Yarn quality requirement for shuttle less weaving
INTRODUCTION
Modern weaving machines stand out as an expensive
class compared to conventional machines in terms of capital investment. This
basic difference requires certain prerequisites to be considered while planning
to venture into modern weaving machines. This paper is intended to throw light
on the essential requirements to be met by the preparatory operations involved
in shuttleless weaving. The quality of yarn used on shuttleless looms is the
prime criteria considered for quality weaving. Parameters related to the
quality warp and weft has been discussed. The machine parameters to be
controlled for an optimised preparatory operation have been dealt with respect
to winding, war ping and sizing operations. Guidelines for machine stoppages
corresponding to warp and weft breakages in weaving are considered as important
in deciding the efficiency of a shuttless weaving shed.
Limitations of Shuttle
Looms
Despite the relatively
high speed and efficiencies in loom with conventional
picking, productivity of these machines will continue to be limited as long as their
fundamental constructions involved the use of shuttle propulsion. Vincent has shown that the power required for picking is proportional to the cube of the loom speed. If the loom speed isincreased from 200 to 300 picks per minute, the power requirement would increase by a factor of (3/2)3 i.e. 3.4 times approximately. This results in following disadvantages
picking, productivity of these machines will continue to be limited as long as their
fundamental constructions involved the use of shuttle propulsion. Vincent has shown that the power required for picking is proportional to the cube of the loom speed. If the loom speed isincreased from 200 to 300 picks per minute, the power requirement would increase by a factor of (3/2)3 i.e. 3.4 times approximately. This results in following disadvantages
1. Greater strain
imposed on the picking mechanism, thus rendering it liable to frequent failure.
2. Greater amount of
noise and vibration.
3.
Because of superior
energy in shuttle, greater strain is again imposed on the Checking
mechanism.
4. The movement of
shuttle will be more difficult to control and there will be a Greater
possibility of its ejection from the loom.
The dynamic problems
created by the picking and checking mechanism and the
inherent process of pirn winding for shuttle looms had encouraged the loom
makers to develop alternative means of weft insertion in which heavy shuttle is not
refer these looms as shuttleless looms. The various shuttleless looms that have been
developed over a period of about 50 years can be classified into various groups.
inherent process of pirn winding for shuttle looms had encouraged the loom
makers to develop alternative means of weft insertion in which heavy shuttle is not
refer these looms as shuttleless looms. The various shuttleless looms that have been
developed over a period of about 50 years can be classified into various groups.
·
Projectile Looms
·
Rapier Looms
·
Air Jet Looms
·
Multiphase Looms
Yarn quality
requirements
Tension on the warp on
a high speed shuttleless weaving machine is higher than that on conventional
loom. On some Repier looms, interference by rapiers, at the initial points of
entry and terminal point of shed exit, can cause bending of the top yarn sheet
around the rapier head producing excessive warp strain on the selvedge region
of warp. Weft tension on Sulzer Ruti projectile weaving machine is equally
high, where tucked-in selvedge is formed.
Consistency of single end strength, C.V. of count
and elongation isessential. Quality of yarn should be at least within
25% Uster which means the quality is among the best 25% of the mills
in the world. Normally shuttleless weaving machine works three to four
times
faster and if the quality of warp remains the same, warp breaks will
increase
three to four times resulting in low production. Yarn should be more
even and
the following parameters of yarn are to be critically reviewed; C. V. of
count,
single thread strength, C. V. of single thread strength, imperfections
per
1,000 meters such as thick places, thin places, and neps. Hairy yarn
will not
be suitable in air jet weaving as it will misdirect the weft insertion.
1. Warping
At warping, the goal should be to avoid missing ends. Number
of thread breakages should not exceed seven per 10 million meters. This can be
achieved by ensuring a top quality yarn package and by following the warping
process parameters mentioned below:
·
Precise
creel alignment
·
Reliable
stop motion on creel and on warping drum, so that broken ends are traceable for
knotting.
·
Minimum
wobbling of warping beams.
·
Uniform
selvedge with good flanges.
·
Yarns
should by preferably warped on spindle driven machines to avoid thermal damage
due to abrasion. Warping machines such as Benninger or Hacoba are preferable.
With drum driven warpers such as the BC Warper, the
following precautionary measures are to be taken:
·
Frictional
drum should be kept in a polished state.
·
Brake
should be very efficient.
·
Aluminium
cast flanges should be used to get faulteless selvedges.
·
Breakages
rate should not exceed 0.3~0.5 breaks per 1000 m / 500 ends.
·
For
wider width looms, wider warping machines are preferred.
Ends breaks during warping
|
Weaving
unit
|
Count
(Ne)
|
Warping
speed(m\min)
|
|
1
|
30s
|
400
|
|
2
|
40s
|
600
|
|
3
|
40s
|
350
|
|
4
|
50s
|
600
|
|
5
|
50s
|
1000
|
|
6
|
60s
|
800
|
|
7
|
60s
|
900
|
|
8
|
60s
|
600
|
|
9
|
80s
|
600
|
|
10
|
80s
|
900
|
Quaility levels of yarns
during high speed warping
|
Yarn quality
|
40s
|
50s
|
60s
|
|
Rkm
|
18.98
|
19.11
|
19.05
|
|
Cv of Rkm
|
7.99
|
7.33
|
10.26
|
|
Breaking elongation
|
4.97
|
5.63
|
4.91
|
|
Hairiness
|
5.16
|
4.8
|
4.51
|
|
Normal imperfections\km
|
142
|
128
|
169
|
International norms for
end breaks during high speed warping
|
Count(Ne)
|
End
breaks per million meter of yarn
|
|
30s to 40s
|
0.65
|
|
50s to 60s
|
0.80
|
|
80s to 100s
|
1.0
|
2. Sizing
During sizing, in view
of the stretch the yarn undergoes at various zones, some loss in yarn
elongation is inevitable.however, these needs to be maintained at its lowest
possible level to ensure better working in loom shed.this is particularly
important for Indian yarns where the breaking elongation is comparatively
lower.
In the weaving units
covered in the study, the loss in elongation during sizing varies between as
low as 0.3% to as high as 1.6%.
To minimise loss in
yarn elongation during sizing, the total stretch during sizing need to be
maintained at lower than 1.0%. Optimum yarn tension levels during sizing in
different zones with a view to avoid exessive stretch are given.
Optimum yarn tension
during sizing
Loss in yarn elongation
and lappers during sizing
|
|
%
of single yarn strength
|
||
|
Zone
|
Creel
|
Between
finishing squeeze roll to the first drying cylinder
|
Head
stock
|
|
Yarn tension
|
2%
|
5%
|
10%
|
Lappers during sizing
vary between 0.2 per 1000 ends per 1000m and 1 per 1000 ends per 1000m in the
sizing units studied, under good working conditions, incidence of lappers
during sizing needs to be maintained below 0.2per 1000ends per 1000 m.in
general, when the sizing lappers are more, the corresponding yarn has higher
loss in elongation.results of a study conducted in this connection for 60s and
80s yarns are given.
|
Count(Ne)
|
Lappers during sizing
(per 1000ends\1000m)
|
Loss in yarn
elongation during sizing (absolute values)(%)
|
|
60s
|
0.1
|
0.27
|
|
60s
|
0.33
|
0.60
|
|
80s
|
0.28
|
0.50
|
The hairiness
reduction during sizing varies between 25 and 80% in different sizing units.in
sizing units where the hairiness reduction is of ahigher order,they generally
employ hihger proportion of PVA as the film former in the size mix.earlier PVA
was generally used for pet and p\c blends.now even for 100% cotton yarns PVA as
a sizing ingradiant is being increasingly used particularly for yarns meant for
shuttle less looms,where weft insertion rate is of a higher order.the
PVAcoating is strong,abrasion resistant and can easily be desized in hot
water.its strength is greater than standard starch and it is also more
flexible.
The size recipes used in
4 sizing units with different level of hairiness reduction during sizing are
provided
|
Sizing unit
|
Count of warp(Ne)
|
Type of loom
|
% reduction in yarn hairiness after sizing
|
Sizing ingradiants of the size mix
|
% size pick up
|
|
1
|
50s
|
Projectile
|
70.10
|
PVA 23%
Starch 69%
Lubricants8%
|
15
|
|
2
|
50s
|
Air jet
|
70.34
|
PVA 23%
Starch 69%
Lubricants8%
|
18
|
|
3
|
60s
|
Projectile
|
52.08
|
PVA 6%
Starch 87%
Lubricants7%
|
15
|
|
4
|
60s
|
Air jet
|
44.49
|
PVA 12%
Starch 82%
Lubricants 6%
|
18
|
In units 1 and 2 where
hairiness reduction is of the order of 70% the size recipe has PVA at 23%.on
the other hand in units 3and 4 where hairiness reduction is around 50% the size
recipe has relatively lower concentration of PVA at 6 to 12%.
Among the weaving units surveyed,
some have achieved breakage rate close to the gudeline balues recommended in
this.major quality attributes of warp yarns used in those uints are given.
Uster statistics rating of quality
levels of warp yarns
|
Quality
parameters
|
Air
jet
|
Projectile
|
Rapier
|
||||
|
50s
|
60s
|
50s
|
60s
|
80s
|
40s
|
60s
|
|
|
Rkm
|
Between 25-50%
|
75%
|
50%
|
Between 75-95%
|
Between 75-95%
|
Between 5-25%
|
Between 75-95%
|
|
CV of Rkm (%)
|
5%
|
Between 75-95%
|
Between 25-50%
|
75%
|
Between 75-95%
|
Between 25-50%
|
Between 25-50%
|
|
Breaking elongation (%)
|
Between 25-50%
|
95%
|
75%
|
75%
|
95%
|
75%
|
95%
|
|
Hairiness index
|
50%
|
50%
|
Between 5-25%
|
75%
|
75%
|
Between 5-25%
|
25%
|
|
Normal
imperfections
|
|||||||
|
Thinplaces\km
(-50%)
|
Between 5-25%
|
Between 5-25%
|
5%
|
Between 25-50%
|
Between 5-25%
|
5%
|
50%
|
|
Thick places\km(+50%)
|
Between 5-25%
|
Between 5-25%
|
Between 5-25%
|
Between 5-25%
|
25%
|
5%
|
50%
|
|
Neps\km(+200)
|
Between 5-25%
|
Between 5-25%
|
Between 5-25%
|
Between 5-25%
|
Between 25-50%
|
Between 25-50%
|
Between 5-25%
|
|
Total imperfections
|
Between 5-25%
|
Between 5-25%
|
Between 5-25%
|
Between 5-25%
|
25%
|
25%
|
25%
|
Suggested values of yarn
quality
|
Yarn quality
|
40S
|
60s
|
80s
|
|
Rkm(G\tex)
|
18
|
20
|
20
|
|
CV of Rkm (%)
|
8.5
|
9
|
10
|
|
Br.elongation (%)
|
5.25
|
5
|
4.75
|
|
Normal imperfections\km
|
125
|
150
|
300
|
|
Hairiness index
|
5
|
4.2
|
3.6
|
|
Classimat faults\Lakh m
|
1 or below
|
||
|
Long thin faults(H1+I1)
|
10
|
15
|
22
|
Case
study 1
Count 60s, projectle loom, satin
|
Yarn qulity
|
Weaving performance
|
|
|
Rkm value
|
18(19)
|
Warp breaks\10000 ends \Lakh
m of weft insertion;4
Guide line value;3
|
|
Imperfections\km
|
300(150)
|
|
|
Classmat faults;long thin
|
31(15)
|
|
The values given in the parenthesis refer to
suggested values of yarn quality requirments for projectile loom
Case
study 2
Count 80s, projectile loom, satin
|
Yarn qulity
|
Weaving performance
|
|
|
Rkm value
|
16(20)
|
Warp breaks\10000 ends \Lakh
m of weft insertion;7.7
Guide line value;1.5
|
|
CV of Rkm
|
13.5(10)
|
|
|
Classmat faults;long thin
|
95(15)
|
|
The values given in the parenthesis refer to
suggested values of yarn quality requirments for projectile loom.
Case
study 3
Count 60s, air jet loom, plain
|
Yarn qulity
|
Weaving performance
|
|
|
Rkm value
|
17.9(21)
|
Warp breaks\10000 ends \Lakh
m of weft insertion;6
Guide line value;3
|
|
Imperfections\km
|
408(150)
|
|
|
Classmat faults;long thin
|
29(15)
|
|
The values given in the parenthesis refer to
suggested values of yarn quality requirments for airjet loom
Shuttleless Looms
Because the shuttle can cause yarns
to splinter and catch, several types of shuttleless looms have been developed.
These operate at higher speeds and reduced noise levels.
Some of the common shuttleless looms
include water-jet looms, air-jet looms, rapier looms, and projectile looms.
Projectile Loom (Gripper Shuttle
Loom)
The multi gripper projectile weaving
machine, introduced by sulzer brothers in 1953, was the first system to begin
shuttleless Weaving.The Company and its successors have remained the sole
suppliers of projectile weaving machinery.
Pick lengths of weft yarn are drawn from large cones by a
weft accumulator.The free end is held in the jaws of a weft carrier
gripper(projectile),88mm long weighing 40kg and the accumulated yarn is
threaded to a sophisticated tensioning and braking system.The Projectile is
lifted to the picking position and is propelled across the warp shed by a
torsion bar system.At the other side of the loom,the projectile is recieved,the
yarn is released and the projectile is ejected for eventual return to the
picking side.The weft is cut at the picking side and is held at both sides by a
selvedge grippers during beat up and shed change.During the next machine
cycle,tucking needles draw the outer ends of weft yarn into fabric to form
selvedges.Usually 10-12 projectiles are associated with a single-width loom.
Picking rates are typically
380-420ppm for worsted yarns and 250-300 ppm for woolen yarns.
It offers the following advantages
·
Low
power consuption
·
Reduced
waste of filling material due to unique clean ,tucked-in selvedges
·
Quick
warp and style change
·
Mechanical
and operatonal reliability and ease of use
·
Low
spare parts requirement and easy maintaince
·
Long
machine life
Rapier Loom
Rapier
Weaving is offered by many loom manufacturers and consequently is in widespread
use in the worsted and woolen industry.
In
this type of weaving a flexible or rigid solid element called rapier, is used
to insert the filling yarn and carries it through the shed .after reaching the
destination, the rapier head returns empty to pick up the next filling yarn,
which completes a cycle.a rapier performs a reciprocating motion.
Single Rapier Machines
A
single,rigid rapier is used in these machines.the rigid rapier is a metal or
composite bar usually with a circular cross section.the rapier enters the shed
from one side and pases it across the weaving machine while retracting.
Therefore a single rapier carries the yarn in one way only and half of the
rapier movement is wasted.also there is no yarn transfer since there is only
one rapier.the single rapiers length is equal to the width of the weaving
machine; this requires relatively high mass and rigidity of the rapier head.for
these reasons, single rapier machines are not popular.however since there is no
yarn transfer to rapier tip rapier, they are suitable for filling yarns that
are difficult control.
Double Rapier Machines
Two
rapiers are used in these machines.one rapier, called the giver takes the
filling yarn from the accumulator on one side of the weaving machine, brings it
to the center of the machine and transfers it to the decond rapier which is
called taker.the taker retracts and brings the filling yarn to the other
side.similar to the single rapier machines, only half of the rapier movements
is used for filling insertion.
Rapier
machines are known for their reliability and performance.since 1972, the rapier
weaving machine has evolved into successfull, versatile and flexible weaving
machine.
A
very wide range of fabrics with 20 g/m2 to heavy fabrics with around 850 gm2
rapier machines are widely used for household textiles and industrial
fabrics.Designed for universal use,the rapier weaving machine can weave not
only the classic wool,cotton and manmade fibers,but also the most technicaly demanding
filament yarns,finest silk and fancy yarns.
Air Jet Loom
Air
jet loom, as one of the shuttleless looms, transports a yarn into warps using
viscosity and kinetic energy of an air jet. Performance of this picking system
depends on the ability of instantaneous inhalation/exhaust, configuration of
nozzle, operation characteristics of a check valve, etc.
Air-jet
weaving is an advanced weaving method with high efficiency and productivity
·
In air-jet looms, the weft is introduced into
the shed opening by air flow.
·
The energy resulting from air pressure is
converted into kinetic energy in the nozzle.
·
The air leaving from the nozzle transfers its
pulse to stationary air and slows down.
·
To this end, in order to achieve a larger rib
width, a confuser is developed, which maintains air velocity in the shooting
line.
·
The confuser drop wires are profiles
narrowing in the direction of shoot, and they are of nearly circular cross
section open at the top.
·
These drop wires are fitted one behind the
other as densely as possible. Therefore, they prevent in the shooting line the
dispersion of air jet generated by the nozzle.
Water Jet Loom
A
water jet is more coherant than an air jet.it does not break up easily, and the
propulsive zone is elongated,making it much more effective.it is effective in
terms of energy requirements ,it is quite and when the jet does break up, it
goes into droplets which create very little turbulence to disturb the filling.
The
droplets spread in such a way as to wet much of the warp; thus a sized warp
containing a water soluble adhesive can be adversely affected.because of this
,water jet weaving is usually restricted to filament yarn,but there is some
hope that it might become economically feasible to weave staple yarns on these
looms.
Two
main reasons for the efficiency of the water-jet loom are that there are no
varying lateral forces to cause the filling to contract and the moving element
is more massive because it is wet.thus there is less chance of fault due to
contact with the warp.
The
range of jet, and thus the width of the loom, depends on the water pressure and
the diameter of the jet.water is virtually incompressible and a simple jerk
pump can be used to give adequate pressure with difficulty.
A
firmans hose has a tremendous range but the jet is several cm in diameter;large
volumes of water and considerable pumping powers have to be used .in weaving ,
a much more modest jet is used; in fact , it is possible to reduce the diameter
of the jet to some 0.1 cm, and the amount of water used per pick is commonly
less than 2c.c. even with these small jets , it is possible to weave at upto 2
meters in width with small power consuptions.it is also possible to weave at
upto 1000 picks/min on narrower looms .several forms of water-jet loom have now
become established.
Circular Loom
The
circular weaving machine proposed by the invention is designed for the
manufacture of tubular fabrics and has an annular frame with an upper ring
plate and a lower ring plate Vertically moving laces are fitted to direct the
warp ends and are mounted at constant intervals round at least one circular
trackway . The two ring plates have bores in them for mounting and directing
the laces. The lower ends of the laces have follower rollers which operate in
conjunction with a cam plate.
Conclusion
It can be concluded that the yarn parameters and machinery
in preparatory for the conventional shuttle looms should be thoroughly assessed
and suitably modified or replaced for their performance for the efficient
functioning of a shuttleless weaving shed. The above factors play a deciding
role in giving quality weaving and better returns thereof.
References
1. Shuttle Looms - Its Present Status
by A. I. Thakkar. NCUTE Pilot Programme on Weaving I - Shuttle looms Page. 47.
(NCUTE, New Delhi, 1999)
2. Vincent J. J. Journal of Textile
Institute, vol. JTI, 50 1959 Page 261.
3. Weaving - A Special Feature by Dr.
Arindam Basu, SITRA in Indian Textile Journal ITJ, June 2002. P. 23.
4. Advances in weaving technology and
looms,
S. Rajagopalan S.S.M. College of
Engineering, Komarapalayam.
5. modular
device for weft yarn presentation in shuttleless looms,by Luciano corain;Luigi
corazzla;Guilio Bortoli,all of V.E.Romangna N1-36015,schio(4),Italy.
- Importance of yarn breakages in weaving process
In
the weaving industry it is always emphasized to increase production and
maintain quality of woven fabric so the mill can meet the demands of both
national and international quality familiar consumers and markets. Also
Competitiveness is the main feature of the textile industry in future. The main
issue is able to compete at international levels. It is clear from many
international exhibitions that the competition will be very brutal in the
coming years. Nowadays many mills are able to produce similar quality of the
woven fabric. Therefore the main issue is the cost of grey cloth per meter. In
order to lower the production costs per meter of woven fabric the yarn
breakages are essential to be reduced at every stage of manufacturing the woven
fabric. In weaving industry one of the most frequent facing problems is
breakages of both warp and weft yarns which not only reduce the production rate
and also deteriorate the quality of the produced fabric. These breakages on the
preparatory processes and also on loom produce lots of problems and become
labor intensive. Lesser the number of yarn breakages lesser will be the
defects. So by reducing these breakages of both warp and weft yarns not only
increase the productivity of the processes involved to the production of
fabrics including warping, sizing etc maintain quality of the woven fabric can
be increased but also reduces wastages of yarn, and energy ultimately the cost
per meter/yard of the prepared fabric reduces.
- See more at: http://textilecentre.blogspot.in/2013/07/project-report-reduction-of-yarn.html#sthash.hBml2J6Q.dpuf
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