

6.986
7.199
7.204
7. 421
7.494
7. 542
8.139
8. 218

8. 536
8. 575
8. 827
9. 257
9.471
9. 509

Charging

Casting

159.0 Mechanical.
104.1 H and.............
319.1 Mechanical.
183.9 H and_______
237. 3 _____do______
181.0 Mechanical.
269.1 _____do______
155.8 Hand and
mechanical.
198.7 H and.............
209.0 Mechanical _
230.8 H and_______
130.7 _____do______
114.0 .........do______
171.1 Hand and
mechanical.
119.2 H and_______
136.2 _____do______
77.7 _____do_..........

Machine.
Sand.
Do.
Machine.
Sand.
Do.
D o.
D o.

557.3
460.3
613.0
378.1
509.3
419.0
318. 5
324.8
303.0
416.0
322.5
416.0
450. 0
340. 6
263. 5
356. 0
350.3
336.5
148.7
281.8
235.2
220.9
213.6
205.4
204.9
195.0

Machine.
Do.
Do.
Do.
Do.
Do.
Do.
D o.
Sand.
Machine.
Do.
Sand.
Machine.
Do.
Do.
Do.
Do.
Do.
Sand.
Machine.
Sand.
Do.
Machine.
Sand.
Machine.
Sand.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.

D o.
Do.
Machine.
Sand.
Do.
Sand and
machine.
Sand.
Do.
Do.

1922
2.0
1.0
.2
1.0

46
53
43
34
18
5 5 ____
57
49
30
31
54
74
15
52
47

400-425
150-175
50- 75
125-150
225-250
100-125
25- 50
125-150
50- 75
175-200
175-200
75-100
200-225
Under 25
75-100
75-100
150-175
75-100
Under 25
Under 25
25- 50
75-100
Under 25
75-100
50- 75
Under 25
25- 50
200-225
25- 50
25- 50
Under 25
50- 75
Under 25
Under 25

68
11

Under 25
Under 25

59.........
25- 50
75
Under 25
65
Under 25
Under 25
71

1 ...........
13
16
9______
3____ _

22

32

12
33
4...........
6_ .........
28
5 _ .........

21
39

20
7 . .........
19__ . .

66

1.3
.7
.4

1 .1

.5

1 .2
1.4
.5

1 .2
.1
1.0
.8
1 .2
.7

.2
.1
.5

0

0

.784
.526
.627

0

.597

0

.415
0)

.717

.381

.642

0

0
0)
.467
.471
.736
.338
.412
.396
.353
.421
.394
.383
.289
.392
.288
0)
.483
.304
0)
.265
0)

0
0

0
0

.422
.409
.308
.562
.418
.412
.440
.313
.309
.287
.372
.277
.311

0.442
.436
.371
.353
.314
.312
.306
.290
.263
.243
.241
.239
.235
.227

.2 22
.219
.217

.2 1 1
.207

.202
.200

0

0

.180
.173
.164
. 163
.162
.150
.149
.147
.139
.138
.134
.125
.117

.1
.2

.20 1

.273
.225

.1 1 1

.6

.242

.3

.2

0

.149

.193
0)
.236

.3

0

0

1.0
.1
1 .2
.9
.3

.6
1.7

.6
.5

.1
.6
.2
.2

i Detail not available.




0

0.940
.977
0)
.642
.782

0.835
.786

.218

0
.2 12
.255
0)
.273
0)

.116
.107
. 105
.091
.077

1.197
1. 272

0

1. 276
1.902

0

1.595
0)
2.412

0
0

2. 625
0)

0

2. 423

2 .12 1
1. 359
2.963
2.428
2.525
2.832
2. 372
2. 539
2. 613
3.460
2. 548
3.470
0)
2.072
3.285

0

1.064
1. 024

0

1. 557
1. 279
0)
1. 676

0

1.394

0
0

1. 558
0)
0)
2. 367
2.445
3. 249
1. 779
2. 390
2.429
2. 271
3.197
3.232
3.484
2.689
3.607
3. 211

0

4. 712
3.922

0

2 . 262
2. 296
2. 697
2. 833
3.181
3. 203
3. 270
3.447
3. 806
4.108
4.155
4.183
4. 248
4.412
4.507
4. 566
4. 607
4. 741
4.819
4.954
5.103
5. 569
5. 772
6.097
6.149
6.156
6.681
6. 711
6. 784
7.207
7. 222
7.444
7.999
8. 567

210 .1
337.8
177.2
167.6
106.6
256.5
172.5
148.9

3. 777

3. 667

0
0

0
0

4.982
4. 586

3. 667
4.436

9. 021

131.0
206.5

4.133
0)
6. 699

5.174 9. 307
9. 509
0)
4.246 10. 945
12.913
0

136. 6
70.0
145.7
86.9

0

8. 649

Mechanical.
_____do______
____ do______
_____do______
_____do_..........
_____do_..........
_____do______
_____do______
_____do_..........
_____d o_..........
_____do______
H and_______
Mechanical.
_____do______
_____do______
H and_______
Mechanical.
H a n d . . ___
Mechanical.
____ do______
____ d o ...........
____ do______
H and_______
Mechanical.
H a n d _______
___ do______
Mechanical.
_____do______
.........do______
____ do______
____ do______
H and_______
Mechanical.
Hand and
mechanical.
H and_______
Hand and
mechanical.
Mechanical.
H and_______
_____do______
.........do_______

Do.
Sand and
machine.
Machine.
Sand.
Do.
Do.

109

APPENDIX 1.— GENERAL TABLES

B . — Labor productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927 — Continued

T a b le

1921
Average labor productivity

Plant
N o.

Produc­
tion in
thou­
sands of
gross
tons

200-225
1 ______
175-200
3 ______
16_____ Under 25
32_____
50- 75
12
25- 50
50- 75
28
Under 25
39
25- 50
4 ______
25- 50
18
5 . .........
50- 75
75-100
20
14
50- 75
Under 25
54
75-100
5 5 ____
Under 25
57
Under 25
53
Under 25
27
34
25- 50
25- 50
66_____
7______ Under 25
25- 50
19
100-125
6 ______
Under 25
74
50- 75
30
Under 25
43
Under 25
24
Under 25
31
100-125
2 _ .........
Under 25
47

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

1.0
1.0
.1
.5
.4
.5

.2
.4
.5
.5
.7
.5
.3

1.0
.1
.3

.1

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

Fur­
nace
crew
labor

0..8O9
0)
0)
.677

0

.365
.473

0

.532

0
0)

.342
.354
.281
.384
.286
.559
.352
.312

0.910

0
0)

.639
0)
.655
.428
0)
.334

0
0

.325
.296
.377
.272
.357

.2 21

.3

. 237

1.0
.2

0
0
0)

0

.4
(2)
(3)
.1

1.0
.2

.6
.4
.4

0

0)
.233

Total
labor

0.428
.340
.332
.329
.249
.234
.225
.214
.205
.181
. 178
.167
.161
.161
.159
.159
.159
.156
.155
.155
. 150
.143
.139
.137
. 136
.131
. 122
. 120
.119

All
‘ Total
other
labor
labor

1

1.236
0)
0)
1.478

1.099

0
0)

1. 564

0

0

2. 741

1.526

2 .112 2. 338
1 0
0
1.879

0
0

2.924
2.828
3. 556
2. 604
3.491
1.789
2. 843
3. 210
0)
4. 222

0
0
0)

3. 083

!
!

2.998
0)

0

3.073
3. 377
2. 652
3.686
2. 799
4. 518
3. 586
3. 227
0)
2.431

0
0)
0)

574.4
525.5
513. 1
347.1
311.7
398.5
261.0
351.2
243.8
395.4
367.0
395.9
178.0

212.6
190.8
203.5
249.9
219.9
112.5
375.5
321.3
312.6
116.8
337.8
169.5

0

0)

.194
.251
0)
. 153

. 108
.106
.087
.082
.075

(0

4. 263
7.494
0)
6. 744

9. 301
5.152 9. 415
3. 982 11.476
0
!12,169
6.523 13. 267

134.4
71.9
54.2
127. 6

. 121
(3)

.064
(3)

7.318
2. 837

8. 279 15. 597
0
0

218.1
195.9

1. 054
1. 381

464. 7
350.1
476.7
340.3
267.3
438.3
286.4
323.6
267.6

11

50
25
25
25
50

.1
1 .1

.235
.133
0)
.148

15
51

Under 25
Under 25

.1
.3

. 137
.352

0

2.510
3. 388
0)

4.286

2. 334
2. 943
3. 016
3. 043
4.011
4. 267
4.451
4. 680
4.877
5. 512
5. 613
5.997
6.205
6.208
6.290
6.290
6. 307
6.428
6.436
6.444
6. 653
7. 002
7.173
7. 307
7. 369
7. 645
8.192
8. 335
8. 371

.202
(0

0

. 176

Charging

Casting

i

.324
0)
.398
.295
0)

25Under
Under
Under
25-

70
60
77
75

All
other
labor

.279
.310
0)
.411

.5

.6
.2

Method of—
Aver­
age
out­
put
per
stackday
(gross
tons)

0

5. 683
4. 947

0
(0

0

163.0
284.8
155.1

122.8

Mechanical _ Machine.
.........do______
Do.
.........do______
Do.
_____do______
Do.
_____do___ __
Do.
H an d _______ Sand.
Mechanical. Machine
------- do---------Do.
------- do______ Sand.
------- do______ Machine.
H an d _______
Do.
_____d o______
Do.
Mechanical. Sand.
H and_______ Machine.
_____do______ Sand.
Mechanical.
Do.
H and_______
Do.
____ do______ Machine.
Mechanical. Sand.
____ do______ Machine.
H and_______
Do.
Mechanical.
Do.
____ do______ Sand.
Do.
____ do______
Do.
____ do______
.........do______ Machine.
____ do______ Sand.
Do.
____ do______
Hand and
Do.
mechanical.
Do.
H and_______
Do.
.........do______
Do.
____ do______
Do.
____ do______
Hand and Sand and
mechanical.
machine.
H and_______ ; Sand.
Mechanical. i Do.
I

1920
1 ...........
9 ...........
3 ...........
3 2 ____
36.........
16
25
12
45
80
24
14
28
39
6 ...........
4
20 . .
2 ...........
46

475-500
250-275
325-350
75-100
75-100
125-150
75-100
175-200
75-100
Under 25
125-150
175-200
100-125
50- 75
4 300-325
300-325
100-125
325-350
75-100

2.9

2.0
1.9

.8
.8
.9

0. 843
.883

0

.631
.554

0

.8
1.6
.8
0
0
1.6
.8
.8
2.6
2 .1
1.0

.383

3.5
.9

.410
.315

0

0

.572
.601

0

.586

0

.377

.592

0
0

0
(0

.426
.361
.412
. 597
0)

0

1 Detail not available.
* N ot reported.




0. 948
.724

.403
.443
.372
.288

0
0

.286
.327

0. 446
.398
.315
.300
.288
.246
.232
.231
.230
.214

.2 1 1
.207
.199
. 196
.194
. 189
. 183
. 168
.161

1.186
1.132

0

1. 585
1. 805

0
2 . 610
0
2. 651

0
0

0

1. 749
1. 665

0

1. 707
0)
1. 689

0
0

2. 345
2. 769
2. 427
1. 675
0)

2. 480
2 . 260
2 . 686
3. 472

2. 439
3.175

3. 502
3. 054

0

0
0

2. 241
2. 513
3.173
3. 334
3. 470
4. 066
4.318
4. 327
4. 340
4. 667
4. 744
4. 825
5.028
5.113
5.147
5. 278
5.472
5.491
6. 229

0
0

347.8
394.4
249.7
319.8
389. 3
341.0
265.6
283.8

Mechanical.
____ do_______
____ do.......... ..
___ do________
____ do_______
____ do.............
____ do.............
____ d o ............
H and_______
(3)
Mechanical.
H and_______
____ do_______
Mechanical _
____ do_______
____ do_______
H and_______
Mechanical _
____ do_______

2 Plant operated less than 18 days during year.
* Fiscal year M ay 1,1919, to Apr. 30,1920.

Machine.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Sand.
Machine.
Do.
Do.
Do.
Sand___
Machine.

110

L A B O R P R O D U C T IV IT Y — M E R C H A N T B L A S T F U R N A C E S

B .— Labor productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927 — Continued

T a b le

1 9 2 0 — Continued
Average labor productivity

Produc­
tion in
thou­
sands of
gross
tons

Plant
No.

43.........
22 .........
33.........
7...........
19_____
49
5 7 ....
55
61
27
30

25- 50
100-125
75-100
200-225
75-100
50- 75
50- 75
50- 75
25- 50
75-100
175-200
25- 50
75-100
Under 25
25- 50
50- 75
50- 75
50- 75
25- 50

68
53

66
67

21
34
31
47
60_____
54
52
64
51
15
70
77
65
59 . . _
18
74
75
79
73
71
42

11
69

.

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

0.6
1.0
.9

1.8
.7

.8
1.0

.9

.6
1.0
1.9
.9

1.0
.6
(*)

.8
.9

1.0
1.0

Method of—
Aver­
age
out­
put
per
stackday
(gross
tons)

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

Fur­
nace
crew
labor

All
other
labor

3. 560
0)
2. 229
0)
2. 377
3, 445
4. 057
3.313
0)
5.512
0)
3.433
3. 766
4. 402
0)
0)
4. 891
6. 575
0)

6. 299
6. 464
6. 594
6. 633
6. 682
6. 765
6. 923

.1 1 2

2. 739
0)
4. 365
I1)
4. 305
3. 320
2 . 866
3. 757
0)
2.183
0)
4. 664
4. 697
4.106
0)
0)
3. 735
2.143
0)

7. 069
7.477
7. 695
8.019
8.097
8.464
8. 508
8. 542
8. 605
8. 626
8.718
8. 960

217.7
324.0
264. 0
317. 0
314. 0
229.5
184. 9
165. 3
134.8
220.9
273.2
140. 2
212. 7
100. 8
(3)
242.8
171.4
171.7
130.0

4.102
5. 747
0)
3. 699
3. 004
5. 290
0)
7. 591
7. 084
5. 232
6. 705
0)
0)
0)
0)
0)
0)
6. 830

4. 958
3. 960
0)
6. 461
7. 754
5. 656
0)
4. 034
4. 491
6. 527
5. 442
0)
0)
0)
0)
0)
0)
7. 215

9. 060
9. 707
9. 891
10.160
10.758
10. 946
10. 961
11.625
11.575
11. 759
12.147
12. 276
12. 385
12. 734
12. 785
13. 920
13. 941
14.045

135. 9
167.0
218. 4
140.8
189.1
223. 3
110 . 8
75.7
139.9
137.0
215.1
75.9
52.9
76.0
80.4
80.0
169.9
136.0

8. 544

7. 218 15. 762

1. 676
1. 752
0)
0)
0)
2. 490
2.880
2. 512
2.193
0)
1.811
0)
2. 267
1.898
4. 579
0)
3. 204

All
other
labor

0.365
0)
.229
0)
.232
.301
.350
.266
0)
.458
0)
.214
.213
.244
0)
0)
.268
.467
0)

0. 281
0)

. 244
. 174
0)
.270
.333
. 189
0)
. 132
.141
.191
. 149

.20 1

0)
0)
0)
0)
0)

0)
0)
0)
0)
0)

.449
0)
.421
. 290
. 247
.302
0)
.181
0)
.291
.266
.227
0)
0)
.205
.152
0)

Total
labor

0.159
. 155
.152
. 151
. 150
. 148
. 144
. 141
. 134
. 130
.125
. 124
. 118
. 118
.117
.116
. 116
.115

25- 50
50- 75
25- 50
25- 50
50- 75
150-175
25- 50
Under 25
25- 50
25- 50
75-100
25- 50
Under 25
Under 25
25- 50
Under 25
25- 50
150-175

1.0

3.4

.146

. 139

. 110
. 103
. 101
.098
.093
.091
.091
.086
.086
.085
.082
.081
.081
.079
.078
.072
.072
.071

25- 50

.9

.117

.139

.063

.9
.5

.8
1.0
1.9

1.0
.9
.9

.8
1.0
1.0
1 .2
.4

1.0
.8
.8

.253
0)
. 155
. 129
. 177
0)
.248
.223
.153
. 184

Total
labor

Charging

Casting

Sand.
Machine.
Sand.
Machine.
Do.
Sand.
Do.
Machine.
Sand.
Do.
Do.
Do.
Do.
Do.
Do.
Machine.
Do.
Sand.
Do.

115. 2

MechanicaL
____ do_______
____ do_______
____ do_______
H and_______
Mechanical.
H and.............
____ do_______
____ do_______
____ do_______
Mechanical.
Hand ______
____ do_______
Mechanical.
____ do_______
____ do_______
Hand _ __
Mechanical.
Hand and
mechanical
Hand
____ d o ...........
____ do_______
____ do_______
Mechanical.
H a n d ............
_ d o _____
____ do_______
____ do_______
Mechanical.
H and_______
____ do_______
____ do ............
_ do —_ _
. do
do
____ do_______
Hand and
mechanical.
H and_______

308.0
319.9
455.7
373.0
(3)
260.1
291.7
353. 5
396.7
399.8
241.0
241.4
333.2
253.0
279. 6
162.0
262.6

Mechanical.
____ do_______
____ do_______
____ do_______
____ do_______
____ do_______
____ do_______
H and.
____ do_______
Mechanical,
____ do_______
____ do_______
H an d_______
Mechanical.
____ do_______
H and_______
Mechanical.

Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Machine.
Sand and
machine.
Sand.

1919
9
32
.
16
4 ...........
24
39
2 . .........
14
28
3 ...........
36

12
19
33
6............
61
46

175-200
100-125
100-125
225-250
100-125
50- 75
300-325
200-225
75-100
175-200
50- 75
100-125
100-125
75-100
* 250-275
25- 50
75-100

1.7
.9

.6
1.8
0)
.6
3.0
1.7

.6
1.4

.6
1 .2
1.0
1.0

2.5

.6
.8

0.728
.611
0)
0)
0)
.444
.530
.421
.355
0)
.288
0)
.270
.238
.556
0)
.300

i Detail not available.




0. 597
.571
0)
0)
0)
.402
.347
.398
.456
0)
.552
0)
.441
.527
.218
0)
.312

0. 328
.295
.269
.237

.222
.2 11
.210
.205

.200
.197
.189
.172
. 167
. 164
.157
. 155
. 153

8 Not reported.

1.373
1.638
0)
0)
0)
2. 250
1.887
2. 376
2. 813
0)
3. 477
0)
3. 704
4. 202
1.799
0)
3. 332

3.049
3. 390
3. 717
4. 216
4. 508
4. 739
4. 767
4. 888
5. 007
5. 070
5. 288
5. 824
5. 971

6.100
6. 379
6. 446
6. 536

Machine.
Do.
Do.
Do.
Do.
Do.
Sand.
Machine.
Sand.
Machine.
Do.
Do.
Do.
Sand.
Machine.
Sand.
Machine.

Fiscal year May 1, 1918, to Apr. 30, 1919.

111

APPENDIX 1.---- GENERAL TABLES

B . — Labor 'productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927 — Continued

T a b le

1 9 1 9 — Continued
Average labor productivity

Plant
N o.

Produc­
tion in
thou­
sands of
gross
tons

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

Fur­
nace
crew
labor

50- 75
Under 25
100-125
50- 75
175-200
50- 75
25- 50
175-200
25- 50
50- 75
175-200
50- 75
50- 75
50- 75
Under 25
50- 75

0.9

1.0

11

50- 75
Under 25
Under 25
25- 50
50- 75
Under 25
50- 75
Under 25
100-125
Under 25
Under 25
25- 50
Under 25
Under 25
25- 50
75-100

.5
.4
.7
1.5

. 217
.171
. 145
.242
0)
. 166
. 180
C1)
0)
. 145
. 122
0)
. 160
. 134

69

25- 50

.9

.1 1 1

55
49_____
27

21

5
43
57
7______
53
51
30 .
31 ,
54
41
60
47
52

66
34
18
65
64
42
63
15
73
70

68
77
71
59

.2

0. 273
. 280
. 505
0)
0)
.266
.314
0)
.223
0)
0)
.451
. 186
.180
.237

.9

(0

.2
1. 2
.7
1.4
.9
.4

1.6
.5
.7

1.8
1 .2
.9
.5

.5

.2
.5

1.0
.3

1.0
.3

1.6

.5
.7

1.0

Method of—

0)
.2 12

All
other
labor

Total
labor

0.309
.298

0 145
. 144
. 143
.140
. 137
.137
. 130
. 128
. 124
.123

Total
labor

. 135
. 115

0)
4. 723
609
5. 856
6. 913
4.136
C1)
6.035
5. 542
0)
0)
6. 902
8. 220
0)
6. 240
7. 451

0)
5. 545
5. 925
4. 937
4.382
7. 225
0)
5. 837
6. 384
0)
0)
5. 081
4. 368
0)
7.433
8. 694

. 131

.060

9. 015

7. 615 16. 630

109.1

1. 650
1.941
0)
0)
2. 725
3. 322
2. 017
2. 942
0)
3. 011
2. 740
3. 790
0)
3.231
0)
4. 790
4. 773
0)
0)
2. 335
5.348
3.365
3.863

337. 6
286.0
452. 3
397.4
241.7
295.2
217.7
285. 5
213.2
279.4
300.0
(3)
297.9
324.5
342.5
205.5
253.4
296.0
315.0
245.0
171.6
(3)
206.3

Mechanical. Machine.
------- d o ...........
Do.
------- do........ .
Do.
_____do............
Do.
_____do.......... ..
Do.
_____do............ Sand.
H and............ Machine.
Do.
_____d o ...........
Mechanical.
Do.
_____do............
Do.
H and............. Sand.
_____do............
Do.
Mechanical. Machine.
H a n d .......... Sand.
_____do______ Machine.
_____do............ Sand.
Mechanical. Machine.
____ do............
Do.
H and_______
Do.
Mechanical. Sand.
_____do............
Do.
H and_______
Do.
Mechanical.
Do.

.278
0)
0)
.148
.270
.270
.196
0)

0)

. 180
. 169
.203
.228
. 138
0)
.171
. 157
0)
0)
. 197
.229

(0

.1 1 2
.1 1 1
. 110
. 108
. 107
.099

(0

162.6
213.5
237.3
243.7
362. 2
204.3
194. 9
304.3
207.9
223.7
277.5
164.8
178. 9
286.0
129.8
155.1

10.100
10. 268

196. 0
93.1
171.1
233.7
147.1
145.2
194.6
125.1
212. 5

Casting

.099
.097
.095
.093
.089
.088
.085
.084
.084
.084
.083
.083
.079
.079
.073
.062

.281

.222
0)

3. 235 6.903
3.358 6. 928
4. 998 6. 977
7.141
0)
7. 276
0)
3. 563 7. 320
4. 510 7. 696
7. 793
0)
3.597 8.082
8.132
0)
8. 940
0)
6. 764 8. 981
3. 697 9. 062
3.707 9. 267
5.100 9. 321
10. 096
0)

Charging

H and_______ Machine.
Mechanical. Sand.
H and .............
Do.
Mechanical. Machine.
.........do............
Do.
_____do............ Sand.
H and_______
Do
Mechanical - Machine.
H a n d ______ Sand.
Mechanical.
Do.
____ do............
Do.
____ do.......... ..
Do.
H and.............
Do.
1_____do______
Do.
____ do______
Do.
Hand and
Do.
mechanical.
H and_______
Do.
Mechanical.
Do.
H and_______ Machine.
____ do............ Sand.
.........do..........
Do.
_____do........ .
Do.
_____do............ Machine.
____ do............ Sand.
____ d o ...........
Do.
____ do ...........
Do.
____ d o ...........
Do.
____ d o ...........
Do.
_____do______
Do.
_____do______
Do.
Mechanical Do.
Hand and Sand and
machine.
mechanical.
H and............. j Sand.

.200
0)
0)

3.668
3. 570
1. 979
0)
0)
3. 757
3.186
0)
4. 486
0)
0)
2.217
5.365
5. 560
4. 220

All
other
labor

Aver­
age
out­
put
per
stackday
(gross
tons)

10. 534
10. 793
11. 294
11. 361
11.819
11. 873
11. 926
11. 947
11. 980
11. 983
12. 588
12. 637
13. 073
16. 146

102.2
96.0
85.0
80.4
85.5
117.3
141.0

1918

16.
3 ..
39.
2 ..

36..
14.

12.

46.
48.
57.
7 _.
19.
27.
6. .

22.

20..
33..
31.
53.
43.

100-125
175-200
150-175
275-300
50- 75
425-450
50- 75
175-200
150-175
75-100
75-100
50- 75
200-225
75-100
100-125
100-125
« 250-275
100-125
100-125
75-100
100-125
50- 75
75-100

1.0
1.9

1.0
2.0
.8
4.0
.9
1.7

2.0
1.0
.9
(3)

2.0
.7

1.0
1.6
2.8
1.0
1.0

.9
1.7
(3)

1.0

i Detail not available.




0. 635
.629
0)
0)
.406
.492
.299
.359
0)
.319
.284
.374
0)
.291
0)
.474
.444
0)
0)
.197
.478
.238
.269

0. 606
.515
0)
0)
.367
.301
.496
.340
0)
.332
.365
.264
0)
.309
0)
.209
.209
0)
0)
.428
.187
.297
.259

0.310
.283
.272
.264
.193
.187
.187
. 175
. 171
. 163
.160
.155
.153
. 150
.147
. 145
.142
.136
.135
.135
.134
.132
.132

1. 576
1 . 590
0)
0)
2.462
2. 033
3. 345
2. 782
0)
3.132
3.523
2. 677
0)
3. 439
0)
2.109
2. 251
0)
0)
5. 077
2.091
4.197
3. 722

* Not reported.

3. 225
3. 531
3. 672
3. 784
5.187
5. 355
5. 362
5. 724
5. 846
6.141
6. 264
6. 467
6. 554
6. 670
6. 785
6. 899
7. 023
7. 374
7.391
7.412
7.439
7. 562
7.585

8 Fiscal year May 1, 1917, to Apr. 30, 1918.

112

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

B . — Labor productivity, production, output per stack-day and methods o f
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927 — Continued

T a b le

1 9 1 8 — Continued
Average labor productivity

Plant
No.

61
49
50
41
52

.

Produc­
tion in
thou­
sands of
gross
tons

25- 50
50- 75
25- 50
75-100
75-100
225-250
100-125
50- 75
75-100
175-200
50- 75
50- 75
100-125
150-175
75-100

10
17
51
35
30
54
34
18
15
47

66

Under 25
25- 50
71. .
59
25- 50
7 0 ____
25- 50
42_____
50- 75
Under 25
77
62
50- 75
73
25- 50
68
25- 50
11
200-225

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

0.7
.7
.9
.9

1.0
1.8
1.7
.7
.9
2.4

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

All
other
labor

Fur­
nace
crew
labor

0)
0. 251
0)

0)
0. 266
0

0.131
. 129
. 127
. 121
.113

0
0)
0)
0)
0

.112

.202
0)
0)
0
0)
0)
0)

2.0
2.0

.156
.188
0)

.8
1.0
1.0

.194
0)
.181

.157
0)
.153

.8

0)
. 124

0
1.0
.8

0
0
. 121

4.7

. 141

(3)
1.5

.9
.9

. 164

.303
0)

.237
0)
.213
. 169
0)

.8

M ethod of—

0

0

0
0

.233
(■1)

0

. 165
.128

Total
labor

.103
. 102

.100
.098
.097
.091
.090
.089
.089
.087
.085
.083
. 083
.082
.081
.079
.070
.070
.067

(0

3.989
0)
4. 948
0)
0)
0)
0)

0
0
6.122
0)

6.409
5.313

0
5.156

0

5. 530

0
0
8. 080
0)
0
8. 236
7.082

All
other
labor

Total
labor

7. 636
7. 753
7. 896
3. 299 8. 247
8. 872
0)
8. 920
0)
9. 666
0
9. 798
0)
10 . 021
0
10.180
0
4. 218 10. 340
11.0 12
0)
4. 692 1 1 .10 1
5.911 11.224
11. 285
0

Charging

Casting

141.4 H and_______
186.4 Mechanical.
145. 5 ___ do
260.6 Hand .
221.9 ------- do.......... ..
345.5 Mechanical.
176. 7 H and_______
192. 6 Mechanical.
267.0
0
209.4 M echanical..
165. 7 Hand_ ___
_____do
0
194.3 ------- do______
209.8 ------- do______
132.9 Hand and
mechanical.
81.1
Mechanical _
93.7 H a n d ...........
132.4 Mechanical.
90.1 H and_______
189.4 ____ do______
79.1 ____ do ._ ___
__ ..d o ___
0
88.6 ____ do______
90.0 ____ do.
___
120.7 Hand and
mechanical.

D o.
Do.
Do.
D o.
Machine.
Sand.
Do.
D o.
Do.
Sand and
machine.

3. 071 376. 8 Mechanical
3.128 356.6 ____ do______
3.180 ; 489.5 ____ do______
3. 551 ; 408.1 ____ do______
4. 800 300.0 H a n d ...........
4.960 285.2 Mechanical.
5.006 258.0 ____ do______
5. 625 318.3 Hand
5. 683 213.5 ____ d o ______
5. 830 370.0 Mechanical.
5.959 232.8 _____d o______
6.001 352.9 H a n d ...........
6. 029 314.0 Mechanical.
6.140 366.0 H a n d ............
6.545 264.9 Mechanical _
6.792 280.3
0
6. 851 175.7 Mechanical.
6.856 155.1 H an d_______
7.039 261.6 Mechanical.
7.133 151.3 ____ do______
7.137 226.1 Hand
7.171 289.0 _____do______
7.314 186. 0 Mechanical.
7. 351 252.5 .........d o ---------7. 469
96.0 .........do______
7. 693
H a n d ...........
0
7. 713 155.0 .........do______
8.030 287.0
0
8.136 248.1 Mechanical .
8.156 139.8 H an d .
8. 360 157.0 .........do............

Machine.
D o.
D o.
D o.
Do.
Do.
Sand.
D o.
Machine.
D o.
D o.
Do.
D o.
Do.
Do.
Sand.
Do.
Do.
Machine.
Sand.
D o.
D o.
D o.
D o.
D o.
D o.
D o.
Machine.
Sand.
Do.
Machine.

0

3. 765

0

6. 365
0
6. 556
0)
0)

Aver­
age
out­
put
per
stackday
(gross
tons)

11. 521
11.700

12 . 086
12 . 0i;0
12 . 186

4. 294 12. 374
12. 690
0
14.194
0
6. 063 14. 299
7. 792 14. 874

Sand.
Do.
Do.
Do.
Do.
Machine.
Sand.
Do.
Machine.
Sand.
Do.
Do.
Do.
Do.
Do.

1917
4...........
32
16
3
14
39
33
28
36

22
12
19
7______

20
46
44
31
61
6 . .........
50
27
41
49
43

66
53
63
35
30
60
55

400-425
100-125
175-200
275-300
175-200
50- 75
75-100
100-125
75-100
100-125
150-175
125-150
225-250
125-150
75-100
100-125
125-150
50- 75
7 200-225
50- 75
75-100
75-100
50- 75
75-100
25- 50
50- 75
50- 75
100-125
250-275
50- 75
50- 75

2.9

.8
1.0
2.0
1.7

.6
.9

1.0
1.0
.9

2.0
1.0
2.0
1.0
.9

1.0
2.0
1.0

.429
0)
.293
.291
.279
.400
0)

0

.616
0)
.300
0)
.513

0

2.3

.469

1.0
1.0
.8
1.0

0

.9
.9

0
1.0
1.0
3.0

1.0
.9

1 Detail not available.




0
0. 686
0)
0

.480
.239
.261
.259
.286
.234
.255
.247

0

.271
.225

0

0. 599

0
(0

.405

0

.627
.456
.475
.300
0)

0

.227

0

.312
0)
.204

0

.204
0)
.198
.334
.283
.286
.252
.291
.264
.249

0

.224
.255

0.326
.320
.314
.282
.208

.202
.200
. 178
. 176
.172
.168
.167
. 166
. 163
.153
.147
.146
. 146
. 142
. 140
. 140
.139
. 137
. 136
. 134
. 130
. 130
. 125
. 123
. 123

.12 0

* Not reported.

0)
1.458
0)
0)
2. 333
0)
3.412
3. 431
3. 580
2.500
0)
0

1. 624

0

3. 337
0)
1. 948

0

2.134

0

2. 084
4.181
3. 774
3. 859
3. 495
4. 273
3. 921
4.045
0)
3. 693
4. 443

0)
1. 670
0
0)

2. 467

0

1. 595
2.195
2.103
3. 330
0)

0

4. 405
0)
3. 209
0)
4. 901
0)
4. 905

0

5. 053
2. 990
3. 540
3. 491
3. 974
3. 420
3. 792
3. 985
0)
4. 463
3.918

7 Fiscal year from May 1,1916, to Apr. 30,1917.

113

APPENDIX 1.— GENERAL TABLES

B . — Labor productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927— Continued

T a b le

1 9 1 7 — Continued
M ethod of—

Average labor productivity

Plant
N o.

Produc­
tion in
thou­
sands of
gross
tons

50- 75
125-150
50- 75
25- 50
150-175
50- 75
25- 50
25- 50
25- 50
50- 75
25- 50
50- 75
25- 50
25- 50

48
18
51
52 .
15
34
65
64_ .
71
42
73
62
59
69.... .

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

0. 7

1.8
1.0
.4
1.9

0

.8
.8
.8

(3)
.9

0

.9

1.0

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

All
other
labor

Fur­
nace
crew
labor

All
other
labor

0
0)
0
0)
0
0

0)
0)
(0
0)
0
0

0
0)
0
0
0)
0

0
0
0
0
0)
0

0. 146
. 241
0)
0)
0)

0.231
. 138

. 151
. 109

.124
. 129

0

0
0
0
0)

Total
labor

0.115
. I ll
. I ll
. 109
. 106
.097
.090
.088
.082
.075
.070
.069
.068
.059

8. 702

Charging

Casting

9.009
9.031
9.191
9. 457
10. 313
11 . 161
11. 403
12 . 208
13. 245
14. 220
14. 535
14. 689
16. 972

248.0 H an d_______
215.9 _____do---------192.7 Mechanical.
205. 8 H an d_______
229. 5 _____d o ...........
.........d o............
0
143.0 .........d o ...........
149.1 .........do______
91.6 ____ do______
____ d o ...........
0
87.9 ____ do______
0 - ____ do______
10 S. 6 Mechanical.
109.1 H an d ...........

Sand.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
Machine.
Sand.
Do.
Do.
Do.

3.404
5.818
5. 843
6. 608
7.014
7.187
7. 328
0
5. 435 7. 740
10. 494
0

445.9 Mechanical.
285.2 ____ do______
173.5 H a n d ............
259.7 Mechanical.
208.6 H and_______
88.2 Mechanical.
283.6 ____ do______
167.4 ____ do______
182.4 H and_______

Machine.
Do.
Do.
Do.
Do.
Do.
Do.
Do.
D o.

3.197
4. 684
5.514
6. 772
6. 863
7. 280
(0
5. 855 7. 527
7. 764
0)
5. 826 8. 212
11.355
0

450. 9
282. 4
285. 2
90.8
245.6
270.8
206.0
184.6
179.4
190.2

Mechanical.
____ do______
_____do............
_____do............
____ d o ...........
_____do______
H and______
____ do______
Mechanical.
H and_______

Machine.
Sand.
Do.
Do.
Machine.
Sand.
Do.
Do.
Do.
Do.

382.4 M echanical.
| 333.4 _____d o ...........
i 368.0 H and_______
283.9 Mechanical.
216. 7 H a n d ..
284.4 ____ do______
477.8 Mechanical.
314.3
244.0 H a n d . . ___
1 317.2 ____ do............
1 266.6 Mechanical .

Machine,
Do.
Do.
Do.
Sand.
Do.
Machine.
Sand.
Do.
Do.
Do.

4.152

4. 330
7. 251

0
0)
0
0

0
0
0
0

6. 831

Total
labor

Aver­
age
out­
put
per
stackday
(gross
tons)

6. 634 8. 055
9. 200 i 7.772

1916
16

.

6 ...........

61.........
46
27

66
30
31
52

100-125

8 75-100
25- 50
75-100
100-125
25- 50
275-300
75-100
50- 75

0.7
2.9

V)
0. 529

0. 255

.8
1.0

0

0

1.4
.9
2.7

1.6
1.0

0

.297
.393
.263

.309
.224
.296
0)
. 184

0

.434

0

0

0. 294
. 172
. 171
. 151
. 143
. 139
.136
. 129
.095

0

1.891
0)
3. 369
2. 543
3. 809
0)
2. 305
0)

0

3. 927
0)
3.240
4.470
3.378

1915
16
39
6 ...........

66

46
30
27
61
31
52

125-150
100-125
275-300
25- 50
50- 75
200-225
50- 75
Under 25
50- 75
50- 75

0.9

1.0

2.9
.9

.6
2 .2
.8
.3

1.0
1.0

0)
0)
0. 549
.270
.272
0)
.598
0)
.419

0. 271
.326
.314
0)
. 171

0

0.313
.214
.181
. 148
.146
.137
. 133
.129

. 172

.12 2

0

0

.088

0
0

0)
0

1.822
3. 706
3. 677

0

1.673

0

2. 386
0)

0
0

3. 693
3. 066
3.186

1914
16
„
1 ...........
29
4 . .........
45
14
3...........

8
48
19

12

125-150
225-250
» 100-125
175-200
75-100
150-175
150-175
100-125
50- 75
50- 75
75-100

1.0
1.8
.8
1.9

1.0
1.6
1 .2
1.0

.7
.5

1.0

>Petail not available.




0
0
0
0
0)

0
0
0)
0
0

0. 376

0. 356

0
0

0
0

.275

.401

0
0

0
0

0. 274
.243
.231
.217
. 188
. 183
.172
. 170
.163
.161
. 149

I Not reported,

0
0
0)
0
0

2. 656

0
0

0
0
0
0
0

2. 807

(0
0

3. 636

2.496

0
0

0
0

3. 653
4.115
4. 336
4.612
5.311
5.463
5.819
5. 886
6.132
6. 209
6. 697

8Jan. 1,1916, to Apr. 30,1916.

•Fiscal year.

114

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

B . — Labor productivity, production, output per stack-day and methods of
charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927— Continued

T a b le

1 9 1 4 — Continued
Average labor productivity

Plant
No.

Produc­
tion in
thou­
sands of
gross
tons

33
50- 75
200-225
6 ...........
27
25- 50
50- 75
46-------81
50- 75
Under 25
57
30
200-225
10
9 125-150
51
75-100
34.........
25- 50
73
25- 50
42
50- 75
52
50- 75
54
25- 50
Under 25
66
2 ......... .
400-425

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

0.8
2.0
.6
.7

1.0
0
2.0
1.3

1.0
(3)
.9
(3)
.9

1.0
.5
3.7

Method of—

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

Fur­
nace
crew
labor

All
other
labor

0. 209
.498
.498
.217
.439
.307
0)

0.481

.393
0)

. 167
0)

. 148
. 120
.552

.215
.227
(3)

.201
. 198
.325
. 185
.217

0
0

0

0
0
0

0
0
(0

Total
labor

0.145
. 143
. 142
. 130
. 130
. 127
. 127
. 117
. 117
. 104
.094
.093
.089
.088
.078
(3)

4. 795
2. 009

2 . 006
4. 603
2. 277
3. 255
0)

0

2. 546

0
0
0
0

6. 756
8. 329
1.917

All
other
labor

Total
labor

2.078
4. 985
5. 058
3.074
5. 418
4. 607
0)
0)
5.983
0)
0)
0)
0)
4. 655
4.414
(3)

6. 873
6. 994
7. 064
7. 677
7. 695
7. 863
7. 891
8. 523
8. 528
9. 565
10. 604
10. 720
11. 193
11.410
12. 743
(3)

Aver­
age
out­
put
per
stackday
(gross
tons)

Charging

Casting

203.0 Mechanical, Sand.
286.8 ____ do______
Do.
212 . 1 H and.
Do.
275. 1 Mechanical.
Do.
192.4 ____ do______
Do.
H and_______
Do.
0
297.0 Mechanical _
Do.
287.6 ____ do______ Machine.
223.9 ____ do______ Sand.
H a n d ...........
Do.
0
89.5 ____ do______
Do.
____ do______
Do.
(3)
174. 9 ____ do______
Do.
134. 7 1____ do______
Do.
72,0 ____ do______
Do.
302.9 Mechanical .
D o.

1913
16
29
7______

22
3
1 4 ____
19
48
33

12
8 ______
5______
6 ______
28
61
55
31
34

10
46
44
51
42_____
66 .
52 .
54
62 .
73 -

125-150

0.9

9 125-150

1.0

175-200
100-125
250-275
200-225
75-100
25- 50
50- 75
150-175
200-225
175-200
225-250
75-100
25- 50
25- 50
50- 75
50- 75
»175-200
25- 50
25- 50
50- 75
50- 75
25- 50
50- 75
25- 50
25- 50
25- 50

1.7

.8
1. 9

2. 0
.8
.5
.9

2.0
2.0
1.5
2.5
.7
.7

0)
0)

0. 523
.519
0)
.335
.297
.283
.245

0. 326
.324
0)
. 403
. 399
.425
.524

0
0)
0

0
0
0)

.436

.239

0

0
0

.8
1.0

C1)
.239
.409

(3)
1.7
.4

0)
.187

.6
.8
0

.9
.9

1.0
(3)
.9

0
0)

.271
. 175

0

0
0

0. 308
.242

.201
. 200
. 196
. 183
. 170
. 168
. 167
. 162
. 162
. 161
. 154
. 152
. 151
. 127
.123
. 122
. 120

.281
0)

.112
.110
. 102

. 141
0)
. 139

.265
0)
. 202

0
0

0
0

.092
.092
.087
.083
.082
.082

0
0)
0)

0
0

0
0

1. 914
1. 926

0

0)
0

3. 067
3. 085

0

2. 9S8
3. 369
3. 529
4. 077
0)

2. 480
2. 507
2, 352
1. 910

2. 291

4.192

0
0

0
0

4.186
2. 443

0
0

5. 337

0
0

7.110

0
0
0
0
0

3. 691
5. 716

0
0

3. 564

0
0
0

7.169

0

3. 768
0)
4. 940

0
0

0
0)

I
3. 252 1 389.0 Mechanical _
4. 130 360. 0 H and_______
4. 981 291. 5 Mechanical _
5. 011 335. 0 ____ do______
5. 099 353. 9
5. 467 i 286.7 H and_______
5. 876 274. 3
5, 952 252.0 ____ do______
5. 987 221.0
Mechanical.
6,171
229.8 _____do______
6.171 288. 2
0
6. 226 320.8 Mechanical.
6. 484 270.2 ____ do........ .
6. 561 319.6 H and.............
6. 609 163. 4 .........d o ............
7. 877 160.0 ____ do______
8.158 181.8 Mechanical8. 208
H and. ____
0
8. 303 316.2 Mechanical.
8. 901 235.9 ____ do______
9.104 203.9
0
9. 817 201.4
Mechanical .
10. 849
Hand _ __
0
10. 879
89.0 _____d o ...........
11.494 172.2 _____do______
12.109 129.2 _____do______
12.141
_____do______
0
12.157
81.9 .........do______

Machine.
Do.
Do.
Do.
Do.
Sand.
Do.
Do.
Do.
Do.
Do.
Machine.
Sand.
Do.
Do.
Machine.
Sand.
Do.
Machine.
Sand.
Do.
D o.
Do.
Do.
Do.
Do.
Do.
Do.

1912
16.........
4______
3...........
29

22
7 _.........
48
28
14

125-150
225-250
200-225
* 100-125
100-125
175-200
75-100
75-100
125-150

0.9

2.6
1.5
.9

0
0
0
(0

1.0
1.8
1.0
.6

0. 501
.544
.293

1.4

.361

0

0. 350
.332
.431
0)
.307

1 Detail not available.




0
0
0
0

0. 299

.222
.220
.219
.206
.206
. 174
.172
.166

0)
0)
0
0

1.997
1. 837
3.416

0

2. 770

0
0
0
0

2. 854
3. 016
2. 320

0

3. 255

8 Not reported.

3. 340
4. 503
4. 549
4. 570
4. 851
4. 853
5. 736
5. 830
6. 025

385.3
251.0
397.7
347. 0
330.0
289.5
266. 0
359.7
286.0

Mechanical. Machine.
_____d o ............
Do.
____ do______
Do.
H and_______
Do.
Mechanical.
Do.
____ do______
Do.
H and_______ Sand.
Do.
____ do_______
_____d o ............
Do.

8 Fiscal year.

115

APPENDIX 1.----GENEBAL TABLES

T a b l e B .— Labor productivity, production, output per stack-day and methods of

charging and casting in merchant blast furnaces in the United States, by years
and by plants, 1911 to 1927— Continued

1 9 1 2 — Continued
Average labor productivity

Plant
N o.

12
61
5______
39
33
31 _
51
55
57 _
42
46
5 3 ____
73
34

10

52
54
62

Produc­
tion in
thou­
sands of
gross
tons

100-125
50- 75
125-150
50- 75
25- 50
75-100
75-100
50- 75
50- 75
50- 75
75-100
50- 75
25- 50
25- 50
9 100-125
50- 75
25- 50
25- 50

Aver­
age
full­
time
fur­
naces
active
dur­
ing
year

1.4

1.0
1 .1

.5
.5
1.3

1.0
1. 0

(3)
(3)

.8

(3)

.8

(3)

1.0
.9

.8
0

M ethod of—

Gross tons of pig
iron produced per
man-hour

Man-hours per gross
ton of pig iron pro­
duced

Fur­
nace
crew
labor

Fur­
nace
crew
labor

All
other
labor

(2)

0)
0)

0)
0)
0)

C1)

0)
0. 206
.452
0)
. 232
.300
0)
.198
. 177
0)
0)
C1)

(0

. 127
0)

0. 440
. 190
0)
. 263
. 211
0)
.297
. 245
0)
0)
0)
0)
. 185
0)

Total
labor

0.152
. 151
. 148
. 144
. 140
. 134
. 131
. 123
. 123
.119
. 119
. 103
. 102
.090
.087
.085
. 075
.052

C1)

0)
0)
0)

4. 855
2 . 211
0)
4.319
3. 381

(0

5. 048
5. 655
0)
0)
0)
0)
7. 850
0)

All
other
labor

Total
labor

0)
0)
0)
0)

6. 588
6. 602
6. 742
6. 967

2. 274 7.129
5. 266 7. 477
7. 650
0)
3. 809 8.128
4. 780 8.160
8. 383
0)
3. 372 8. 420
4. 075 9. 730
0 ) I 9.812
0 ) 11.168
11. 434
(0
0 ) 11. 722
5. 409 13. 259
0 ) 19. 051

Aver­
age
out­
put
per
stackday
(gross
tons)

240.8
158.1
351.7
294.7
227.0
164. 8
208. 3
| 147.3
(3)
(3)
249.4
(3)
95.0
(3)
312.8
168. 0
140.2
(3)

Charging

Casting

Mechanical.
Hand _ _ _
Mechanical.
_____do______
_____d o ............
____ do............
____ d o ...........
H and.............
__ .do______
____ do_______
MechanicalH and__ __
____ do______
____ do_______
Mechanical .
H and_______
____ do______
.........do ............

Sand.
Do.
Machine.
Sand.
Do.
Do.
Do.
Machine.
Sand.
Do.
Do.
Do.
Do.
Do.
Machine.
Sand.
Do.
Do.

1911
16
14
3______
7...........
61
28
5______

22
12
33
48
51
46
34
42

10
73
31
39
52
54
62

...

100-125
25- 50
150-175
125-150
50- 75
75-100
150-175
25- 50
75-100
50- 75
50- 75
75-100
25- 50
50- 75
50- 75
9125-150
25- 50
50- 75
50- 75
50- 75
25- 50
Under 25

0.9
.5

1.0
1 .2
1. 0
.6
1.3
.4
.9

1.0
.7

1.0
.5
(3)
(3)

1.0
1.0
1.0

.7

1.0
.7
(3)

0)
0)
0)

0. 440
(])
0)
0)
.522

(0

.218
.249
0)
. 223
0)
0)
0)
0)
.379
0)
0)
.115
0)

0. 267
0)
0)
0)
.215
0)
.464
.362
0)
.334
(i)
0)
0)
0)
.148
0)
0)
.167
0)

i Detail not available.




0)
0)
0)

0.313
. 182
. 182
. 166
. 164
.163
.158
. 152
.150
. 148
.148
. 136
. 134
. 131
. 124
. 119
.107
. 106
.095
.090
.068
.051

0)
0)
0)

2 . 272
0)
0)
0)
1. 915

(0

4. 597
4.012
0)
4. 479
0)

(0
0)
(0

2. 639
0)
0)
8. 673
0)

0)
0)
0)

3. 750

(0
0)

4. 647
0)
2. 153
2. 761

(0

2. 992
0)
0)
0)
0)
6. 753
0)
0)
5. 976
0)

3. 200 385.0 Mechanical. !
5. 483 ! 289.0 H and_______
5. 4S3 417.5
Mechanical.
6. 023 318.5 ____ do_______ j
6. 105 169.0 H a n d . . ___
6. 136 360.2 ____ do_______
6. 330 341.8 M echanical.
6. 562 337.0 ____ do_______
6. 667 249.3 ____ d o ...........
6. 750 198.0 ____ do_______
6. 773 258. 0 H and_______
7. 335 215. 7 M echanical.
7. 471 281.1 ____ do_______
7. 659
H a n d .. __
(3)
8. 066
____ do_______
(3)
8. 382 374.2 Mechanical.
9. 385
98.0 H and_______
9. 392 158.1
Mechanical .
10.535 249.8 H and_______
11.12 2 168.1 ____ do_______
14. 648 136.1 .........d o ............
19. 529
____ do_______
(3)

• Not reported.

• Fiscal year.

Machine.
Sand.
Machine.
Do.
Sand.
Do.
Machine.
Do.
Sand.
Do.
Do.
Do.
Do.
Do.
Do.
Machine.
Sand.
Do.
Do.
Do.
Do.
Do.

A P P E N D IX 2 .— IN D IV ID U A L P L A N T S T U D IE S IN E A R L Y Y E A R S

Data in Table C represent long histories for six selected plants.
They bring out the character of certain changes in the industry
prior to 1911. The items in the table are not complete but all
available material has been tabulated.
Output per stack day for plant No. 28 represents the spectacular
progress of 60 years. With the exception of 1880, operating data
a,nd man-hours for this plant are not available for years prior to 1902.
Daily furnace output is shown by blast periods (i. e., the interval
between blowing in and blowing out for rebuilding or relining) prior
to 1902. Productivity in 1880 is particularly interesting in con­
trast with 1911 when examined in connection with output per stack
day. Productivity doubled while furnace output increased eight­
fold during this period; it is therefore evident that crews were very
small during these early years of small scale operation, while it is
quite likely that productivity may have actually decreased during
some of the intermediate years as production increased without
mechanical aids in handling materials.
A remarkably complete operating record is shown for plant No.
29 over a long term of years. It will be noted that no man-hours
are available prior to 1907; it will be profitable therefore to examine
this plant’s history in relation to that of plant 28, which includes
man-hours for an early year without a continuous operating record.
Increasing output per day since 1880 runs closely parallel in both
cases. The man-hours for plant No. 28 may be regarded as typical of
conditions in both plants, since they were operated along similar
lines and were located in the same district where labor conditions
were analagous. Likewise, the operating record of plant No. 29
may be taken as representative of plant No. 28 during this early
period. Steady progress in daily output and in coke consumption
are the two outstanding features of early operating records. The
primary cause of increased output is seen in the frequency of relin­
ing and rebuilding. This plant began in 1915 to dispose of product
as hot metal.
Plant No. 16 is of interest as one of the first merchant furnace
plants to install a pig casting machine. The marked reduction in
man-hours per ton between 1897 and 1903 is explained by the elimina­
tion of sand casting, and the sudden decrease in hours in 1910 was
due directly to the introduction of mechanical filling and the dis­
placement of top and bottom fillers. Except as a direct result of
these labor-saving changes, this plant shows no improvement in
productivity comparable with the increase in daily furnace output.
It seems that an increase in production was usually paralleled by
larger pay rolls, an unusual condition in blast furnace operation.
116




APPENDIX 2.— INDIVIDUAL PLANT STUDIES

117

The first skip hoist in its district was installed by plant No. 51, but
there was no important effect on productivity since the skips were
hand filled and the only men displaced were the top fillers. The
installation of bins and larry car in 1909 illustrates the usual drastic
reduction of crews which accompanies the modernization of the
stockhouse side of the furnace. This small furnace produces a
special grade of pig iron, and no efforts have been made to push
its daily production to high levels.
Data on early history are also shown for plants Nos. 6 and 7. It
is of interest to compare the 1905 productivity record of these two
plants and plant No. 51.




T a b l e C .— Labor productivity, output per stack-day , consumption of materials charged, and changes in equipment in six merchant blast-furnace

plants reporting for earlier years
PLANT NO. 28

1926...........................
1925..........................
1924_______ _____
1923______________
1922___________
1921______________
1920.........................
1919______________
....................
1918

.5
.7
.5
.5

.8
.6

%7
i!o
.9
.7
.5
.7

0. 672
0)
0)

(0

.642
.655
.443
. 456
.309
.456
0)
0)
(1)

Total
labor

0.326
.321
.278
.241
.239
.234
. 199

.200
.150
.178
(!)
0)

(0

Fur­
nace
crew
labor

1.585
0)
0)
0)
2. 625
2. 741
2. 769
2. 813
3.439
3. 431
0)
0)
0)
0)
0)
0)

All
other
labor

Total
labor

(0
0)
(0
(0
0)

3.072
3.117
3.601
4.150
4.183
4. 267
5.028
5.007
6. 670
5. 625
0)
0)
0)
6. 501
5. 830
6.136

1.488
0)

(0
(0

1. 558
1. 526
2 . 260
2.193
3.231
2.195
0)

(0

(0
0)
0)

. 152
.172
.163

0)

«

0)

0)

(0

0)

0)

0)

0)

0)

0)

(1)

0)

0)

(0
0)

0)
(0
0)
0)

0)
0)
0)
0)

0)
0)
0)
0)

0)
0)
0)
0)

0)
0)
0)

0)
(0
0)
0)

.6
.6

•

0.631
0)
0)
0)
.381
.365
.361
.355
.291
.291
0)
0)
(!)
0)
0)

All
other
labor

(*)
0)

(!)

Aver­
age
out­
put
per
stack- Iron ore
day

Remarks
Scrap

Flux

Coke

Gross
Pounds Pounds Pounds
tons
1,985
421
3,768
454.4
419
2,092
3. 734
441.5
390
2,053
3,703
444.4
2,253
401
3,683
402.4
426
2,138
416.0
3,588
444
2,251
398.5
3,658
430
2,283
394.4
3,732
2,220
421
3,772
396.7
450
2,489
3.904
324.5
444
2,439
3,801
318.3
439
2,345
3,736
358.3
421
2,209
393.8
3, 721
553
2,129
857.0
3,532
319.6
0)
0)
0)
336
2,233
359.7
3, 833
360.2
0)
0)
(0
f 2,376
2,324
\ 2,406
330.0
0)
0)
2,444
I 2,349
f 2,307
I 2,162
292.0
0)
0)
1 2,389
I 2 ,2 1 1
272.0
0)
0)
0)
168.0
0)
0)
0)
156.0
0)
0)
0)
124.0
0)
0)
0)

Pounds
1,046
1,066
1,068
1,035

Pig-casting machine installed.
Stack rebuilt.

1,010
1,084
1,138
1,310
1,501
1,478
1,422
1,263
1,257
0)
1,301
0)
• 0)

!
|■ (0

1

>

0)
0)
(0
0)

Do.

FURNACES




0.8
.6

Fur­
nace
crew
labor

Man-hours per gross ton
of pig iron produced

BLAST

1916______________
1915 ____________
1914_______ ______ 1913 .......................
1912.........................
1911...........................
1910........................
1909...........................
1 9 0 8 ........................
1 907 -.-.........- ..........
1906.........- ................
1905..........................
1904...........................
1903...........................
1902...........................
1896-1901 2..............
1892-1896.................
1886-1891................
1885-1886.................

125-150
75-100
75-100
100-125
75-100
50- 75
100-125
75-100
75-100
100—125
125-150
75-100
50- 75
75-100
75-100
75-100
50- 75
100-125
50- 75
100-125
75-100
100-125
75-100
75-100
100-125
425-450
225-250
250-275
50- 75

Gross tons of pig iron
produced per man-hour

PRODUCTIVITY— MERCHANT

Year

Average
full­
Produc­
time
tion in
thousands furnaces
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

50Under
Under
25Under
Under
Under
Under
Under
Under
Under
Under
Under

75
25
25
50
25
25
25
25 l
25 !
25 I
25
25
25

1 N ot reported.

0)
m

0)
0)
0)

0)
0)
0)
0)
0)
0)
0)
0)
0)
0)
0)
0)
0)

0)

i1)

0)
0)
0)
0)
0)
0)
0)
0)
0)
0)
0)

0)
0)

.07-6
0)

(0
0)
0)
0)
0)
0)
0)
0)
0)

0)
0)
0)
0)

(!)
I1)
(!)
0)
0)
0)
0)

(0
0)

(1)
0)
0)
(!)
0)
(*)
0)
0)
0)

(0
0)
(0
w

(!)

99.0
58.0
48.0
47.0
46.0
42.0
34.0
24.0

(0
0)
0)
0)
0)

23.0
25.0
24.0
19.0

0)
(0

13.149
0)
(!)

(0
0)

22.0

0)
(0

3,116
0)
0)

(0
0)
0)
0)
0)
i1)
0)
0)

0)
0)
1,360
(!)
0)
(0
0)
0)
(!)

0)
0)
0)
C1)

0)
0)
3 4,211
0)
0)
0)
0)
0)
0)
0)
(0
0)
0)

0)
0)
1 , 8C
0)
(0
(0
0)
0)
0)
0)
0)
(0
0)

a Data for 1867 to 1901, inclusive, are for blast periods and not for fiscal or calendar years.

First blast with coke only.

* Both coal and coke.

2 .— INDIVIDUAL
PLANT
STUDIES




0)
0)
0)
0)
0)
0)
0)
0)

APPENDIX

1882-1884................
1881-1882................
1879-1880................
1877-1879_________
1876-1877................
1875-1876_________
1874-1875_________
1871-1874_________
1870-1871_________
1869-1870_________
1868-1869_________
1867-1868...........
1867...........................

to

T able

C.— Labor productivity, output per stack-day, consumption of materials charged, and changes in equipment in six merchant blast-furnace
plants reporting for earlier years—Continued

J-1
g

PLANT NO. 29




1.0
1.0

.9

1.0
1.0
.6
.4

.8
.8
.6
1.0
.9

.8
.8
1.0
.9

.8
.7

.6
.7
.9
.9

.8
.6
.8
.8
.8
1.0
.6

0.673
.658
.679
.533
0)
.446
0)
0)
0)
0)
0)

0
0)
0)
0)
0)
0
0)
0)
0)
0)
0
0
0)
0)

(I}

0
0

All
other
labor

0. 665
.650
.671
.526

0

.511

0)
0)
0
0)
0)
0)
0)
0
0
0)
0)
0)
0)
0
0
0)
0)
0)
0
0
0)
0
0

Total
labor

0.334
.327
.337
.265
.249
.240
0)
0)
0)
0)
.260
0)

0

.231
.242
.219
0)
0)
0)
0)
. 181

0
0)
0)
0)
(0
0)
0)

1.486
1.519
1. 473
1.877
0)
2. 245

0
0)
0)
0)
0)
0)
0
0)
0)
0)
0)

0)
0)
0)
0)
0)

0
0)
0
0)
0)
0)
0

1.504
1. 537
1,491
1.899

0

1.928
0)
0)
0)
0)
0)
0)
0)
0)
0)

0
0
0
0
0)
0)
0
0)
0)
0
0)
0
0

2.990
3.056
2.963
3. 776
4. 018
4.173

0
0)
0
0)

3. 846

0
0)
4. 336
4.130
4. 570
0)
0)
0)
0)
5. 517
0)
0
0)
0
0
0)
0

Gross
tons
431.0
426.0
393.0
371.0
340.0
327.0
366.0
356.0
341.0
396.0
366.0
365.0
365.0
368. 0
360.0
347.0
342.0
327.0
262.0
303.0
309.0
351.0
300.0
328.0
313.0
259.0
274.0
273.0
255.0

Scrap

Coke

Flux

Pounds ' Pounds Pounds Pounds
3,893
240
1,033
1,917
4,034
968
287
1,876
184
4,247
979
1,963
1,028
4,283
206
2,075
4,222
1, 219
195
1,855
121
1,252
4,039
2,197
4, 442
45
2,022
1,169
1, 239
4, 476
2, 097
0
4, 572
2,201
1, 250
0
1,084
3,996
1,899
0
0)
0)
0
1,187
4,110
271
1,995
1,292
4, 211
267
2,161
1 , 212
4,133
2,103
213
1,174
4,316
2,282
0)
3,857
1, 271
333
2,186
4,180
1 , 212
103
2,153
4,321
1,416
2 , 212
0
4, 693
1, 505
2,485
0)
1,387
4,444
47
2,328
0
0)
0
0
4, 372
2 ,1 1 2
1,147
0
905
3, 270
2,232
0
4, 236
2,168
1,129
0)
4, 283
1,1
22
2,10
2
0
4,178
36
2,269
1, 272
195
1,084
3,868
0)
4,025
110
1,073
2,135
1,028
3, 620
208
0

54.2
51.9
48.6
49.9
50.7
53.8
49.9
50.1
49.0
56.1
0)
51.6
50.0
51.5
51.9
53.4
53.3
49.8
47.7
49.8
0)
51.2
53.2
53.0
52.3
53.1

0

54.2
55.5

Remarks

0)

93
96
90
97
82
45
77
59
0)

0
0
0)

Stack relined.

Do.
New management.
First disposal of hot metal to ad­
jacent steel plant.

Pig-casting machine installed.
Stack relined.
Pig breaker installed, saving 18
men daily.
New casting house, new Tod
engine.
Electric slag conveyer saves 13 men
daily.
New Tod engine, new boilers.
Furnace enlarged.

FURNACES

75-100
150-175
125-150
125-150
100-125
50- 75
50- 75
100-125
75-100
75-100
125-150
100-125
100-125
100-125
125-150
100-125
75-100
75-100
50- 75
50- 75
100-125
100-125
75-100
50- 75
75-100
50- 75
75-100
75-100
50- 75

Furnace
crew
labor

Iron
ore

Per
Per
cent of
cent of
yield
metal
from
used in
ores
molten
and
condi­
equiv­
tion
alent

BLAST

1927
1926_____
1925_____
1924_____
1923.........
1922.........
1921_____
1920_____
1919_____
1918_____
1917.........
1916_____
1915_____
1914.........
1913.........
1912.........
1911_____
1910.........
1909_____
1908_____
1907_____
1906_____
1905_____
1904_____
1903_____
1902_____
1901_____
1900_____
1899.........

Gross tons of pig iron
produced per man-hour

Aver­
age
Man-hours per gross ton
output
of pig iron produced
per
stackday
All
Furnace
Total
crew
other
labor
labor
labor

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion in
furnaces
thousands
active
of gross
during
tons
year

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

IZfQ

1898.

50- 75

0

1897.

25- 50

0

1896.

50- 75

0

50
50
50
75
50
50
50
50
50
25
50
50
25
25
25

.5

.8

1.0
.6
.7

1.0
1.0
1.0
1.0
1.0
1.0
.3
1.0

0)
0
0
0

0
0
0)
0
0
0
0
0
0
0

0
0
0
0)
0
0
0
0
0)
0
0
0)
0)
0
0
0
0
0)

0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0

217.0

3,564

170

2,148

878

59.8

202.0

3,692

219

2,249

894

57.3

168.0

3,627

204

2,210

860

58.5

151.0
144.0
136.0
143.0
114.0
114.0

3, 537

184
517
468
219
172
251
224

2,311
2,745
2,722
2,603
2,936
2,883
2,699
2,728
0)
0)

894
833
950
974

60.2
60.0
59.0
58.0
58.1
59.2
59.3
60.4

0

112 .0

3,331
3,638
3, 680
3, 501
3,553

95.0
82.0
59.0
75.0
85.0
29.0
28.0
27.0

0
0
0)
0)
0
0
0)
0

0
0
0
0
0
0
0
0)

2 ,1 1 2
0
0
0
0

1 , 021
1,055
1,006
0
0
0
0
0
0
0

0
0
0
0)
0)
0
0

4 First 6 months only.

New bosh, new pumping engine,
etc.
New coke and limestone bins,
chills for casting.
Stack relined; new boilers and new
Tod blowing engine.
New Julian Kennedy stoves.
Stack relined; coal strike.
Plant overhauled, engines rebuilt.
Stack relined.
.

-

Stack rebuilt, new auxiliary equip­
ment.

PLANT
STUDIES




0

0
0)
0
0
0
0
0
(1
)
0
0
0
0
0
0
0
0
0

2 .— INDIVIDUAL

252525502525252525Under
2525Under
Under
Under

0
0
0
0
0
0)
0
0
0
0
0
0
0
0
0
0
0
0

APPENDIX

1895.
0 1894.
1 1893.
I 1892.
g
1891.
1890.
1889.
1888.
CO 1887.
1886.
1885.
1884.
1883
1882.
1881.

0
0
0)
0
0
0
0
0
0
0
0
0
0)
0)
0
0
0
0

fcO

PLANT NO. 16
T a b le

C.— Labor productivity, output per stack-day, consumption of materials charged, and changes in equipment in six merchant blast-furnace
plants reporting for earlier years— Continued

Average
full-time
furnaces
active
during
year

Gross tons of pig iron
produced per man-hour

Furnace j All
crew | other
labor
labor

Total
labor

0.854

0.685

0.380

1924 . ...........
50 - 75
1923..... ............
125-150
1922_________ I
50- 75
1921....... ..........i Under 25.
125-150
1920 _
100-125
1919,
150-175
1918 _
175-200
1917_
100-125
1916_
1915_
125-150
1914125-150
1913125-150
125-150
1912_
100-125
1911125-150
191025- 50
1909-

.3
.7

1.105

.429

.309
.280
.371
.332
.246
.269
.272
.314
.294
.313
.274
.308
.299
.313
.310
.179

1908_
1907190619051904_
19031902_
19011900-

25- 50
75-100
100-125
75-100
50- 75
75-100
50- 75
75-100
50- 75




.2
.1
.9
.6

1.0
1.0
.7

0)

0)
0
0)
0)

0
0
0
0
0)
0
0)
0
0
0
0
0
0
0

.376
.360
.389
.381
.375
.375

.355
.341 ;
.319
.340
.396
.333

0
0

0

0)
0)
0)
0)
0
0

.9

1.0
.5

.5

.8

1.0
.9
.5

0)
0
0)

|

.348

0
0)
0

.905

!
!

1
1
1

!
!
;

.183 1
.175
. 175
. 180
.192
. 176
0)
0)
0)

1.461

2. 632

2. 329

3.233
3.566
2.697
3.016
4.066
3.717
3.672
3.180
3.404
3.197
3. 653
3. 252
3. 340
3. 200
3.226
5. 593

0
0
0
0
0
0
0
0)
0)
0
0
0
(1>

0

0

2.718

2.876

2.658
2. 778
2.572
2.622
2. 670
2.669

2.817
2. 932
3.136
2.941
2. 528
3. 002

0
0)
0

0)

0
0

Flux

Scrap

Remarks

jGross
tons |Pounds Pounds Pounds Pounds
2,282
72
392.3 \ 4,070

0)

i

!
i
;
1
!
1
;
I
j
!

3,913
512.0
493.4 i 3,792
613.0 !
0
513.1
4,084
438.3
3,922
455.7
0
452.3
0
489.5
0
445.9
0)
450.9
3,882
382.4
0
389.0
0
385.3
0)
385.0
0
4,108
381.9
279.3
0

277.2
5.476
5.709 1 285.1
312. 2
5. 708
5.563
310. 4
5.198
309. 0
5.671 ! 296.8
0
! 255. 1
250.4
0
0)
1 232. 5 !

0
0
0)

3,900

0
0
0)
0

3, 709

199
249
0
170
242

0
0

0

0
108

0)

0)

1, 996

2,120
0
2,101

2,092

0
0
0
0
0
0
0

0

2,024

0)

0

2,190

0
0
0

0)
0
0)
0

0

965
1,055

0
0
0
0
1, 064
0
0

0

0)
0)
(0

912
900

0)

0)

874

0

0

8

0

0
0
0

2,064

1, 077

0

8

0
0
0
0

2,144

I, 254

0)

182
166
156
146
162
154
151
142
141
131
127
115
117

3-shift system introduced.

112
112
142
138
148
162
157
146
153

(0
0
0

New skip, larry, and bins
hand filling; furnace rebuilt.

FURNACES

0.7

Iron
ore

Aver­
age
num­
ber
of
men
per
day

BLAST

75-100

1926 _

Aver­
age
Man-hours per gross ton
output
of pig iron produced
per
stackday
All
Furnace
Total
crew
other
labor
labor
labor

PRODUCTIVITY— MERCHANT

Year

Produc­
tion in
thousands
of gross
tons

LABOR

Consumption of materials per
gross ton of pig iron produced

Average labor productivity

1899,...............
50- 75
1898-...............
75-100
25- 50
1897....... .........
1 8 9 6 ---........... Under 25.

.8
1.0
.6
.3

0)
0)
0)
0)

0)
0)
0)
0)

0)
0)

. 131
. 119

0)
0)
0)
0)

0)
1 220.6
241.7
0)
7. 643
215. 9
8.400
189.9

0)
0)
0)
0)

0)
0)
0)

<‘>

0)
0)
0)
0)

0)
0)
0)
0)

0)
0)
0)
0)

0)
0)

Pig-casting machine installed.

150
145

P L A N T N O . 51

1908_
1907__
1906--.
1905__
1904--.

5050505050-

75
75
75
75
75

1903__.
1902__
1901
1900--.
1899._.
1898-_.
1897-_.

25505050255050-

50
75
75
75
50
75
75




0. 504

0. 271

1. 705

1.984

262. 8

3,624

2 , 028

965

117

.564
.437
.366

.344
.294
.171

.214
.176
.117

1. 772
2.289
2. 732

2.900
3. 398
5. 843

4. 672
5. 687
8. 575

248.3
248.1
209.0

3, 804
4,081
4,059

2, 076
2 , 228
2, 295

1,062
1,053
1 , 281

140
170
185

.352
.333

0)

0)

2.837
3.004

0)

0)
0)
0)
0)
0)

2,148
2, 659
2, 715
3,100
4,193

2, 593
2, 586
2,408
2,494
2,475

1, 532
1,478
1, 396
1,420
1, 398

5. 983
0)
0)
0)
0)
0)

195. 9
189.1
223.7
192.6
192.7
207.3
225.5
223.9
201.4
208.3
215.7
210.1
168.4

186
180
161

.1 1 1

0)
10. 758
8.132
9. 798
9. 031
0)
0)
8. 528
9. 817
7. 650
7. 335
8.497
14. 826

0)
0)
0)

0)
0)
0)
0)
0)

12. 654
13. 580
10.439
10. 525
10. 453

180.4
184.7
208.8
208.3
203.2

s 4, 334
«4,140
« 4, 081
« 3, 882

0)
0)
0)

0)
0)
0)
0)
0)
0)
0)

0)
0)
0)
0)
0)
0)
0)

12. 205
10. 985
11. 010
11. 763
12. 672
10. 019
9. 000

96.3
191. 3
164.2
153.7
142.7
174.8
190.8

* 3,868
« 3, 779
5 3, 734
* 3, 792
« 3, 844
« 3, 568
5 3, 692

0)

.7

1.0
1.0
1.0
1.0
.8
1.0
1.0
1.0
.7

1.0
.9

1.0
.6
.9

1.0

.9
.7

1.0
1.0

0)

0)

0)
0)
0)

.129

.093
. 123
.102

0)
0)

(0

0)

0)

0)
0)

.117
. 102
.131
.136
.118
.067

8

0)
0)
0)
0)
0)

.079
.074
.096
.095
.096

.393

0)
0)

0)
0)
0)
0)
0)
0)
0)
0)

0)

0)
0)

.167

0)
0)

0)
0)
0)

0)
0)
0)
0)

.091
.091
.085
.079
.100

.111

0)

8

0)
0)

2 . 546
0)

0)

0)
0)
0)
0)

0)

7. 754
0)
0)

0)

0)
0)

* First 6 months only.

0)

0)

4,169
3,998
3, 349
« 4, 229
5 4,162
«4, 061

1,980
1,680
1, 559
1,046

0)
0)

0)

0)
92
103
692

0)
0)
0)

0)

0)

0)
0)

0)
0)

0)

0)

0)

0)

0)
0)
0)
0)

Stack relined.
Abnormal labor conditions.
Stack relined.

169
175
141
140
158

2,426
2,433
2, 342
2,357
2,218
2,324

1,434
1,519
1,443
1, 373
1,429
1,499

2, 734
2,442
1,914
2, 364
2, 274

1, 516
1, 393
1,391
1, 243
1, 223

202

2, 230
2, 236
2,316
2, 502
2,246
2, 340
2,164

1, 210

212
186
160
160
160
155
152

1,129
1,163
965
1, 205
1,136
1, 075

Pig-casting machine installed.

8-hour day introduced.

221

Larry car, bins, and cast-house crane
installed.
Stack rebuilding at end of 1908.

222

193
194
Slack times required much piling of
iron and inflated yard gangs.
Stack relined; new boilers installed.

Skip hoist and new engines installed.

STUDIES

U nder 25.
50- 75
50- 75
50- 75
50- 75
75-100
75-100
75-100
50- 75
75-100
75-100
75-100
25-100

0. 587

.5
.4
.7

PLANT

1921__
1920--.
1919-_.
1918__.
1917--.
1916--.
1915__
1914._
1913
1912...
19111910-_
1909-

0.9

2.— INDIVIDUAL

1925.
1924,
1923-_.

25- 50
25- 50
50- 75

APPENDIX

1927 4_.

» A n y scrap inseparably combined with ore.

to
OO

124

PLANT NO. 6
T a b le

C

— Labor 'productivity, output per stack-day, consumption of materials charged, and changes in equipment in six merchant blast-furnace
plants reporting for earlier years— Continued

* Not reported.




2.0
L8
2 .2
2.0
2.5
1.4

1.0
2.6
2.5

2.8
2.3
2.9
2.9

2.0
2.5
2. 7
2.3
2.7
2.3

2.0
2.7
2.7
3.0

0.8
2.7

2.8
1.5

1 . 216
1.006
.924

(9
0)
(9
0)

.597
.556
.444
.469
.529
. 549
.498
.436

(9
(9
(9
(9
(9
(9
0)

.243

0)

(9
(9
0)

All
other
labor

0. 610
.393
.475

(9
C1)
(9
0)

.288
.218
.209
.204
.255
.271

.20 1
.239
(l)
(l)
0)

(9
0)
(9
(9

.165

0)

(9
(9
(9

Total
labor

0. 406
.283
.314
.251
.248
.241
. 143
.194
. 157
. 142
. 142
. 172
.181
. 143
. 154
0)

(9
(9
(9
(9
(9
(9

.098

(9
(9
0)

0)

Furnace
crew
labor

• 0.822
.994
1.082

0)
(9
(9
(9

1. 675
1. 799
2. 251
2.134
1.891
1 . 822
2.009
2.291

(9
(9
(9

0)
0)
0)
0)

4.111
0)

(9

0)
0)

4 First 6 months only.

All
other
labor

1.640
2. 543
2.104

0)
0)
(9
0)
3. 472
4. 579
4.773
4. 905
3. 927
3. 693
4. 985
4.192
0)
0)
0)

(9

0)
0)
0)
6. 059

(9

0)
0)
0)

Aver­
age
output
per
stack
day

ore

Scrap

Coke

Flux

Total
labor

2.463
3. 536
3.187
3. 982
4. 033
4. 155
7. 002
5.147
6.379
7. 023
7. 039
5. 818
5. 514
6.994
6.484

(9
(9
(9

0)
0)
(0
0)

10.170
0)
0)

(9

0)

Gross
Pou nds P ou nds P ou nds Pou nds
tons
408. 5
(9
(9
(9
(9
23
1,952
860
3, 943
359.1
29
2,071
4, 086
896
341.7
2 , 268
4, 368
76
1,051
317.2
58
2, 244
1,004
4, 325
325.4
44
2, 234
4,173
1,039
322.5
2,181
1 , 021
4,267
36
312.6
30
2, 367
4, 341
1,089
319.8
101
2 ,499
1,077
4, 359
279.6
2, 619
1,10 0
26
4, 384
253.4
29
2, 393
1,039
4, 274
261.6
11
934
4,097
285.2
0)
2,140
285.2
(9
(9
0)
2,120
8
862
4,191
286.8
2,243
1,024
4, 213
47
270.2
2,261
1,163
4,343
273.5
2,215
1,095
4,252
29
290.7
2,182
1,004
9
4,338
277.6
38
2,114
4, 321
267.3
?}
4
4,285
216.4
(9
1
128
4,119
214.4
0)
4, 314
67
200.5
(9
0)
2,402
1,037
13
4,220
202.7
251.4
0)
0)
(9
0)
151.4
(9
0)
0)
0)
176.0
(9
(9
0)
0)
170.5
(9
0)
(9
0)
• Fiscal year M a y 1 to Apr. 30.

Average
cubic
feet of
air
blown
per
minute

30, 629
31, 903
31, 469
33,040
33, 986
36, 284
29, 432

(9

28, 937
29, 472
29, 593
28, 219
28, 215
29, 403
30, 910
31, 376
32, 695

(9
(9
(9
(9
(9
(9
(9
(9
(9
(9

Average
number
of men
per day

Remarks

241
240
283
278
300
168
188
388
401
441
389

(9

405
366
390

(9
(9
(9
(9
(9
(9
(9
540
(9
(9
(9
(9

7 Jan. 1 to Apr. 30 only.

FURNACES

125-150
225-250
275-300
225-250
300-325
150-175
100-125
300-325
250-275
250-275
200-225
75-100
275-300
200-225
225-250
250-275
225-250
250-275
225-250
150-175
200-225
175-200
200-225
75-100
125-150
175-200
75-100

Furnace
crew
labor

Man-hours per gross ton
of pig iron produced

BLAST

1927 *....................
1026.....................
1925.......................
1 924 ....................
1923.......................
1922.......................
1921....................
1920 ®_..................
1919 ® ..................
1918 «___...............
1 9 1 7 .................
1916 7-___.............
1915__...................
1 9 1 4 .....................
1913____________
1912
1911...................
1910.......................
1909......................
1908.......................
1907.......................
1906____________
1905____________
1904 .....................
1903.......................
1902.......................
1901.......................

Gross tons of pig iron
produced per man-hour

PRODUCTIVITY— MERCHANT

Year

Average
Produc­
full-time
tion in
furnaces
thousands
active
of gross
during
tons
year

LABOB

Consumption of material per
gross ton of pig iron produced

Average labor productivity

P L A N T NO. 7
T a b i jE C — Labor 'productivity, output per stack-day, consumption of materials charged, and changes in equipment in six merchant blast-furnace
plants reporting fo r earlier years— Continued

Year

Produc­
tion in
thousands
of gross
tons

Average
full-time
furnaces
active
during
year

Gross tons of pig iron
produced per man-hour

All
other
labor

Total
labor

Furnace
crew
labor

All
other
labor

Iron
ore

Scrap

Coke

Flux

Total
labor

Average
cubic
feet of
air
blown
per
minute

Remarks

2 .— INDIVIDUAL

Furnace
crew
labor

Aver­
age
output
per
stackday

Man-hours per gross ton
of pig iron produced

APPENDIX

Consumption of material per
gross ton of pig iron produced

Average labor productivity

!




50- 75
50- 75
50- 75
75-100
75-100
50- 75

1.9

2.0
1.9

1.8
1 .2
.2
1.8
1.6
2.0
2.0
1.8
2.0

1.4
1.7

1.8
1 .2
1.4

.8
.7
.9

1.0
.9
.9

0.848
.816
0)
0)

0.515
.424

0

0
0
0

0)
0)
0)
0

0
0
0
0

0
0

0
0
0

. 736

.616
0)
.523
.544
.440
0)

.308

.227

0
0
0
.201

1.179
1.226

0
0
0

1,359

0
0
0
0

1. 624

0
0
0

0

0

1,914
1. 837
2. 272
0)

0
0
0
0

0
0
0
0

0
0)
0
0

. 104

0
0)
0
0

4. 297

0)

<*>

0

(1)

.232

.326
.332
.267

0.321
.279
.270
.250
.231
.217
. 155
.151
. 128
.153
.166

.189

1 N ot reported.

.206
.166

1.940
2. 358

0
0
0

3.249

0
0
0
0

4.405

0
0
0

3. 067
3. 016
3. 750

0
0
0)
0
0

5. 300

0

Gross
tons
Pounds Pounds Pounds Pounds
3.119
410.0
0
0
0
\ 0)
392. 8
3. 584
3,618
372 1 .2,042
993
363.1
3. 703
3, 774
237 | 2,146
1, 111
3. 999
375.5
3, 718
262 1 2,088
999
346.8
4.322
4, 234
45
2,209
1,030
4. 607
350.3
103 [ 2,148
4,231
1,030
6.444 ! 375.5
22
2,050
1,131
4, 390
6. 633
317.0
4, 451
22
2,407
1, 239
7. 793
304. 3
0
0)
0
0
6. 554
297.9
0
0
0
0
6. 029 1 314.0
0)
0
0)
0
j 331.5
0
0)
0)
0
! 328.7
0
0
1 0
0
0
306.2
0
0
0
0
0
4.981
291.5
0
0
0
O
4. 853
289.5
0)
0
0
0
6. 023
318.5
0
0
0)
0
261.5
0
0
0
0
0)

0
0
0)
0

9. 597

246.9
261.4
236.5
227.2
235. 5
228. 2

0
0
0)
0
0
0

0
0
0
0
0
0

0
0
0
0
0)
0

First 6 months only.

0
0)
0
0
0
0

35,
34,
34,
35,
35,

514
747
379
037
387

(0
0
0)
0
0
0
0
0
0
0
0
0
0
0
0
0
0
( 1)
0

Relined.
Do.

Do.

One stack rebuilt.
Pig machine installed.
Stack rebuilt.
Pig machine installed;
stack built.

“B”

STUDIES

1909................... ............
1908......... ..................
1907.......... ....................
1 9 0 6 .............................
1905........................... ..
1904......................... ..

2.0

PLANT

19274................. ............
125-150
1926_________________
250-275
1925_________________
250-275
1924........... ............. ..
250-275
1923_________________
225-250
1922_________________
150-175
1921_________________ Under 25
1920_________________
200-225
1919_________________
175-200
1918_________________
200-225
1917............... ................
225-250
1916_________________
200-225
225-250
1915._____ ___________
1914_________________
150-175
1913_________________
175-200
1912_________________
175-200
1911............... ................
125-150
1910.......... ....................
125-150

fcO

Oi

APPENDIX 3.— REPRESENTATIVE FORCE
ANALYZED AND COMPARED

REPORTS

In an effort to keep the number of men employed at a minimum,
the management in most blast furnace plants makes a daily record
of the number of men actually working, by labor groups and occupa­
tions. These daily records are frequently recapitulated on a weekly
or monthly basis. From these records it is easy to determine the
minimum number of men with which the plant can be efficiently
operated, and the effort is being made continually to reduce this
minimum. On the basis of the experience thus recorded a standard
or “ bogie” is constructed for each department. This standard then
becomes an upper limit, each foreman being strictly limited to his
quota except in special situations. This standard of course is not a
fixed one, but is reduced from time to time as fewer and fewer workers
are able to operate the plant.
The relationship between the standard force and the number of
men actually employed from day to day differs between plants in
accordance with the way the standard is applied, and the care and
frequency with which it is revised. A standard to which foremen
must rigidly conform can not too closely approximate the minimum
daily force without danger of hampering operations. On the other
hand, the standard may be a guide to best practice— a goal to be
attained. This second type of standard is frequently exceeded by
the actual daily force, and can not be strictly compared with the
former type.
Modern blast furnace plants are essentially similar, and the same
basic processes must be performed, although the auxiliary equipment
and the division of labor by occupations differs widely. All blast
furnace force reports will necessarily include certain essential labor
groups, but there is a marked lack of uniformity in the wTav indi­
vidual occupations are classified in different force reports. For ex­
ample, the blowing engineers and helpers are sometimes listed with
the power-house crew and sometimes with the cast house.
The force reports presented in this appendix include only those
labor groups and occupations which have actually been used in con­
structing the man-hours for productivity purposes. That part of
the report which covers the office force, a nodulizing plant, sintering
plant, or other auxiliary operation not included as part of the blast
furnace plant proper has been omitted. Thus these reports give an
excellent idea of the labor winch has been included in measuring
productivity in a few typical plants.
Force report No. 1 is for one-furnace operation in a two-furnace
northern inland plant. The force report is presented exactly as it
is kept by the company with one minor exception. All plants do
not use the same terminology in their force reports, and it is not
unusual to find identical groups or occupations called by different
names. In order to facilitate comparison between the various force
reports and to make them more easily understood, explanatory terms
have been inserted in parentheses at various points. For example,
this plant uses the term “ trestle” to cover what is ordinarily known
126




APPENDIX 3.— REPRESENTATIVE FORCE REPORTS

127

as “ stocking” ; some plants use the term “ material delivery” to
co^er the same operation. By using a uniform word “ stocking” in
all such cases, the essential similarity of the operation in different
plants is emphasized. Some plants, for instance, have an occupa­
tion called “ trestlemen,” which applies only to those who work on
top of the trestle and does not include men or machines engaged in
delivering materials. However, in force report No. 1 the term “ tres­
tlemen” includes both those engaged in the delivery of ore from the
stock piles and those dumping materials into the bins.
In the first place, the men in the crew are divided into two genera!
groups: Direct blast furnace labor and indirect blast furnace labor.
The former includes all men employed permanently and regularly
around the stack itself; the latter includes all the auxiliary labor
which is necessary to the operation of the plant.
The first process in the operation of a blast furnace is the unloading
of the materials— ore, scrap, coke, and limestone—in the yard. But
this is ordinarily done by the unloading or yard gangs and is con­
sidered as indirect labor. In the most modern plants this unloading
would usually be done by means of a car dumper in an inland plant or
by a Hulett unloader in a lakeside plant. The materials as thus
delivered must then be removed either to the bins for immediate
use or to the stockpiles for storage until needed. Smaller plants will
usually perform these operations by means of locomotive cranes
and the yard railway; this particular plant uses an ore bridge to take
care of the ore. This machine can perform both operations at once—
it removes the ore from the dump to the stockpiles and can at the
same time keep the bins supplied. The saving of labor which this
makes possible is apparent. The coke, however, is delivered on the
trestle in railroad cars, and the four unloaders listed in the force report
are responsible for unloading these cars into the coke bins. These
men also look after the ore and limestone bins in so far as these need
attention.
The next step in the process takes place underneath the bins. By
means of a lever the operator of the larry car opens the bins from
below and allows the ore, coke, or stone to fall into the car, which is a
small, electrically driven dump car and is usually equipped with a
weighing device. The larryman runs the loaded car over to the skip,
where he dumps the load into the skip bucket, in which it is carried
to the top of the stack and dropped in. The man who operates the
skip is known as a skip operator, skip engineer, or hoisting engineer.
The larrymen, larrymen’s helpers, and skipmen are usually termed
the charging labor.
In the cast house are included all the men engaged in operating
both the stack itself, the stoves, and the gas washer. These men
take care of the blowing, the water-cooilng system, the slag removal,
the casting, the clean-up, etc.
The blowing engineers and oilers have charge of the blowing
engines which furnish the blast for the stack. In some plants these
men are classed with the power-house crew, in others (as in this one)
with the blast furnace direct labor. The dry blast is very rare in the
merchant industry to-day and the dry-blast operators will not be
found in any other force report.
The pig-machine crew consists of the men who cast the hot metal.
This requires four men to a shift— a foreman, a craneman who pours
the hot metal from the ladle into the molds of the machine, a trough



128

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

man who manages the water-cooling system at the top of the machine
and loosens the pigs so that they will drop out into the car below,
and a lime mixer who fixes the lime bath through which the molds
pass on their way back to the ladle.
In this plant there are a number of full-time mechanical men
attached to the blast furnace proper. These include a millwright,
a motor inspector, and two molders. In other plants these men might
be listed with the mechanical gang and not with the furnace crew.
Since this is a 2-furnace plant the indirect labor is exceptionally
large for 1-furnace operation. The boilers, yard railway, and
mechanical crew carry approximately as many men as they would
for two furnaces; it is only in the cranes, general labor, and track
labor that any great saving in men can be obtained while one furnace
is down. A 1-furnace plant would not require nearly as much
overhead labor as is listed here.
The departments and occupations are mostly self-explanatory, and
there is no necessity for going into details. The plant is on an 8-hour
basis.
R e p o r t N o . 1 .— Number of men normally employed in a northern, inland,
two stack blast-furnace plant, during one-furnace operation in 1927, by labor
groups and occupations

F orce

Labor group and occupation

BLAST FURNACE DIRECT LABOR

Trestles (stocking):
Ore bridge operators................. .......
Trestle foreman.................................
Unloaders........ ....................................
Stock house (charging):
Skip engineers....... ............................
Larry car operators...........................
Cast house:
Blowers_______ _____ _______ ______
Keepers___________________________
Keepers, first helpers.......................
Cinder snappers................................
Stove m en.................................... .......
Stove cleaners.....................................
Scrap men............................................
Clay men....... ....................... ........... ..
B arm en ................................ ..............
Gas cleaner and flue-dust m en. . .
Stove foremen____________________
Water tenders._______ ___________
Blowing engines and dry blast:
Blowing engineers.............................
Blowing oilers.....................................
D ry blast engineers..........................
D ry blast oilers..................................
Pig machine:
Foremen...............................................
Cranemen............................................
Line mixers.......... ..............................
Trough men.........................................
Mechanical: Millwrights.......................
Electrical: Motor inspectors.................
Foundry:
Molders.................................................
Molders, helpers.............................. .
Slag: D um p m en........... ................... .......
Supervisory: Superintendents_______
BLAST FURNACE INDIRECT LABOR

Water department: Pumpmen______
Steam department:
Foremen.......................... .....................
Water tenders.......................... ...........
Firemen................................................
Ash wheelers.......................................
Boiler washers and helpers............




Number
of men
employed

Number
of men
employed

Labor group and occupation

BLAST FURNACE INDIRECT LABOR—

COn,

Electric light and powder:
Foremen....................... ................. ........
Electricians____________ _________ _
Electricians’ helpers........................... .
Engineers____ _____________________ _
Oilers______________ _________ ______ _
Yard switching:
Weighmaster_______________________
Locomotive engineers______________
Locomotive firemen_____ __________
Locomotive brakemen........... ........... .
Locomotive cranes:
Locomotive brakemen......... .............
Locomotive crane firemen_________
Mechanical shop:
Master mechanics and assistants
Machinist........ ........................... ............
Pipe fitter................................... ............
Blacksmiths............. ..................... ........
Blacksmiths’ helpers...........................
Carpenters____________ _____________
Riggers......... ....................... ...................
Riggers’ helpers........................ ...........
Painters_______ ______ ________ _____
Boiler m akers..____________________
M asons__________ _____ _____________
Masons’ helpers____________________
Handymen..............................................
Machinists’ helpers________________
Autotrucks and auto department:
Stablemen_________ _____ ___________
Teamsters__________________________
Cart drivers................. ................. ........
Chemical laboratory:
Chemists and assistants___________
Sampler____________________________
General labor:
General foremen___________________
Foreman___________________________
Assistant foremen______________ _
Laborers...... ............. ......... ................. ..
Track labor:
Foremen..................................................
Laborers................................ .................

1
1

1
2

1
1
1
1

10

1

6

129

APPENDIX 3.-— REPRESENTATIVE FORCE REPORTS

Force report No. 2 is for a single-furnace inland northern plant.
This furnace is very efficiently operated and the crew represents
practically a minimum for plants of this type. Some of the labor
saving is due to a very scientific arrangement of plant equipment;
the rest is due to continuous efforts to cut down the crew, abolish
jobs, and expand the duties of each position. The smallness of the
crew is especially apparent in certain labor groups. For example,
all delivery of materials to the bins is done by means of the ore
bridge; there is no trestle or high line. Thus, two men take care of
all this operation. The pig machine is run with 7 men instead of the
usual 12; the boilers are tended by only 5 men instead of the normal
10 to 15; the mechanical crew is cut to the barest minimum with
which it would be possible to operate; the single locomotive crane
does such switching as may be necessary around the plant; there is
no plant railway.
The success of this plant at saving labor is quite remarkable, but
it must be emphasized once more that every blast-furnace plant has
its own little peculiarities which distinguish it from every other.
Some of the labor saving which has been accomplished at this plant
was made possible by the extremely convenient arrangement of plant
layout; therefore, it would not be possible for some other plants,
even at best, to equal the labor performance of this one. The force
report, however, is interesting in that it does show what is actually
being done in a blast-furnace plant toward reducing the labor force to
the very minimum. Except as indicated to the contrary the plant is
on an 8-hour basis.
F o r c e R e p o r t N o . 2 .— Num ber o f men normally em ployed in a northern, inland ,

one stack blast-furnace plant in 1927, by labor groups and occupations

Labor group and occupation

Ore bridge:
Operators
________
Foremen (10 h o u rs)________________
Stock house:
Larrymen
__________
Larry helpers _ ____________________
Skip operators
- ______
Cast house:
Blowers
_________ _________
K eepers_______________ ________ _____
Keepers’ helpers _ _ _
.
______
Water tenders
__ __
Cast-house labor (10hours)................
Pig machine:
Foremen........ ..... ........... ......... .................
Helpers______________________________
Cranemen
Slag pit:
Shovel men (10 hours) .
...........
Car droppers (10 hours)
__ »
Boilers:
Water tenders_______________________
Firemen (10 hours)___________ _____
Blowing engines:
Engineers_____________ _______________
Oilers________________________________

Number
of men
employed

1
1
3
3
3
3
3
3
3
5
3
3

1
2
2

Labor group and occupation

Mechanical:
General mechanics............ .....................
Mechanics...................... ...........................
Millwrights_________________ ________
Blacksmiths ______________ ________ _
Blacksmith helpers ..............................
Machinists.......... ....................... ............ ..
Chief engineers.......................................
Master mechanics..................... ...........
Electrical:
Electricians........ ............. .........................
Electrician helpers..................................
Locomotive cranes:
Locomotive cranemen............................
Locomotive firemen (8M> hours)........
Miscellaneous:
L a boratory.-................................ ..........
Filter house........................ .....................
Chief chemists..........................................
Storeroom men...................................... ..
General labor_________ ______ ______

N umber
of men
employed

1
2
3

1
1
1
1
1
3

1
1
1
3

1
1
1
12

3

2
3
3

Force report No. 3 shows the situation in a plant before and after
the installation of a coke plant. It makes clear the extent of the
saving in labor which is possible under the joint operation of a coke
plant with a blast furnace. The report for 1925 shows the composition



130

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

of the force as it was before the coke plant was built; the report for
1927 shows the reorganization necessitated by the operation of the
coke plant. The report for the latter year lists the full number of
men in each labor group, but the percentages in the next column
indicate the amount of each group which is charged against the blast
furnace. Therefore, while most of the indirect labor groups have
increased in number, only a part of the group is now chargeable against
the blast furnace. Thus the saving in labor under joint operation,
as has already been stated, is largely in the indirect labor groups,
while the furnace crew remains practically unchanged, as would be
expected.
The substitution of the ore bridge and the transfer-car man for the
trestlemen is, of course, entirely independent of the coke plant installa­
tion; it just happened that this change in method was made at about
the same time. The apparent change in the laboratory crew is mostly
a matter of reclassification. While three samplers and three castmen
were added to the laboratory force after the coke plant started
operation, at the same time in the salary group the assistant chem­
ists were reduced from three to one. Considering that at present
only 50 per cent of the laboratory labor is charged against the blast
furnace, the net change in this group amounted to an increase of only
one-half a man per day. The plant is on an 8-hour basis except in
one occupation.
R e p o r t N o . 3 . — Number of men normally employed in a northern, inland,
one stack blast-furnace plant, before arkf. after the installation of a coke plant, by
labor groups and occupations with the percentage of labor time chargeable to the
blast-furnace department under joint operation with the coke plant in 1927

F orce

Number of
men em­
ployed

Labor group and occupation

Ore bridge_____. ___________
Bridge operators________
Trestle_______________________
Trestlemen.........................
Transfer carmen...............
Stackhouse____ - ..................
Hoist engineers_________
Operators, scale car_____
Laborers, scrap pit _
Cast house._________________
Keepers_________________
Keepers, first helpers___
Keepers, second helpers.
d a y m e n ________________
Laborers, cast house (10
h ours)............ ......... .......
Pig machine_________ ______ _
Repair foremen............... .
Operators_______________
Operator helpers..........
Stoves______________ _______ _
Stove tenders...................
Engine house_______________
Engineers, blowing en­
gines__________________
Oilers, blowing engines..
Chief engineers........ .........
Pump housemen............




In 1925 In .1927
after
before
instal­ instal­
lation lation
of coke of coke
plant plant

2
6

Per
cent of
labor
time
charge­
able to
blast
fur­
nace
de­
part­
ment
in 1927

3
3
3

3
3
3

3
3
3

3
3
3

1

1

2

1

1

1

3
9

3
9

3

3

3
3

3
3

1

1
1

Per
cent of
labor
time
In 1925 In 1927 charge­
after able to
before
Labor group and occupation
instal­ instal­ blast
fur­
lation lation
of coke of coke nace
de­
plant plant
part­
ment
in 1927

Boiler house______ __________
Water tenders...................
Firemen..............................
Ash wheelers....................
Boiler cleaners__________
Mechanical_______ _______ _
100
Repair foremen_________
Repairmen.......... ............. .
Repair helpers...................
Machinists................... ..
100
Blacksm iths.......... ..........
Blacksmith helpers_____
Carpenters______________
Carpenter helpers............
Electrical_______ ___________
Electricians_____________
Electricians’ helpers____
100 j
Pipe department____________
Pipe fitters______________
Pipe fitters’ helpers.........
Locomotive cranes...................
100
_
Engineers______
Firemen.................
100
Conductors. _
Locomotives (switching
Engineers_______________ I
Firemen. _. __________ !
Conductors......... ................ !

100

100
1

Number of
men em­
ployed

60
3
3

1
1
6
2
1
1
1
1

3
3

2 1
3

1

57

3
7

2
1
1
3

1
2

1
1

1

2
1

5
5

4
4
4

35
57

3
3
3

;
3 !__
3
3

88

80

....

131

APPENDIX 3.— REPRESENTATIVE FORCE REPORTS

No. 3 . — Number of men normally employed in a northern, inland,
one stack blast-furnace plant, before and after the installation of a coke plant, by
labor groups and occupations with the percentage of labor time chargeable to the
blast-furnace department under joint operation with the coke plant in 1927 — Con.

F orce R ep ort

Number of
men em­
ployed

Number of
men em­
ployed

Per
cent of
labor
time
charge­
In 1925 In 1927
able to
after
before
blast
Labor group and occupation
instal­ instal­
fur­
lation lation
nace
of coke of coke
de­
plant plant
part­
ment
in 1927

Per
cent of
labor
time
In 1925 In 1927 charge­
after able to
before
Labor group and occupation
blast
instal­ instal­
fur­
lation lation
nace
of coke of coke
de­
plant plant
part­
ment
in 1927

Locomotives (switching)—
Continued.
Brakemen_______________
Yardmaster .
__ __
Assistant yardmaster
Yard labor
Foreman
Cleaning yard
Laborers
Iron yard laborers
Janitor.................. ............. ..
Storeroom
Track labor................................
Foreman.......................... ..
Laborers...................... .......
Laboratory__________________
Assistant chemist_______

Laboratory-Continued.
Samplers________________
Cast men.................... .......
Salaries______________________
Superintendents________
Burden clerks___________
Blowers__________ ___ __
Chief chemists__________
Assistant chemists______
Master mechanics______
Assistant master me­
chanics________________
Chief electricians_______
T,ohr»r
fAromcn
JL/aUUi lUIt5IllCU—
_______
Mechanical engineers
Storeroom
Timekeepers____________

3

3

1

1
1
50

1
26

2

2
19

2
1
1

50

1

1

5

7

1

1

50

3
3
50

1
1

1

3

3

1

1
1
1

3

1

1X

1
1
11

1
1

1
1

•

Force report No. 4 presents a sharp contrast to those previously
discussed. This is a southern two-furnace plant mechanically filled
and sand cast, although a pig breaker is used. Like a number of
other merchant furnace plants it still retains the two-shift, 12-hour
day. This plant is quite typical of southern plants, but it should
not be directly compared with the northern plants previously dis­
cussed which are working the 8-hour day. On all continuous opera­
tions the 8-hour plants would use three men for every two men
employed at this plant; therefore the number of men shown on the
latter force report must be increased to allow for this difference be­
fore any direct comparisons are made.
In fact, it is difficult to compare northern and southern plants
with reference to the labor force because of different conditions
of operation—for example, the handling of materials.
The advantage of the pig machine over the pig breaker as a laborsaving device is shown in comparing the pig machine crew in No. 1
with the iron yard crew (excluding the locomotive cranes) in No. 4.
Of course, this saving in labor does not tell the w^hole story. The
pig machine is a very costly piece of machinery to install and the up­
keep is high, while the pig breaker is a simple hammer, requiring only
a wooden scaffold as auxiliary equipment. Because of the differences
in wages in the two sections, the southern plants find it more profit­
able to use the pig breaker and hire more labor, while the northern
plants find it more economical to cut the labor cost by installing the
pig machine.




132

LABOR PRODUCTIVITY----MERCHANT BLAST FURNACES

R e p o r t N o . 4 . — Num ber o f men norm ally em ployed in a southern two
stack blast-furnace plant during one and two fu rn ace operations in 1927, by labor
groups and occupations

F orce

Labor group and occupation

Stock house (stocking and charg­
ing):
Stock dumpers_______________
Stock dumpers’ helpers______
Manganese pitmen__________
Scrappers___________________ _
Tunnel car m en______________
Scale car men________________
Skipmen_____________________
Cast house:
Foundry m en________________
Keepers_________ •____________
Fallmen (cinder-snappers)___
Scrappers_____________________
Hand sand cutters____________
Sand cutters_______________ . ..
Fifth helpers__________________
d a y m e n ____________ ______ _
Open sand molders............... .
Stove tenders_________________
Stove repairmen_____________ _
Stove repairmen helpers______
Blowing engines:
Chief engineer (10 hours)_____
Chief engineer’s helpers (10
hours)______________________
Blowing engineers......................
Oilers______________ ______ ____
Boilers:
Foremen (10 hours)__________
Assistant foremen (10 hours) _ _
Firemen___________________
Tube blowers (10 hours)___
Water tenders______________
Ashmen (10 hours)_________
Pumpmen______________ . . .
Iron yard:
Locomotive crane engineers
Locomotive crane firemen..
Breakers on platform______
Breakers’ helpers__________
Hookers____________________
Cranemen (overhead)______
Switchmen_____________________
Hostlers____________________
Iron -yard helpers. .............
Loaders____________________
Mechanical:
Machinists (10 hours)______
Machinists’ apprentices____
Machinists, repairmen_____
Machinists helpers_________
Blacksmiths________________
Blacksmiths’ helpers_______
Pipe fitters_________ _______ _
Carpenter foremen............... .
C arpenters............................ .

OneTwofurnace furnace
opera­
opera­
tion
tion

2
1
1
2
2
2
2

2
2
2
4
4
4
4

2
2
2

4
4

2
8

4

4

12

2

4
4

1

1

4

1
1

1
2

1

1

1

1
2
4

1
1
2
!

2
1
l2

12
1

1
1
2
2
2
2
2
i2
i2

2

4

1

2
5

1
1
1
10

2
1
1
20
3

1
23
•35

1

1
23
35
1
2

1

11
1

3

3

Labor group and occupation
i
Mechanical— Continued.
C arpenters’ helpers.....................
Boilermaker foremen...... ...........
Boilermakers___________ ______
Boilermakers’ helpers _____
Boilermakers’ apprentices____
Welders____________ _ _______
Electricians___ ______________
Electricans’ assistant _______
Electrical power:
Operators... ________________
Operators’ helpers......... .............
Repairmen (10hours)................
Masonry:
Brick mason foremen _______
Brick masons (8 hours)_______
Brick masons’ helpers (10
hours) ___________ _________
Switching and stock delivery:
Locomotive engineers_________
Locomotive firemen__________
Switchmen. _ . . . _ _ _
Locomotive crane engineers
(10 hours)_____ _____________
Locomotive crane firemen
(10 hours)___________________
Cinder yard:
Locomotive engineers...... .........
Locomotive firemen___ _______
Pot dumpers___ __________ __
Pot and car oilers (10 hours). . _
Cinder dump:
Dry car cleaner (10 hours)____
Run cutters___ __ ____________
Floating and track gang:
Labor foremen_____________ _
Track foremen. __ __________ _
Trackmen______ ________ . . .
Common laborers______ . . _
General:
Watchmen __ _______________
Stablemen (10 hours)_____ . . .
Supply men (10 hours)_______
Supply men’s helpers______ _
Cartmen_________
___
1
Salaries:
Superintendents______________
Master mechanics____________
Iron yard foremen. __________
C h em ists_________ ______ _____ I
Sample boys______ _______ _ !
Weighmasters________________ !
Timekeepers__________________ ;
Supply clerks . . . __________ . ;
T o t a l....................................... ..

One- j Twofurnace furnace
opera­ opera­
tion
tion

1
1
1
2
1
1
1
1

1
1
1
2
1
1
1
1

2
1
1

2
1
1

1
2

1
2

5

5

2
2

2
2

3

3

1

2

1

2

1
1
2
1

2
2
2
1

1
44

33

2
1
10

2
1
10

1

16

16

2
1
1
1

2

4
1
1
1

2
i
i

2
l
178

224

I

1 1 on 10 hours per day.

2 2 on 10 hours per day.

* 1 on 12 hours per day.

« 2 on 12 hours per day.

Force report No. 5 is drawn up to show" the effect of the 8-hour day
on the blast furnace labor force. This is a northern inland plant
with single-furnace operation. One column shows the number of
men under the old 10 and 12 hour day in 1923; the next column shows
the way the crew was reorganized at the time the change was made;
then the third column shows the way the organization was eventually
developed after four years of experience. A comparison of the force
from period to period is complicated somewhat by the improve­
ments that were introduced in the meantime. The bins were rebuilt




133

APPENDIX 3.— REPRESENTATIVE FORCE REPORTS

and the lage crew of ore fillers eliminated. The method of handling
slag at the stack was improved upon and the cinder ladle men were
cut off, though this saving wTas partly counteracted by the addition of
2 men at the cinder dump. Thus when considering the effect of the
8-hour day the crew of 1927 is not on a comparable basis with that of
1923. However the introduction of the 8-hour day brought the
problem of labor economy more directly to the attention of the
management and probably led indirectly to a large number of the
improvements which were made.
R e p o r t No. 5 . — Number of ?nen normally employed in a northern, inland,
one stack-blast furnace plant during 2 and 3 shift operations in 1923 and 1927,
by labor groups and occupations

F orce

Labor group and
occupation

Stocking furnace bins:
Trestlemen_______ ______
Steam shovel cranemen
and h e lp ers_____ __
Stock house:
Ore fillers.
__ . .
Scale car operators and
helpers________________
Skip operators..................
Cast house:
B low ers___________ _____
K e e p e rs............... .............
Keepers’ helpers......... ..
Stove tenders___________
Clay men. ........................
Scrappers. _______ _ .
Furnace water tenders - .
Filter
operator
and
helper___
. ________
Cinder ladle men
__
Pig machine:
Pig machine operators._
Helpers
_____ . . .
Blowing engines:
Blowing engineers______
Oilers___________________
Steam:
Water tenders.._________
Firemen______ __________
Boiler washers__________
Slag disposal:
Cinder pit labor ________
Cinder dump labor
Mechanical:
Master mechanics and
assistants______
Electricians and helpers.

Twoshift
opera­
tion in
1923

Three- Threeshift
shift
opera­ opera­
tion in tion in
1923
1927

14

14

5

4

18

24

6
2
2
2
6
2
1
3

2
2

6
3
3
3

6
3

1
3
3

M echanical— C ont inued.
Machinists and helpers.
Blacksmiths____________
4
Pipefitters_______________
Riggers and repairers___
__ ___
Carpenters.
Molders and helpers____
6 Switching:
3
Locomotive engineers.
Locomotive firemen____
3
Locomotive switchmen.
3
Hostlers_________________
6 ! Track labor:
3
Track boss______________
1
Track labor........................
Iron yard:
Foremen and weighmasters_______ ________
Locomotive cranemen
1
and helpers___________

11

4

2
6

2
10

12

3
9

2
2

3
3

3
3

2
2

3
3

3

3
3
3

2

3

3

3

L a b o re rs____ ______

2
2

2
2

2
2

Two- Three- Threeshift
shift
shift
opera­ opera­ opera­
tion in tion in tion in
1923
1923
1927

Labor group and
occupation

1
2

._

Miscellaneous:
General laborers________
Unloading and stocking
material_______________
Carters__________________
Cinder crash labor______
Miscellaneous labor.
Management and general
supervisory:
Office___ . . . _____ ______
Chief engineers____
Superintendents...............
General foremen________
Labor foremen................
Laboratory. _______
W atchm en............... .........

2

2

3

3

9
3

9
3

2

2

1
1
2
1

1
1
1

1
2
1
5

2
1
1
2
1

1
6

1

1

7

3

1

1

1

4

3

2
1

1

2

3

5

3

4

6

4

1

3

3

1
1

1
1

1

1

3

3
3

2

2

3

1
1
1

3
3

Force report No. 6 is but a classification of the labor crew into
groups. However, it is shown in sufficient detail to bring out the
changes which took place between 1923 and 1926. The one impor­
tant change was the installation of a skip hoist, which resulted in the
elimination of 10 men on the trestle and 45 men in the stock house.
There was also a pronounced cut in the cast house and stove crews,
but this was independent of the other. The plant in both years was
on a 2-shift, 12-hour basis except as noted. This is a one-furnace
plant located in Pennsylvania.




134

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

F o r c e R e p o r t N o. 6 .—

Number of men normally employed in an eastern Pennsyl­
vania one stack-blast furnace before and after the installation of mechanical filling
equipment, by labor groups

Labor group

Opera­
tion in
1923 be­
fore the
installa­
tion of
skip

Opera­
tion in
1926 aftj er the
jinstallaj tion of
! skip

Labor group

i

Trestle....... ..................... .......................
Stock house............................... ...........
Cast house .................... ............. .......
B lo w ers..___________ _____________
Pig machine_______________________
Boiler room
Stove tenders and cleaners.............

8

14
53

13
4

4

4

General yard (10 hours)
Iron yard (10 hours)
Track repair (10 hours)___________
Mechanical.. ............ ............... . ._
Miscellaneous....... ......... ......... . . .

21

10
0

11

4

11

9
Total........................................ ..

Opera­ Opera­
tion in tion in
1926 aft­ 1923 be­
er the fore the
installa­ installa­
tion of tion of
skip
skip

25

26

3

18
3

108

175

1
8
22

2
2

Force report No. 7 brings out the comparison between the labor
force under a 2-shift, 12-hour system and that under a 3-shift, 8-hour
system in a typical northern plant. This shows the situation in 1923
at the time the change was made. It does not show the ultimate
organization of the crew under the 3-shift system.
F

orce

R

eport

N o . 7 . — Comparison of the labor force under 2-shift operation with
the force used under 3-shift operation, 1923, plant 16

Labor group

Blowing room......................................
Boilers
____________ ___________
Blacksmith shop ________ _______
Casting house . ______
_ ___
Casting machine__________________
Carpenters_________ . ___________ i
Electricians___ _____ __ _ _ ____ 1
Gas washers and D u m p s __________j
Janitor____________________________ !
Laborers___________________________!
Labor foremen____________________ j
Locomotive cranes_______________ !
Locomotive engine _____________ 1
Machinist_________________________ j




Two
shifts

Three
shifts

6

6

9

9

2

2

15
14
3

19
16

2
2

Labor group

1
8

Mason
...
.................. ..
Mechanics
Moulder _ _____ __
Patrolmen... __ __ __
Power h o u se _
Steam shoveL
Stock house
Stock unloading to b in s _.
_
Stove tenders. ____ ______ _____
j Truck driver_____________ . . . . . .
! Track gang___________________ . . .
| Thaw house.................. . .......... _

10
12
2
1
6
2

Total____ _______ ____________

139

2
2
1
6
2
10

1
6
1
10

15

15 !

1

1 1

3

Two
shifts

Three
shifts

1
8

1

1

3

3
3
3
15

2
3

12
3
]

6
2
151

APPENDIX 4.— RELATIVE EFFICIENCY OF A BLAST FURNACE
IN PRODUCING DIFFERENT GRADES OF PIG IRON
A. FOUNDRY VERSUS BASIC

The unit used in measuring blast-furnace output for the purposes
of this study is the gross ton of pig iron. In the calculations it has
been assumed that these tons, as measures of output for produc­
tivity purposes, are for the same article. However, even in successive
casts at the same blast furnace there are minor differences in grade
and quality, and these differences have some slight influence on the
amount of pig iron that the furnace can turn out. Of course, it is
well known that the ferro-alloys are in an altogether different class
from the standard grades of pig iron as far as productivity is concerned.
A blast furnace working on ferro-alloys will not ordinarily turn out
much more than half as much metal as it would if working on standard
basic iron; that is the reason ferro-alloy plants have been excluded
from this study.
However, even within the different grades of standard pig iron
there are minor differences in output efficiency. The following table
shows the comparative efficiency of a blast furnace as between foundry
and basic pig iron, which are the twTo most important grades in the
merchant industry. The table shows the daily output of the stack
for each grade of iron and for two subclasses within each grade. It
is, of course, impossible to maintain identical operating conditions
throughout the year, so it is possible that some of the variations in
daily output are due to outside factors and not to the grade of pig
iron. Nevertheless, the marked difference between daily output of
basic iron and that of foundry iron is noticeable. In 1926 the output
per stack-day of the furnace when working on basic iron exceeded the
daily output when working on foundry iron by 8.5 per cent, in 1927
basic exceeded foundry by 6.7 per cent.
The effect of this on the productivity averages is evident. If this
furnace worked altogether on basic iron instead of about equally on
both, its output per man-hour being increased from 7 to 8 per cent for
every ton of basic substituted for a ton of foundry, the productivity
average for the year would be nearly 4 per cent higher than it was.
However, the reverse would more frequently be the case. Not many
merchant furnaces work exclusively on basic iron, but it is not unusual
to find some of them working practically altogether on foundry. It
is apparent that such a blast furnace has a somewhat depressed
productivity average when it is compared with another furnace which
produces a large proportion of basic iron. When a furnace changes
frequently from one grade of iron to another, its daily performance
suffers still more as a result of irregular operating requirements.




135

136

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES
Output per stack-day of different grades of pig iron in a blast furnace

Output per stack-day
Characteristics

Name

1927

Foundry_____ ________________
High phosphorus..............
Low phosphorus..............
Basic
__ __
Standard..........................
High manganese............

Over 1.75 per cent silicon................ ..................... ........... 1
Over 0.6 per cent phosphorus. _ ._______________
Under 0.6 per cent phosphorus..______________
Under 1.75 per cent silicon....... .................. .........
Under 1.50 per cent managanese_______________
Over 1.50 per cent manganese........... ........... ..........

Gross tons
372
378
366
397
400
396

1926

Gross tons
352
348
356
382
387
378

B. FOUNDRY VERSUS BASIC AND MALLEABLE

A further illustration on this point is shown in the next table
which shows the relative output per stack-day of a particular blast
furnace for foundry iron as contrasted with malleable and basic.
The two latter grades are very close together in output efficiency, so
the daily output figures might be assumed to stand for either of them.
The data cover complete operations for this plant for the period
1921-1926.
.
In the year 1926 the daily output of foundry iron slightly exceeded
that of basic, but this was due to the materials in the charge and may
be disregarded as not occurring under similar operating conditions.
However, in the five years 1921-1925, the daily output of basic iron
exceeded that of foundry iron every year, the excess varying from a
low of 8.2 per Cent in 1923 to 18.5 per cent in 1924. The unweighted
average for the five years is slightly less than 13 per cent. This is
practically twice as great a discrepancy as existed in the blast furnace
previously mentioned; thus it emphasizes still more the loss in
productivity of a furnace working on foundry iron instead of basic.
Average daily product
Year

1926..................................
1925..................................
1924..................................
1923..................................
1922__________ ________
1921..................................

Foundry

Malleable
and basic

Gross tons
433
369
336. 6
328.5
313
300

Gross tons
432
411
398.9
355.3
358
336

P e rce n ta g e b y
which the daily
output of malle­
able and basic
exceeds that of
foundry iron

1 0.2
11.4
18.5

8.2
14.4

12.0

1 Negative percentage—malleable and basic less than foundry.

C. FOUNDRY VERSUS FERROMANGANESE

The last table shows the relative efficiency of a blast furnace on
ferromanganese as compared with foundry iron. One column shows
the average daily output when on foundry iron while another shows
the output of ferromanganese in the same years and the same furnace.
The average daily output of the furnace increased each year and
this increase showed itself in both foundry and ferromanganese
production. In the last column is shown the percentage which the
daily output on ferromanganese is of the daily output on foundry



APPENDIX 4.— RELATIVE EFFICIENCY

137

iron. It is probable that the variations from year to year are due
to the presence of other factors which can not be taken into account.
The variations, however, do not obscure the essential point, which
is that the production of a furnace on ferromanganese is only about
50 per cent of its production on foundry iron.
Average daily product
Year

1 9 1 9 ...............................
1918-................................
191 7 .............................. .

5 4 2 1 °— 2 9 --------10




Foundry
(a)

Ferroman­
ganese (b)

Gross tons
219.6
204.3
187. 2

Gross tons
117.8
94.8
89.7

Percent­
age,
(b) of (a)

53.6
46.4
47.9

APPENDIX 5.— STATISTICS OF MERCHANT BLAST FURNACES
IN RELATION TO THE ENTIRE BLAST-FURNACE INDUSTRY

In order to show the position of the merchant furnaces in relation
to the blast-furnace industry as a whole, and to bring out the propor­
tion of the merchant industry covered by the present study, a classi­
fication of all active blast furnaces is presented in the table below.
This table is based upon data published in the 1916, 1920, and 1926
Iron and Steel Directories 1 and upon the records of the bureau.
In constructing the table the plants have been classified according
to the definitions set forth in the foreword to this study. (See p. III.
All charcoal blast furnaces and all ferro-alloy stacks have been
excluded from the tabulation, in so far as it has been possible to do so.
In case a plant produced both pig iron and ferro-alloys, it was classed
as a ferro-alloy plant if the proportion of ferro-alloy production to
the total tonnage was known to be large. In the case of steel works
plants it was impossible to exclude ferro-alloy stacks, because the
directories do not contain sufficient information upon which to base
the exclusion of some stacks out of a large battery. Therefore, in
large steel plants all active stacks are included in the figures.
The data in the table are for the active plants and stacks only,
although to be classed as active it was necessary only that a plant
or stack should have been active at some time during the period,
not active continuously. Here again, in the case of steel plants it is
impossible to be certain of absolute accuracy on this point, because
the directories do not specify which stacks out of a large number in
the plant were idle throughout the period.
The count, as given in the table, is substantially accurate, although
the classification of some plants in the early periods is somewhat
uncertain. However, the number of such plants and stacks is not
large enough to affect the data to any extent.
Total number of active blast furnaces in the United States, by hind, and the number
of active merchant blast furnaces covered in this study, 1912 to 1926

All active blast
furnaces in the
United States

All active steel
works blast fur­
naces

Number
of plants

Number
of stacks

Number
of plants

C)
145
176
167

(•)
350
389
358

All active mer­
chant blast fur­
naces

Active
merchant
blast
furnaces
covered in study

Number
of plants

Number
of stacks

Number
of plants

52
87

84
124
154
164

b 48

Period or year

1926..................................
1921-1925....................... ;
1917-1920_____________
1912-1914.................. ..

• No data.

1

(•)

58
65
53

Number
of stacks

(a)
226
235
194

111
114

68
67
36

Number
of stacks

‘ 77
93
96
56

h Excluding one ferro-alloy plant.

Iron and Steel Works Directory of the United States and Canada. B y American Iron and Steel Insti­
tute. Eighteenth, nineteenth, and twentieth editions— 1916, 1920, and 1926.

138




A P P E N D IX

5 .— R E L A T I O N

TO

E N T IR E

IN D U S T R Y

139

The table brings out very clearly the decline of the merchant
industry in competition with steel works blast furnaces. In the
early period 1912-1914 the merchant plants numbered more than
twice as many as the steel plants, although the latter excelled in
number of stacks, 194 to 164. By the next period 1917-1920 the
merchant plants had declined slightly in number, but the steel works
blast furnaces increased both in plants and stacks. In 1921-1925 the
steel plants receded somewhat from the peak, suffering a loss of 7
plants and 9 stacks, but the merchant plants declined more than 20
per cent, and their total stacks declined about the same amount.
The steel plants had nearly twice as many stacks active during this
period as the merchant plants had. However, it must not be assumed
that there has been a corresponding decrease in production in either
merchant or steel works furnaces as the decline in number of plants
is partly counterbalanced by the increase in size of the stacks. Nor
do these figures convey the whole story, for quite a number of mer­
chant stacks are included in the table as active because they ran for
part of a year in 1923, while as a matter of fact they have not operated
since and will not do so. The shrinkage in the merchant furnace
industry is best shown by the figures for 1926, when there were less
than half the number of merchant plants active that there were in
the period 1912-1914. As a matter of fact, the decline in strictly
merchant plants has been even greater than shown in the table,
since the figures include a few independently operated steel company
plants, which, according to the definition commonly accepted in the
industry, are not classed as merchant. Some allowance must also be
made for the fact that the data for 1926 cover only one year as
against three years in 1912-1914.
A comparison of the merchant industry as a whole with the plants
included in the bureau averages shows to what extent the data in
this study cover the whole merchant industry. In 1926 only four
active plants, containing seven stacks, are not shown in the averages
for that year; these constitute less than 10 per cent of the industry,
either in number of stacks or in output. In 1921-1925 the bureau’s
representation is better than appears at first sight, for a fairly large
number of the plants and stacks listed for the industry in this period
were active only a few months in 1923; their contribution to the total
merchant furnace production during the period was negligible. The
most important plants missing from the bureau averages during these
years are the same four which did not furnish data for 1926. For
the period 1917-1920 the bureau has data for somewhat less than
two-thirds of the industry, while in 1912-1914 the averages cover
almost exactly one-third, computed either in plants or stacks. Thus,
even in the earliest period, the representation is fairly large. In rela­
tion to amount of pig iron produced the proportion of the industry
represented in the bureau data would be still larger; but no data on
production are available along the lines of this classification of plants.




APPENDIX 6.— METHODS OF COMPUTING MAN-HOURS

The part of this study which required the greatest expenditure of
time was the computation of the man-hours. This particular subject
raised some difficult problems, especially in the field work. These
difficulties centered around two main points: (1) The definition of
a blast furnace plant, and (2) the compilation of the man-hours from
available data.
In theory, the definition of a merchant blast furnace is simple
enough, but when the definition is applied to the problem of obtain­
ing man-hours all fine theoretical distinctions have to be subordinated
to the practical necessities of the situation. The guiding principle
in all this work was so to define the blast-furnace plant that the manhour data for all plants would cover uniform operations, even though
this involved the adjustment of the man-hours for some plants.
The best example of this first point is the sintering plant which
is an integral part of many blast furnace plants. In one sense sinter­
ing is an important process in blast furnace operation; most large
modern plants include a sintering machine in their equipment. But
the sintering plant is not an absolutely essential part of furnace oper­
ation; it can and does operate independently of the blast furnace,
and it does not exist in many of the smaller, older plants. Therefor:-,
the decision was made to exclude the sintering machine from the defi­
nition of a merchant blast furnace, which meant eliminating all sintBr­
ing labor from the man-hours.
A second illustration is that of ore crushers or roasters. These
machines treat or rework the ore so as to improve it for smelting in the
blast furnace. Yet, because the treatment of ore is really a
part of mining and not smelting, these too had to be excluded from
the definition.
Still another illustration is that of a slag disposal or cement plant.
Ten or 15 years ago most blast furnaces dumped their slag in the
most convenient place and left it. Recently, however, slag has come
to be a valuable by-product of pig iron manufacture, and at the pres­
ent time there are very few blast-furnace plants which do not sell
or remanufacture their slag. Sometimes the slag is contracted for by
an outside company, which takes charge of it as soon as it is dumped.
In other cases, however, the blast furnace company builds its own
slag-crushing plant and does its own manufacturing. In these plants
it was sometimes necessary to take out the slag-preparation manhours from the total man-hours for the plant.
Finally, there is another class of cases which concern deficiencies
in particular plants. At one blast-furnace plant there was no yard
railway, the switching being done by the railroad company which
delivered the ore and other materials. No switching labor appears
in the total man-hours for the plant, and yet this is an essential opera­
tion which is actually being performed in this plant. In the lakeside
plants, the dock labor is usually included with the blast-furnace labor,
but there are some lakeside plants at which the dock unloading is
done by a separate terminal company. In all such cases the principle
followed has been that of taking the man-hours for the plant just as
they are, all exceptional situations or arrangements being noted.
Such plants show a slightly higher productivity than they would if
all the essential man-hours were included in the data, and to that
140




APPENDIX

6.—

METHODS OF COMPUTING MAN-HOURS

141

extent some allowance must be made in comparing them with other
plants in the industry.
The second major problem arose in connection with the actual com­
pilation of the man-hours from the plant records. There is almost no
uniformity among the plants in the industry in their records of manhours, but in a general way the plants can be classified into the fol­
lowing groups:
1. A very few plants keep a complete record of all man-hours, classi­
fying and summarizing these man-hours annually. The classification
into labor groups will, of course, be on the basis which is most satis­
factory for the lay-out of the plant, and this may not coincide with a
classification which would be used in another plant; but where the
basis of classification is process and overhead, these man-hours are
very useful.
2. A somewhat larger group of plants keen man-hours for the direct
labor, but have no distribution of the indirect or overhead labor.
In the case of an isolated merchant furnace this makes no difference
for all indirect labor is chargeable to blast-furnace operation, but where
there is integrated operation between a blast furnace and some auxil­
iary process, data on total indirect overhead man-hours are of little
value unless some basis for distribution between the two processes
can be determined upon.
3. A small number of merchant plants keep a monthly record of
man-days of labor by occupations. By using these in connection with
the hours worked per day by those in the occupation it is possible to
calculate the total man-hours for each occupation by months. In this
case also the problem of distributing the overhead labor is a serious
one in plants where there are two or more operations to be considered.
4. A type of record much more frequent in the blast-furnace industry
than those listed above is that of daily force reports by positions;
these are usually kept in a time book, each position being given one
line and each day the position was filled being entered up in the
appropriate column. If the number of working-days for each position
is added up at the end of the pay period— month, half month, or 10
days— it is possible to add up the total working-days on each posi­
tion, and by combining these as necessary, the man-days and even­
tually the man-hours for any labor group can be obtained. In case
such figures are not found totaled the expenditure of time in making
additions would be prohibitive, and the man-days worked on each
position must be estimated from a quick survey of the record. Be­
cause of the fact that very many blast-furnace jobs must be filled
every day, this is very much simpler than it might seem; keepers,
blowers, foremen, stovetenders, watertenders, and numerous other
positions will be filled by a fixed number of men every day the
furnace operates, and no calculation is necessary beyond figuring up
the hours per day and multiplying these by the number of days the
plant operated in the course of the year. Attention can then be
concentrated on the positions with varying employment; these can
either be laboriously added up from the time book for the month,
or an average or typical daily employment can be determined upcn;
the latter can be handled as in the case of the more stable positions
indicated above. The resulting total annual man-hours, as calcu­
lated by this method, will contain a certai i amount of error, but
the running of an occasional monthly test coun of hours will serve
to check. Such tests showed but slight variations.



APPENDIX 7.— DEFINITIONS

Blast furnace} — The blast furnace, in which is conducted the
manufacture of pig iron, is merely a cylindrical steel shell lined
throughout with fire brick. This shell varies in height from 40 to
100 feet or even higher, and in each furnace has varying diameters
from top to bottom, the lines of the furnace being thus adjusted to
the various changes going on within it. The furnace consists of
three primary sections— the hearth or lower part, the bosh just
above the hearth, and the inwall or upper section. The hearth
varies in inside diameter anywhere from 10 to 22 feet, the bosh
usually from 12 to 24 feet at the widest part, and the top of the
inwall from about 9 to 18 feet. The walls of the hearth near the
bottom of the furnace are pierced with openings through which the
so-called tuyeres supply a strong blast of heated air to unite with
the carbon of the fuel. The volume of the blast varies from about
25,000 to 40,000 cubic feet of air per minute and is usually heated
to from 1,100° to 1,400° F.
Into the furnace top is charged at frequent intervals the ore, the
fuel (coke, bituminous coal, etc.), and the flux (limestone, dolomite,
etc.), which together make up the “ burden” or furnace charge.
The ore furnishes the iron for which the furnace is operated. The
fuel in combustion gives off gases which serve to reduce the iron to
a metallic form and also supplies the heat necessary for the reactions
which occur within the furnace and to melt the resultant products.
The flux serves to unite with various compounds which would other­
wise be infusible at furnace temperatures, and so not only removes
in a fluid state the ash of the fuel, but the earthy materials and
impurities occurring in the ore. It also serves in such combination
as the means of controlling the amounts of certain elements desirable
in the iron, but desirable only within limited percentages.
As the charge slowly works its way downward, approaching the
zone of highest temperature at or slightly above the tuyeres, the
various reactions become more and more complete and, finally,
fusion of the resultant products occurs, the molten material collect­
ing in the hearth of the furnace, which serves as a reservoir. The
molten iron being of greater specific gravity than the impurities,
sinks to the bottom while the impurities of the ore and ash, together
with the flux, combine to form a slag which floats on the surface of
the iron. The two can then be easily tapped off separately through
openings located at proper levels.
The gaseous products rising through the descending column of
ore, flux, and fuel, pass off through openings at the top and being
combustible, are led through the downcomers to the hot blast stoves
and to the boilers where they are burned.
The tuyeres are small openings in the lower part of the furnace
through which hot air under heavy pressure is blown into the furnace.
J Description taken mainly from A Study of the Blast Furnace, by Harbison-Walker Refractories Co.
of Pittsburgh, Pa

142




APPENDIX 7.— DEFINITIONS

143

In addition to the furnace proper, the blast-furnace plant also
includes auxiliary equipment essential for furnace operation, such as
blowing and pumping engines, hot-blast stoves, stocking and charg­
ing equipment, casting machines, yard railroad, boiler house, etc.
Also a single plant may consist of one blast furnace, or a “ battery”
of a number of furnaces operated together. A few plants, which
were built a number of years ago, have two stacks operated alter­
nately, a practice not common in the industry at the present time.
The hot-blast stoves are cylindrical in form, up to 100 feet or more
in height, and consist of a steel or iron shell lined with fire brick
which forms a number of flues or passages. They are regenerative
in principle, gas being introduced and burned at the bottom. Air is
then forced through the stove at the top, is heated by the hot brick,
and blown from there into the furnace through the tuyeres. The
larger furnaces ordinarily have four stoves each.
Gross tons oj pig iron.— Production of blast-furnace metal is meas­
ured in gross tons (2,240 pounds), without reference to differences
in grade of pig iron produced. All furnaces producing ferro-alloys
have been generally excluded but in some instances, where only a
comparatively small amount of ferro-alloy has been manufactured in
connection with the manufacture of pig iron, the figures have been
used where the labor time could not be separated for each product.
Tonnage of product is measured net; that is, excluding “ runner and
ladle scrap” produced at the furnace, since consideration is given
to usable product, rather than the total metal cast.
Man-hours.— A man-hour is an hour’s work by one man. Total
man-hours is the sum of the hours worked by all of the employees.
The man-hours used in obtaining labor productivity include the total
labor time required for the production of pig iron without reference
to the kind or quality of labor. For example, 8 hours of a foreman’s
time and 48 hours of a laborer’s time aggregate 56 man-hours, to be
combined with the labor time of other workers contributing in pro­
duction regardless of skill, efficiency, or compensation. All direct
and indirect labor essential for blast-furnace operation is used in
compiling man-hour totals for productivity measurement, exclusive
of strictly clerical and office help, concerning which see page iv.
Stack-day.— The calendar days of operation of one furnace, with­
out reference to labor time. In a plant of more than one furnace
the stack-days of operation are the sum of the days operated by
each separate furnace. The term calendar day as here used means
a day of 24 hours.
Output per stack-day.—Average production per furnace per calen­
dar day of operation. Changes from year to year reflect the changes
in materials and operating practice in the smelting process or in the
size of the stack due to rebuilding or alteration.
Sand-cast iron.— Blast-furnace metal cast in sand molds on the
furnace floor and broken up either by hand or machine and when
cool removed to cars by hand labor.
Machine-cast iron.— Blast-furnace metal cast from a ladle into steel
or cast-iron molds run on an endless chain parallel to each other
with edges overlapping. As the ladle is tipped, the travel of the
chain brings into position a continuous train of empty molds to be
filled. The chain carries the full molds through a trough of water,




144

LABOR PRODUCTIVITY— MERCHANT BLAST FURNACES

thus cooling the iron so that it may be dumped at the turn into
cars, ready to be shipped. Thus casting machines eliminate the
hand labor involved in sand casting and loading for shipment.
Molten metal.— Technically molten metal means the liquid pig iron
as drawn from the furnace. However, in this bulletin, when metal
is spoken of as “ molten” it refers to that metal which is conveyed
directly, without cooling, to a foundry or to a steel or other refining
furnace. In most merchant furnaces this covers only a small part
of the product ; usually the metal is cast cold into pigs either in sand
beds or a pig machine.
Ore.— Iron ore is measured in gross tons, no distinction being made
as between quality or preparation for the purposes of this study.
Purchased flue dust is included in the ore totals. Produced flue
dust, however, whether sintered or unsintered, usually recharged at
the furnace, has been excluded from consideration, since it has
already been weighed in when originally charged as ore. Flue dust,
blown to the top of the furnace, k lost at many plants. Where
recovered and recharged it represents an improvement in the total
efficiency of operation, largely reflected in a higher yield. However,
in measuring furnace performance for productivity purposes the same
charge should obviously not be duplicated.
Ore equivalent.— All iron-bearing materials other than ore have
been included under this heading. This includes cinder, scale, scrap,
etc., but excludes “ remelt” or runner and ladle scrap which is excluded
both as product and as charge. These materials are treated apart
from ores because of their high iron content. This furnace scrap is
pig iron which remains in the runners and ladles and has to be chipped
out. It is unfair to charge the furnace with materials which have
already been weighed in. This scrap is not additional raw materials
when recharged, but is rather a recovery of otherwise waste material
during the process of smelting.
Coke.— Coke is commonly measured in net tons, whereas gross
tons are used for ores, ore equivalents, and limestone. Metallurgical
coke may be bee-hive or by-product, no distinction being made in
this study. Figures for consumption have been compiled for
“ natural” coke, i. e., coke before drying.
Flux.— Flux used in blast furnaces is usually limestone, but some­
times lime in the form of oyster shells, dolomite, or some combination
of these ingredients is used. It is impossible to obtain a cheap and
high grade limestone in all localities which usually accounts for the
other fluxes. Small amounts of sand or gravel have sometimes been
added as a fluxing agent.
Sinter.— This word is commonly applied to flue dust (discussed
under iron ores) which is charged into the furnace. The flue dust
collects at the top of the stack and is composed of fine particles of ore
which are blown up through the column of material by the strong
pressure of the blast at the bottom. These ore particles have been
partially refined and are very high in iron content. However, such
material can not be recharged in the form of dust and must be put
through a process of agglomeration (usually sintering) to form the
finely divided particles into porous lumps suitable for handling.
This sintered flue dust must not be conflused with sintered ore.
Ore sintering is explained under treatment of ores.




APPENDIX 7.— DEFINITIONS

145

Treatment of ores.— Iron ores are treated in various ways before
being charged into the furnace. The usual forms of treatment
practiced are: Drying, roasting, washing, jigging, magnetic separa­
tion, briquetting, and nodulizing or sintering. These processes are
resorted to in order to remove excess moisture, to remove waste
materials (clay, rock, and sand), to reduce the percentage of sulphur
in high sulphur ores, to form finely divided material into lumps
suitable for charging, ©tc. Many of the above processes are carried
on at the plant, the most common one being the sintering process.
In sintering fine ore is mixed with fine coal or cok$ breeze dust and
ignited. By the aid of a forced draught the material is burned until
it sinters (combines) into a slab. The slabs are then broken into
sizes suitable for handling. Also the high temperature resulting
from the forced draught drives off the hydroscopic moisture, the
sulphur and the water.
However, all the ore treatment processes have been excluded from
this study, except in a few instances where the man-hours of labor in
ore treatment could not be separated from the total plant labor.