Indian Journal of Fibre & Textile Research Vol. 17, December 1992, pp. 194-200
Influence of fibre properties in air jet spinning
W Oxenham"
Department of Textile Industries, University of Leeds, Leeds LS2 9JT, UK
Received 30 January 1992
The properties of fibres used in jet spinning not only affect the spinning performance but also playa significant role in the ultimate yarn quality . The effects of processing parameters and fibre properties are quantified and, in particular, the influences of polyester/cotton blend composition and cotton fibre properties are demonstrated.
Keywords: Cotton fibre, Jet spinning, Polyester/cotton blend , Wrapper fibre , Yarn structure
Introduction Whilst the technology behind air jet spinning can
be traced back at least 30 years\ the commercial exploitation of the technique for short staple spinning must be regarded as a relatively recent development. Several manufacturers have developed systems for producing air jet yarns2 but the MJS (Murata Jet Spinning) system is by far the most successful. Mor~ recently, the use of air jet technology has been applied to the production of two-assembly wound yams3 which are subsequently twisted to yield a two-fold yarn .
Fasciated yarn4 is a term applied to a staple fibre yam which is composed of a central core of essentially parallel fibres bound together by wrapper fibres . The technique which is used to create such structures is often referred to as 'twist transference' and relies on the use of a false twisting process, where 'edge fibres' (which are at the outside edges of the drafted strand and are not false twisted) form wrapper fibres as the core of the yam untwists. Jet spinning is a method for producing fasciated yarns, the essential feature of which being the use of air jets as the false twisting
between the MJS system (Fig.2) and its predecessor is that the newer system utilizes two twisting jets which operate in contrarotation. This arrangement has been shown 5 , both theoretically and practically, to produce a larger number and better distribution of wrapper fibres which result in a stronger yarn.
Several reports6 - 9 have been published on the comparison of properties of jet-spun yarns with those of ring- and rotor-spun yarns. Investigations have also been carried out into the effect of processing conditions on yarn properties I 0, II and, to a lesser extent, the role of fibre properties has also been analyzed 12 , 13. The general finding of most of these researchers is that whilst relatively strong yarns can be produced from polyester and polyester-rich blends, with other fibre types the yarn tenacity is significantly lower than that of ring-spun equivalent.
The results reported in this paper represent a part of an ongoi ng research programme concerned wi th the theoretical and practical aspects of jet spinning I4 - 18 •
unit. Sliver Wraps
The original Du Pont patent l (Fig. I) embodied the essential elements for the production of fasciated yarns but never attained commercial success. This is believed to be associated with the need to produce a uniform distribution of wrapper fibre to yield adequate yarn properties. The major difference
' Present address: Department of Textile and Apparel Management, College of Textiles, North Carolina Stale University, Box 8301, Raleigh, NC 27695-8301, USA
Edge fibr~
Fig. l-Concept of twist transference
OXENHAM: INFWENCE OF FmRE PROPERTIES IN AIR JET SPINNING 195
1 st Nozzle(N 1)
2nd Nozzle(N2)
Fig.2- Principle of Murata Jet Spinner
Whilst the data were obtained using an experimental unit l9 , it is believed that the trends exhibited should be reflected in results which can be achieved from commercial machines.
2 Influence of Blend Composition on the Properties of Polyester/Cotton Yarns
Whilst it has been widely reported that jet spinning is restricted to the processing of polyester-rich blends, very little information is available on any systematic study on the effect of blend composition. Puttachaiyong IS used various blends of polyester (38 mm, 2.2 dtex) and combed cotton to determine the influence or cotton content on yarn quality. Typical results are shown in Fig.3 from which it may be observed that there is a rapid deterioration in yarn quality with increasing cotton content. A further feature which was also c1eariy evident from the results obtained in this research was that the yarn properties also appear to be count dependent.
3 Influence of Fibre Properties on the Quality of Cotton Yarns
The results obtained from blended yarns indicate that thereis a clear reduction in quality when spinning cotton . It was considered that this is due to 'deficiencies' in the properties of cotton as a raw material for jet spinning and it was believed to be worthwhile to investigate whether the type 0f cotton played a significant role in the properties of jet-spun yarns. Tembo l 7 assessed the properties of yarns produced from a range of cotton fibres, the properties of which are given in Table I.
16~------------------------'
12
10
8
6
4
2 ·
0 0
s- E .,. 0- U "I. v-gf/tex
25 50 75 Polyester content ,.,.
100
Fig. 3~Effect of polyester co ntent on the properties of po lyes ter/cotton yarns
With other spinning systems, such as ring and rotor, it would be expected that the quality of the fibre would be reflected in the quality of the resultant yarn (i.e. longer, finer fibres give the better yarns). It can, however, be observed from FigsA-6 that jet-spun
196
Staple length mm
27
30
32
34
38
45
INDIAN J. FIBRE TEXT. RES., DECEMBER 1992
Table I- Colton fib re properties Mic ronaire Matu re Fineness Matu rity Tenacit y E%
fib re dtex rat io g/d tex
><
6·0 V-'51~x 0- 20 I~x
5·5 ,,-30t~
5-0
4.4
3.8
4.4
4.5
3.7
3.0
%
68 .9
73.3
80.8
82.1
76.6
81.3
!! 4·5 .... z u 4{)
2'0
' ·5
,-o.~~~~~~~~~~~~~ ,·0 , ·2 ' -4 '-6 "8 2-0 2-2
Fi breo f i neon~ss I dteox
Fig.4-Effect of fib re fi neness on yarn tenacity
>< II -.... z u
>-'u " c II
c .. 0
>-
6 '0
5·5
5·0
4·5
4{)
3'5
3-0
V-15t~x a-20t~x 0-30teox
1 -0!:-:---=-a,-~"....-~,....--,.L,_-'-_~ 24 28 32 36 40 44 48
F i br~ l~ngth .mm
Fig.5- Effect of fib re length on yarn tenacity
2. 13
1.70
1.87
1. 84
1.55
1.1 2
.. II -.... z u
>-'u " c II
C .. " >
6·0
5-5
5-0
4·5
4·0
3-5
3'0
2·5
2'0
, ·5
0.78
0.82
0.9 1
0.93
0.86
0.92
1.8
2.74
2.59
2. 31
3.02
3.69
.-15 t~x Q-20 t~x 0-30 t~x
,-O.~~~~~~~~~~~~ '·6 2-0 2'4 2 -8 3-2 3-6 4-0
F i br~ str~ngth , g/dt~x
Fig.6---Effect of fibre strength on yarn strength
3.9
5.3
4.7
4.9
5.0
4.0
yarns fai l to exhibit the expected trends_ Indeed, none of the normal aspects associated with higher quality fibres appears to demonstrate any benefits to yarn qua lity and surprisingly it appears that for finer coun ts the yarn tenacity is higher when using coarser and shorter fi bres.
The influence of fi bre fi neness on yarn tenacity is para lleled by the effect of yarn count on tenacity, as shown in Fig. 7, since both of these factors are linked to the number of fi bres in the yarn cross-section. A probable explanation fo r this effect is that within a particular machinery design , the number of fi bres which can be classified as 'edge fibres' (and hence the potential number of wrapper fi bres) is fixed. Thus, for fi ner fibres and coarser yarns, the fraction of wrapper fi bres decreases and hence the yarn strength reduces. The magnitude of this effect must be balanced against any potential increase in strength normally associa ted with the use of higher quali ty fi bres, but from the current results it appears that. the influence of wrapper fibre fraction plays the dominant role. The effect offibre length can also be explained in terms of
OXENHAM : INFLUENCE OF FIBRE PROPERTIES IN AIR JET SPINNING 197
7r-----------------~--~
)(
" -..... 6
~ 5
?: u g.4 " c ... ~ 3
Material-lOa'" Collon Delivery speed,65ml min
2~~~ __ ~ __ -L __ ~ __ ~~ 8 10 12 14 16 18
Yarn count, tex
Fig.7-Effect of yam count on yam tenacity
the above mechanism since there is a correlation between the length and fineness of the fibres used and the effect of fibre length is probably a reflection of different fibre fineness.
4 Structure of Jet-spun YarllS and Its Effect on Yarn Properties
Whilst the structure of jet-spun yarns can be idealized as "a core of parallel fibres held together by wrapper fibres", there is a considerable variation in the structure along the yarn length. In particular, there are large variations in the number and type of wrapper fibres and it is thus impossible to assign a singular structure to jet-spun yarns. Several different classification systems have been applied to jet-spun yarns but in the most recent study into the effect of blend composition on yarn strength 18, the system suggested by Miao l4 was adopted.
The classification which was used to quantify the various structural components along the yarn length (Fig. 8) was:
Oass I : those parts of the yarn which have a regular helical wrapping and in which the core is crimped;
Class 2: those parts which have no wrapping fibres and possess the appearance of a low-twist ring-spun yarn;
Class 3 : those parts of the yarn which have a straight yarn core regularly bound with wrapper fibres; and
Class 4 : those parts of the yarn which have a straight yarn core bound by irregular wrapper fibres.
Analyses of many yarns were carried out 18 and a typical set of results, which was based on a random selection of 300 sections of yarn, is shown in Fig.9. It is apparent that the blend composition appears to have only a minor effect on the proportion of each class and
CLASS 4 .
C'i~angl. Numb« of Wl'app.n
~~" ~Cor.IWisl ang ..
Numb« of wraw ....
( ,_.of) WlOp~S Imm
Fig.8-Classification of yarn structure
60r---------------------------~
o 40 -0
-o CI> 01 o
~ 20 u Q; a..
r-
~
7 V V V V / /
r-
o Polyester
~ Pol yester I Co t ton ~ Collon
7 r- t,? V / V -
: / tV V V
~/ '~V 2 3 "
V O~~~~~~~-L~~~mLU--J
Classification of structure
Fig.9- Effect of fibre type on proportion of structural classes
whilst the polyester yarn has the highest percentage of Class I (which is claimed to have the greatest influence on yarn tenacity) this is only a marginal effect. If the various classes of structure are analyzed more closely it can be seen from Fig.l 0 that a major effect of fibre type is that it influences the length of the various classes and thus the polyester yarn has Class I wrappings which are twice the length of those found in the cotton yarn. It was considered that this aspect of structure was the most significant and in order to try to improve the strength of cotton yarns, attempts
198 INDIAN 1. FIBRE TEXT. RES., DECEMBER 1992
E E -1/1 1/1 C -u
'0 .s:::.
01 c: GI
GI 01 C .... GI > 4:
z u
20 r- D Polyester
mJ Po.lyester/Cot ton
r.'! m Cotton
.
10
0
" ~ r-
. ~ r-
11 r-
:~ ~ II ~ 'j r/,-,-- rLL-L 2 3
Classification of structure
Fig.IO-Effect of fibre type on class length
10 v- 9 tex 8-15 tex 0-20 'tex
6
;. 6 u o c
.2! c 4 L-
o >
2·
o 1.·~0~--------~1.~5----------5~0 Nozzle angle,deg
Fig. II - Effect of nozzle angle on cotton ya rn tenacity
were made at increasing the number and ex tent of the Class 1 wrappers by introducing modifica tions to the jet design .
The angle of the nozzle in an air jet twister consists of two components which a re: tangentia l to the yarn in o rder to genera te twist; and axia l to the yarn in order to suck fibres into the system. It was considered to be appropria te to modify the latter component of the second jet since it was believed that this could resul t in improved wrapper fibres. Fig.1 1 gives a
summary of typical results obtained when spinning a long cotton (45 mm/ 1.25 dtex) using different nozzle angles. The most noticeable feature of this figure is the large role played by yarn count and whilst, in general, improvements in tenacity accompany an increase in nozzle angle this is more pronounced for the finest yam. Indeed, for the finest yam it was possible to
achieve tenacity > 10 cN/tex which is similar to figures claimed by other workers J 2 but at coarser counts it was impossible to achieve half this figure .
Structural analyses of yams revealed that the use of a second jet orifice angle of 50° led to an increase in both the number and extent of the Class I wrappings. Typical results for a 15 tex yam showed a change from 50% proportion of Class 1 to 67.5% Class I as the nozzle angle increased from 45" to 50°. This was accompanied by an increase in the average wrapping length from 8.12 mm to 10.7 mm. Trials were carried out with other nozzle angles but it was found impossible to spin at a nozzle angle of 35", and increasing the nozzle angle above 50° produced a drastic reduction in ya rn tenacity.
Other modifica tions to jet designs were also tried but these followed the general trend obtained above in that the greatest effects were achieved with fine yarns and at yarn counts coarser than 15 tex the improvements were only ma rginal.
Attempts were made to correlate yarn properties to fibre properties using data obtained from trials with different types of cotton, polyester and Tencel fibres. As in earlier trials 1 7, little correla tion could be found between the yarn tenacity and fibre length and fineness. A very good correlation was, however, established between yarn tenacity and fibre extension at break (correlation coefficient = 0.99). Whilst this may appear to be an unusual result, a recent paper20 has reported that, when working with modified polyesters, the most significant improvement in yarn tenacity of jet-spun yarns was achieved when usi ng fibres with higher extensi bility. Thi s aspect of fibre/yarn interaction could offer benefi ts for man-made fibres since their properties could perhaps be modified to suit a particular spinning system (e.g. higher extensibility fo r fibres to be used in jet spi nning) . Unfortunately, this approach offers very little promise for cotton where, fo r example, the fibre extensibility is relatively low and unlike for man-made fibres the properties cannot be readily modified.
5 Use of Air Jet Spinning for Producing Two-assembly Wound Yarns
There has been considerable interest in the recentl y introduced 'jet spin/assembly wind concept which
OXENHAM: INFUJENCE OF FIBRE PROPERTIES IN AIR JET SPINNING 199
produces an assembly wound package for subsequent two-folding. This, therefore, offers the potential for the higher speed production of yams for two-folding without the need for an additional assembly winding operation. A further potential advantage of the system is that the strength of the final yam may be influenced by the folding twist and this may compensate for deficiencies in the strength of the single yarns. This could provide greater opportunity for the use of fibres such as cotton, where the single jet-spun yarn is oflow strength. Whilst there is ver-y little data avai lable concerning the properties of yarns produced by this route, there have been claims that a further advantage of the system is that the level of folding twist which can be used is lower than that normally used for conventional ring-spun yarns21 .
The experimental spinning unit, used for earlier trials, was modified to enable two yarns to be spun simultaneously and these were wound together on a single package. Preliminary trials with polyester revealed that for the range of processing conditions used, the properties of the single yarn had very little effect on the tenacity of the folded yarn. A series of yarns were produced from polyester, cotton and Tencel fibres and these were folded with a range of folding twist factors and the results are summarised in Fig.12. It may be observed that whilst the level of folding twist has very little effect on the tenacity of the polyester and Tencel yarns, there is an improvement
40
35 ~ Polyesll"r(48 tex)
30
)(
~
z 25 u~ ~ ?: Teneel (30 lex) u a 20 c ~ c '-a > 15
51~5----------3~0~--------~45 Twisl factor, tex"2 turns/em
Fig. 12- Effect of folding twist factor on the tenacity of two-fold jet-spun ya rns
in cotton yam properties with increasing twist. The level of strength which is obtained for the cotton yam is, however, lower than that for the corresponding nng-spun yarn.
6 Conclusions Whilst jet spinning may produce acceptable yarns
from polyester-rich blends, it is apparent that jet-spun yarns produced from cotton possess very low tenacity.
Modifications in the design of certain critical components can afford improvements in the tenacity of cotton yarns, but the benefits are evident only for fine counts (about 10 tex) and the coarser yarns show very little improvement.
The most important fibre parameter affecting jet-spun yarn tenacity is the extensibility . Whilst this may offer a potential source of improvements in yarn quality produced from man-made fibres, it is possible that thi s may impose a limitation on the use of jet spinning for cotton fibres.
The use of jet spinning as a precursor to the production of two-fold yarns could offer several advantages. The current work has, however, indicated that for cotton, not only is the level of folding twist important in respect of yarn tenacity, but the two-fold product is weaker than its ring-spun equivalent.
Whilst jet spinning may still be regarded as a novel system, it has no doubt achieved considerable commercial success. This success is restricted to the processing of polyester-rich blends and there is no doubt that the system would gain much greater acceptance if it could produce cotton yarns of acceptable tensile properties. This has stimulated much research but to date thi s has failed to produce any development which can be used over a wide range of counts. There is no doubt that this research will continue since jet spinning offers the potential of high speed production which can be largely automated, but without the ability to process 100% cotton the application of the system will continue to be restricted .
Acknowledgement The author would like to gratefully acknowledge
the considerable efforts of postgraduate students who have provided the raw data for this review. He is also grateful to the various international agencies who have provided the necessary fund s for the studies.
References I Ibrahim S M & Barron E R. New ways to process tex tiles. Pmc,
Texl /nsl Anl1u Con/: 1972.2 17.
200 INDIAN J. FIBRE TEXT. RES., DECEMBER 1992
2 Oxenham W, Texl Asia, 15(2) (1984) 40. 3 Suessen PL Yfil 1000, Customer Information Pamphlet.
4 Te:oi/e Terms and De./inilions (The Textile Institute, Manchester) .
5 Miao M, Oxenham W & Grosberg p, J Chin Texf Univ, I (1987) 59.
6 Duessen H. Me/liand Texfi/ber Inf, 70(11) (1989) 815 .
7 Stalder H, Inl Tex t Bull, Yarn Forming , (I) (1988) 27.
8 Ka to H, J Texf Mach Soc Jpn , 32(4) (1986) 95 .
9 Artzt p, Melliand Textilber Inl, 70( 11 ) (1989) 821 (E 354). 10 Wang K Y & Jordan G, Me/liand Texfi/ber Inf (Eng Ed), 65(6)
(1984) 344.
II Wang X, J Te:o Res, 8(4) (1987) 227.
12 ArlZl P & Dallman H, Melliand TeXli/ber 1m (Eng Ed), 70(5 ) (1989) 131.
13 Looney F S, Me/liand Texli/her Inl (Eng Ed), 65(3) (1984) 164.
14 Miao M , The inserTion ollll'isf infO yarns hI' means orair jels, Ph D thesis, University of Leeds, 1986.
15 Puttachaiyong S, The properties oljel-spun ,fIo/resler/col/on yarns, M Sc disserta tion, University of Leeds, 1986.
16 Noor A, The lorsiona/ charaClerislics o(fihrous strands , Ph D thesis , University of Leeds, 1987.
17 Tembo A p, Air~iel spinning of' cOl/on , M Sc dissertation, University of Leeds, 1989.
18 Basu A, Inffuence o/fibre Iype on Ihe properlies ofje f-spun yarn, Ph D thesis, University of Leeds, 1991.
19 Miao M, Oxenham W & Grosberg P,J Texl {nsf , 78(3)( 1987) 189.
20 Santjer H J , Texl Asia, 22(2) (1991) 26. 21 Stahlecker H , Texl Techno/lnl, (1990) 97.