The Jute Industry: From Seed to Finished Cloth by T. Woodhouse and P. Kilgour

T >> T. Woodhouse and P. Kilgour >> The Jute Industry: From Seed to Finished Cloth

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[Illustration: FIG. 36 LOOMS DRIVEN WITH INDIVIDUAL MOTORS _By
permission of The English Electric Co., Ltd._]

The order of lifting and depressing the threads of the warp is, as
already stated, demonstrated on the design paper in Fig. 33, and the
selected order determines, in the simplest cases, the pattern on the
surface of the cloth when the warp and weft yarns are of the same
colour. A great diversity of pattern can be obtained by the method
of interlacing the two sets of yarn, and a still greater variety of
pattern is possible when differently-coloured threads are added to
the mode of interlacing.

To illustrate the contrast in the general appearance of a weaving
shed in which all the looms are driven by belts from overhead
shafting as in Fig. 35, and in a similar shed in which all the looms
are individually driven by small motors made by the English Electric
Co., Ltd. we introduce Fig. 36. This particular illustration shows
cotton weaving shed, but precisely the same principle of driving is
being adopted in many jute factories.

A great variety of carpet patterns of a similar nature to that
illustrated at C, Fig. 32, can be woven in looms such as those
illustrated in Fig. 35; indeed, far more elaborate patterns than
that mentioned and illustrated are capable of being produced in
these comparatively simple looms. When, however, more than 4 leaves
are required for the weaving of a pattern, a dobby loom, of the
nature of that shown in Fig. 37, is employed; this machine is made
by Messrs. Charles Parker, Sons & Co., Ltd., Dundee. The dobby itself,
or the apparatus which lifts the leaves according to the
requirements of the design, is fixed on the upper part of the
frame-work, and is designed to control 12 leaves, that is, it
operates 12 leaves, each of which lifts differently from the others.

[Illustration: _By permission of Messrs. Charles Parker, Sons & Co_.
FIG. 37 DOBBY LOOM]

A considerable quantity of Wilton and Brussels carpets is made from
jute yarns, and Fig. 38 illustrates a loom at work on this
particular branch of the trade. The different colours of warp for
forming the pattern me from small bobbins in the five frames at the
back of the loom (hence the term 5-frame Brussels or Wilton carpet)
and the ends passed through "mail eyes" and then through the reed.
The design is cut on the three sets of cards suspended in the
cradles in the front of the loom, and these cards operate on the
needles of the jacquard machine to raise those colours of yarn which
e necessary to produce the colour effect in the cloth t correspond
with the colour effect on the design paper made by the designer.
This machine weaves the actual Brussels and Wilton fabrics, and
these cloths are quite different from that illustrated at _P_, Fig.
32. In both fabrics, however, ground or foundation warps are
required. It need hardly be said that there is a considerable
difference between the two types of cloth, as well as between the
designs and the looms in which they are woven.[2]

[Footnote 2: For structure of carpets, _see_ pp. 394-114, _Textile
Design: Pure and Applied_, by T. Woodhouse and T. Milne.]

[Illustration: FIG. 38 BRUSSELS CARPET JACQUARD LOOM]

In the weaving department there are heavy warp beams to be placed in
the looms, and in the finishing department there are often heavy
rolls of cloth to be conveyed from the machines to the despatch room.
Accidents often happen when these heavy packages, especially the
warp beams, are being placed in position. In order to minimize the
danger to workpeople and to execute the work more quickly and with
fewer hands, some firms have installed Overhead Runway Systems, with
suitable Lifting Gear, by means of which the warp beams are run from
the dressing and drawing-in departments direct to the looms, and
then lowered quickly and safely into the bearings. Such means of
transport are exceedingly valuable where the looms are set close to
each other and where wide beams are employed; indeed, they are
valuable for all conditions, and are used for conveying cloth direct
from the looms as well as warp beams to the looms. Fig. 39 shows the
old wasteful and slow method of transferring warp beams from place
to place, while Fig. 40 illustrates the modern and efficient method.
The latter figure illustrates one kind of apparatus, supplied by
Messrs. Herbert Morris, Ltd., Loughborough, for this important
branch of the industry.

[Illustration: FIG. 39. THE OLD WAY]

[Illustration: FIG. 40. THE NEW WAY _By permission of Messrs.
Herbert Morris, Ltd_.]

CHAPTER XV. FINISHING

The finishing touches are added to the cloth after the latter leaves
the loom. The first operation is that of inspecting the cloth,
removing the lumps and other undesirables, as well as repairing any
damaged or imperfect parts. After this, the cloth is passed through
a cropping machine the function of which is to remove all projecting
fibres from the surface of the cloth, and so impart a clean, smart
appearance. It is usual to crop both sides of the cloth, although
there are some cloths which require only one side to be treated,
while others again miss this operation entirely.

A cropping machine is shown in the foreground of Fig. 41, and in
this particular case there are two fabrics being cropped or cut at
the same time; these happen to be figured fabrics which have been
woven in a jacquard loom similar to that illustrated in Fig. 38. The
fabrics are, indeed, typical examples of jute Wilton carpets. The
illustration shows one of the spiral croppers in the upper part of
the machine in Fig. 41. Machines are made usually with either two or
four of such spirals with their corresponding fixed blades.

[Illustration: FIG. 41 CROPPING MACHINE AT WORK]

The cloth is tensioned either by threading it over and under a
series of stout rails, or else between two in a specially adjustable
arrangement by means of which the tension may be varied by rotating
slightly the two rails so as to alter the angle formed by the cloth
in contact with them. This is, of course, at the feed side; the
cloth is pulled through the machine by three rollers shown
distinctly on the right in Fig. 42. This view illustrates a double
cropper in which both the spirals are controlled by one belt. As the
cloth is pulled through, both sides of it are cropped by the two
spirals.[3] When four spirals are required, the frame is much wider,
and the second set of spirals is identical with those in the
machines illustrated.

[Illustration: FIG 42 DOUBLE CROPPING MACHINE _By permission of
Messrs. Charles Parker, Sons & Co., Ltd_.]

[Footnote 3: For a full description of all finishing processes,
see _The Finishing of Jute and Linen Fabrics_, by T. Woodhouse.
(Published by Messrs. Emmott & Co., Ltd., Manchester.)]

The cropped cloth is now taken to the clamping machine, and placed
on the floor on the left of the machine illustrated in Fig. 43,
which represents the type made by Messrs. Charles Parker, Sons &, Co.,
Dundee. The cloth is passed below a roller near to the floor, then
upwards and over the middle roller, backwards to be passed under and
over the roller on the left, and then forwards to the nip of the
pulling rollers, the bottom one of which is driven positively by
means of a belt on the pulleys shown. While the cloth is pulled
rapidly through this machine, two lines of fine jets spray water on
to the two sides of the fabric to prepare it for subsequent processes
in which heat is generated by the nature of the finishing process.
At other times, or rather in other machines, the water is
distributed on the two sides of the cloth by means of two rapidly
rotating brushes which flick the water from two rollers rotating in
a tank of water at a fixed level. In both cases, both sides of the
fabric are "damped," as it is termed, simultaneously. The damped
fabric is then allowed to lie for several hours to condition, that is,
to enable the moisture to spread, and then it is taken to the
calender.

[Illustration: _By permission of Messrs. Charles Parker, Sons & Co.,
Ltd_. FIG. 43 DAMPING MACHINE]

The calenders for jute almost invariably contain five different
rollers, or "bowls," as they are usually termed; one of these bowls,
the smallest diameter one, is often heated with steam. A five-bowl
calender is shown on the extreme right in Fig. 41, and in the
background, while a complete illustration of a modern 5-bowl calender,
with full equipment, and made by Messrs. Urquhart, Lindsay & Co., Ltd.,
Dundee, appears in Fig. 44.

[Illustration: _By permission of Messrs. Urquhart, Lindsay & Co., Ltd_.
FIG. 44 CALENDAR]

The cloth is placed on the floor between the two distinct parts of
the calender, threaded amongst the tension rails near the bottom
roller or bowl, and then passed over two or more of the bowls
according to the type of finish desired. For calender finish, the
bowls flatten the cloth by pressing out the threads and picks, so
that all the interstices which appear in most cloths as they leave
the loom, and which are exaggerated in the plan view in Fig. 34, are
eliminated by this calendering action. The cloth is then delivered
at the far side of the machine in Fig. 44. If necessary, the surface
speed of the middle or steam-heated roller may differ from the
others so that a glazed effect--somewhat resembling that obtained by
ordinary ironing--is imparted to the surface of the fabric. The
faster moving roller is the steam-heated one. For ordinary calender
finish, the surface speed of all the rollers is the same.

Another "finish" obtained on the calender is known as "chest finish"
or "round-thread finish." In this case, the whole length of cloth is
wound either on to the top roller, or the second top one, Fig. 44,
and while there is subjected to the degree of pressure required; the
amount of pressure can be regulated by the number of weights and the
way in which the tension belt is attached to its pulley. The two
sets of weights are seen clearly on the left in Fig. 44, and these
act on the long horizontal levers, usually to add pressure to the
dead weight of the top roller, but occasionally, for very light
finishes, to decrease the effective weight of the top bowl. After
the cloth has been chested on one or other of the two top bowls, it
is stripped from the bowl on to a light roller shown clearly with
its belt pulley in Fig. 41.

There are two belt pulleys shown on the machine in Fig. 44; one is
driven by an open belt, and the other by a crossed belt. Provision
is thus made for driving the calender in both directions. The
pulleys are driven by two friction clutches, both of which are
inoperative when the set-on handle is vertical as in the figure.
Either pulley may be rotated, however, by moving the handle to a
oblique position.

The compound leverage imparted to the bearings of the top bowl, and
the weights of the bowls themselves, result in the necessary pressure,
and this pressure may be varied according to the number of small
weights used. The heaviest finish on the calender, i.e. the
chest-finish on the second top roller, imitates more or less the
"mangle finish."

[Illustration: _By permission of Messrs. Urquhart, Lindsay & Co., Ltd_.
FIG. 45 HYDRAULIC MANGLE]

A heavy hydraulic mangle with its accumulator and made by Messrs.
Urquhart, Lindsay & Co., Ltd., Dundee, is illustrated in Fig. 45.
The cloth is wound or beamed by the mechanism in the front on to
what is termed a "mangle pin"; it is reality a thick iron bowl; when
the piece is beamed, it is automatically moved between two huge
rollers, and hydraulic pressure applied. Four narrow pieces are
shown in Fig. 45 on the pin, and between the two rollers. There are
other four narrow pieces, already beamed on another pin, in the
beaming position, and there is still another pin at the delivery
side with a similar number of cloths ready for being stripped. The
three pins are arranged thus o deg.o, and since all three are
moved simultaneously, when the mangling operation is finished, each
roller or pin is moved through 120 deg.. Thus, the stripped pin will be
placed in the beaming position, the beamed pin carried into the
mangling position, and the pin with the mangled cloth taken to the
stripping position.

While the operation of mangling is proceeding, the rollers move
first in one direction and then in the other direction, and this
change of direction is accomplished automatically by mechanism
situated between the accumulator and the helical-toothed gearing
seen at the far end of the mangle. And while this mangling is taking
place, the operatives are beaming a fresh set, while the previously
mangles pieces are being stripped by the plaiting-down apparatus
which deposits the cloth in folds. This operation is also known as
"cuttling" or "faking." It will be, understood that a wide mangle,
such as that illustrated in Fig. 45. is constructed specially for
treating wide fabrics, and narrow fabrics are mangled on it simply
because circumstances and change of trade from time to time demand it.

[Illustration: _By permission of Messrs. Charles Parker, Sons & Co.
Ltd_. Fig 46 FOLDING, LAPPING OR PLEATING MACHINE]

The high structure on the left is the accumulator, the manipulation
of this and the number of wide weights which are ingeniously brought
into action to act on the plunger determine the pressure which is
applied to the fabrics between the bowls or rollers.

Cloths both from the calender and the mangle now pass through a
measuring machine, the clock of which records the length passed
through. There are usually two hands and two circles of numbers on
the clock face; one hand registers the units up to 10 on one circle
of numbers, while the slower-moving hand registers 10, 20, 30, up to
100. The measuring roller in these machines is usually one yard in
circumference.

If the cloth in process of being finished is for use as the backing
or foundation of linoleum, it is invariably wound on to a wooden
centre as it emerges from the bowls of the calender, measured as well,
and the winding-on mechanism is of a friction drive somewhat similar
to that mentioned in connection with the dressing machine. Cloths
for this purpose are often made up to 600 yards in length; indeed,
special looms, with winding appliances, have been constructed to
weave cloths up to 2,000 yards in length. Special dressing machines
and loom beams have to be made for the latter kind. When the
linoleum backing is finished at the calender, both cloth and centre
are forwarded direct to the linoleum works. The empty centres are
returned periodically.

Narrow-width cloths are often made up into a roll by means of a
simple machine termed a calenderoy, while somewhat similar cloth,
and several types of cloths of much wider width, are lapped or
folded by special machines such as that illustrated in Fig. 46. The
cloth passes over the oblique board, being guided by the discs shown,
to the upper part of the carrier where it passes between the two bars.
As the carrier is oscillated from side to side (it is the right hand
side in the illustration) the cloth is piled neatly in folds on the
convex table. The carriers may be adjusted to move through different
distances, so that any width or length of fold, between limits, may
be made.

Comparatively wide pieces can be folded on the above machine, but
some merchants prefer to have wide pieces doubled lengthwise, and
this is done by machines of different kinds. In all cases, however,
the operation is termed "crisping" in regard to jute fabrics. Thus,
Fig. 47, illustrates one type of machine used for this purpose, and
made by Messrs. Urquhart, Lindsay & Ca., Ltd., Dundee. The
full-width cloth on the right has obviously two prominent
stripes--one near each side. The full width cloth passes upwards
obliquely a triangular board, and when the cloth reaches the apex it
is doubled and passed between two bars also set obliquely on the left.
The doubled piece now passes between a pair of positively driven
drawing rollers, and is then "faked," "cuttled," or pleated as
indicated. The machine thus automatically, doubles the piece, and
delivers it as exemplified in folds of half width. In other
industries, this operation is termed creasing and, rigging. Some of
the later types of crisping or creasing machines double the cloth
lengthwise as illustrated in Fig. 47, and, in addition, roll it at
the same time instead of delivering it in loose folds.

[Illustration: _By permission of Messrs. Urquhart Lindsay & Co. Ltd_.
FIG. 47 CRISPING, CREASING OR RIGGING MACHINE]

If the cloth is intended to be cut up into lengths, say for the
making of bags of various kinds, and millions of such bags are made
annually, it is cut up into the desired lengths, either by hand,
semi-mechanically, or wholly mechanically, and then the lengths are
sewn at desired places by sewing machines, and in various ways
according to requirements.

[Illustration: _By permission of Messrs. Urquhart, Lindsay & Co. Ltd_
FIG 48 SEMI-MECHANICAL BAG OR SACK CUTTING MACHINE]

Fig. 48 illustrates one of the semi-mechanical machines for this
purpose; this particular type being made by Messrs. Urquhart,
Lindsay & Co., Ltd., Dundee. About eight or nine different cloths
are arranged in frames behind the cutting machine, and the ends of
these cloths passed between the horizontal bars at the back of the
machine. They are then led between the rollers, under the cutting
knife, and on to the table. The length of cloth is measured as it
passes between the rollers, and different change pinions are
supplied so that practically any length may be cut. Eight or nine
lengths are thus passed under the knife frame simultaneously, and
when the required length has been delivered, the operative inserts
the knife in the slot of the knife frame, and pushes it forward by
means of the long handle shown distinctly above the frame and table.
He thus cuts eight or nine at a time, after which a further length
is drawn forward, and the cycle repeated. Means are provided for
registering the number passed through; from 36,000 yards to 40,000
yards can be treated per day.

The bags may be made of different materials, e.g. the first four in
Fig. 32. When hessian cloth, II, Fig. 32, is used, the sewing is
usually done by quick-running small machines, such as the Yankee or
Union; each of these machines is capable of sewing more than 2,000
bags per day. For the heavier types of cloth, such as sacking,
_S_, Fig. 32, the sewing is almost invariably done by the Laing or
overhead sewing machine, the general type of which is illustrated in
Fig. 49, and made by Mr. D. J. Macdonald, South St. Roque's Works,
Dundee. This is an absolutely fast stitch, and approximately 1,000
bags can be sewn in one day.

[Illustration: FIG. 49 OVERHEAD (LAING) SACK SEWING MACHINE _By
permission of Mr. D. J. Macdonald_]

The distinctive marks in bags for identification often take the form
of coloured stripes woven in the cloth, and as illustrated at
_S_, Fig. 32. It is obvious that a considerable variety can be
made by altering the number of the stripes, their position, and
their width, while if different coloured threads appear in the same
cloth, the variety is still further increased.

Many firms, however, prefer to have their names, trade marks, and
other distinctive features printed on the bags; in these cases, the
necessary particulars are printed on the otherwise completed bag by
a sack-printing machine of the flat-bed or circular roller type. The
latter type, which is most largely used, is illustrated in Fig. 50.
It is termed a two-colour machine, and is made by Mr. D. J. Macdonald,
Dundee; it will be observed that there are two rollers for the two
distinct colours, say red and black. Occasionally three and
four-colour machines are used, but the one-colour type is probably
the most common.

[Illustration: _By Permission of Mr. D. J. Macdonald_. FIG 50 SACK
PRINTING MACHINE]

The ownership of the bags can thus be shown distinctly by one of the
many methods of colour printing, and if any firm desires to number
their bags consecutively in order to provide a record of their stock,
or for any other purpose, the bags may be so numbered by means of a
special numbering machine, also made by Mr. D. J. Macdonald.

The last operation, excluding the actual delivery of the goods, is
that of packing the pieces or bags in small compass by means of a
hydraulic press. The goods are placed on the lower moving table upon
a suitable wrapping of some kind of jute cloth; when the requisite
quantity has been placed thereon, the top and side wrappers are
placed in position, and the pumps started in order to raise the
bottom table and to squeeze the content between it and the top fixed
table. From 1 1/2 ton to 2 tons per square inch is applied
according to the nature of the goods and their destination. While
the goods are thus held securely in position between the two plates,
the wrappers a sewn together. Then specially prepared hoops or metal
bands are placed round the bale, and an ingenious and simple system,
involving a buckle and two pins, adopted for fastening the bale. The
ends of the hoop or band are bent in a small press, and these bent
ends are passed through a rectangular hole in the buckle and the
pins inserted in the loops. As soon as the hydraulic pressure is
removed, the bale expands slightly, and the buckled hoop grips the
bale securely.

Such is in brief the routine followed in the production of the fibre,
the transformation of this fibre, first into yarn, and then into
cloth, and the use of the latter in performing the function of the
world's common carrier.

INDEX

ACCUMULATOR
Assorting jute fibre.

BAG-MAKING
Bale opener
opening
Baling cloth
house
press
station
Bast layer (see also Fibrous layer)
Batch
Batchers
Batching
apparatus
carts or stalls
Batch-ticket
Beamer's lease
Beaming
(dry) direct from bank,
Blending
Bobbin winding
Bojah
Botanical features of jute plants
Breaker card
Brussels carpet
Bundle of jute.

CALCUTTA, jute machinery introduced into
Calender
finish
Calenderoy
Carding
Card waste
Cargoes of jute
Chest finish
Clasp-rods
Conditioning fibre
Cops
Cop winding
Corchorus capsularis
clitorius
Crisping and crisping machines
Cropping machine
Cultivation of jute
Cutting knife for jute fibre
Cuttings.

DAMPING machine
Defects in fibre and in handling
Designs or weaves
Differential motion
Dobby loom
Draft
Drafting
Drawing
frames
different kinds of
Drawing-in
Dressing and dressing machine
Drum
Drying jute fibre
Dust shaker.

EAST India Co.
Exports of jute from India.

FABRICS
Faller
Farming operations
Fibres,
the five main
imports of jute.

Fibrous layer
Finisher card
Finishing
folding machine.

Gaiting
Glazed finish
Grading jute fibre
Gunny bags.

Hand batching
Harvesting the plants
Height of jute plants
Hydraulic mangle
press.

Identification marks on bags
Imports of jute.

Jacquard loom
Jute crop
exports from India
fabrics
fibre, imports of
industry
knife
plants, botanical and physical features of
cultivation of
height of
marks.

Laddering
Ladders
Lapping machine
Linking machine
Linoleum
Looms
Lubrication of fibre.

Machine batching
Machinery for jute manufacture introduced into Calcutta
Mangle finish
(hydraulic)
Marks of jute (_see_ jute marks)
Maund
Measuring and marking machine
machine for cloth
the warp
Methods of preparing warps
Multiple-colour printing machines.

Numbering machine for bags.

Opening jute heads
Overhead runway systems
sewing machine (Laing's).

Packing goods
Physical features of jute plants
Pin-lease
Plaiting machine
Plants, thinning of
weeding of
Ploughs for jute cultivation
Point-paper designs
Porcupine feed
Printing machine.

Reach
Reeling
Retting
Roller-feed
Rolls
Root-comber
opener
Round-thread finish
Rove
Roving frame
Roxburgh, Dr.

Sack-cutting frame, semi-mechanical
Sack making
printing machine
Sand bags
Seed
per acre, amount of
sowing of
Sewing machines
Shell-feed
Short-tell
Snipping machine
Softening machines
Spinning
Spool or roll winding
Spools (_see_ Rolls)
Standard bale
Starching (_see_ Dressing)
Steeping (_see_ Retting)
Striker-up (_see_ Batcher)
Stripping
Systems.

Teazer
Tell (of yarn)
Thinning of plants
Thrum
Time for harvesting the plants
Tube-twisters
Twist
Twisting
Two-colour printing machine
Tying-on
Typical jute fabrics.

Union Or Yankee sewing machine
Unloading bales of jute from ship.

Variations in jute
Varieties of jute fibre
plants.

Warp
Warp dressing (_see_ Dressing)
Warping, beaming and dressing
mill
Washing
Waste
teazer
Weaves or designs
Weaving
Weaver's lease
Weeding of plants
Weft
winding
Wilton carpet
Winding (bobbin) machine
from hank
(large roll) machine
(ordinary size from hanks) machine
rolls and cops
World's great war.

Yankee or Union sewing machine
Yarn table
Yield of fibre.

_Printed by Sir Isaac Pitman & Sons, Ltd., Bath, England_

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