Uludağ University Journal of The Faculty of Engineering, Vol. 23, No. 3, 2018                     RESEARCH 
 
DOI:10.17482/uumfd.445916 
 
 
EFFECT OF WET LAUNDERING ON STRETCHING AND AIR 
PERMEABILITY PROPERTIES OF POLYESTER WARP 
KNITTED FABRICS WITH DIFFERENT FABRIC WEIGHTS 
 
 
 
 
*
Gizem KARAKAN GÜNAYDIN   
**
Erhan Kenan ÇEVEN  
 
 
Received: 19.07.2018 ; revised: 03.10.2018 ; accepted: 08.10.2018 
 
Abstract: Warp knitting technology combines the two properties of dimensional stability and elasticity 
which are provided from woven and knitted fabrics separately. These fabrics consist of several threads 
(warp) which are formed as loops via needles and run through the fabric mainly in a vertical direction. 
These fabrics may be produced on a flat or a circular warp knitting machines. This study aims to 
investigate the influence of washing cycles (1, 5 and 20) on stretching (%) and air permeability properties 
of the polyester warp knitted fabrics of different weight. In order to analyze the effect of washing process 
on stretching ratios (%) and air permeability of the samples; Fyrma fabric extensometer and SDL Atlas 
M021A model Air Permeability Tester devices were used respectively. Additionally, the changes in fabric 
weight according to washing cycles of 1, 5 and 20 were also evaluated. According to test results; the 
stretching properties and air permeability values of the polyester warp knitted fabrics produced in 
different weights varied according to the laundering cycle which emphasized that caring processes should 
also be considered during the evaluation of mechanical properties (such as stretching, air permeability 
properties) of polyester warp knitted fabrics.  
 
Keywords: warp knitting, polyester, stretching properties, air permeability, wet laundering 
 
Farklı Ağırlıklarda Üretilen Poliester Çözgülü Örme Kumaşların Uzama Ve Hava Geçirgenlik 
Özelliklerine Yıkamanın Etkisi 
Öz: Dokuma ve örme kumaşlardan ayrı ayrı sağlanan boyutsal stabilite ve elastikiyet özellikleri çözgülü 
örme teknolojisinde bir araya getirilmektedir. Bu kumaşlar dikey doğrultuda kumaş boyunca uzanan, 
iğneler vasıtasıyla ilmekler oluşturabilen çözgü ipliklerinden oluşmaktadır. Çözgülü örme kumaşlar düz 
ya da dairesel çözgülü örme makinelerinde üretilebilmektedir. Bu çalışma kapsamında yıkama işleminin 
(1, 5 ve 20 tekrar sayısında) farklı ağırlıklarda üretilen poliester çözgülü örme kumaşların uzama ve hava 
geçirgenlik özelliklerine etkisini incelenmesi amaçlanmaktadır. Bunun için sırasıyla, Fyrma kumaş 
ekstensiyometresi ve SDL Atlas M021A model hava geçirgenliği ölçüm cihazları kullanılmıştır. Ayrıca 1, 
5 ve 20 yıkama sayısı ile kumaş ağırlıklarındaki değişim değerlendirilmiştir. Yapılan testlere göre farklı 
ağırlıklarda üretilen poliester çözgülü örme kumaşlar, uzama ve hava geçirgenliği özellikleri bakımından 
yıkama tekrar sayısına göre değişiklik göstermiştir. Bu sonuç ise poliester çözgülü örme kumaşların 
mekanik özellikleri değerlendirilirken bakım işlemlerinin de göz önünde bulundurulması gerektiğini 
vurgulamaktadır.  
 
Anahtar Kelimeler: çözgülü örme, poliester, uzama özellikleri, hava geçirgenliği, yıkama  
 
                                                          
*   Pamukkale University, Buldan Vocational School, Fashion Design Department,20400, Buldan ,Denizli  
** Uludağ University, Faculty of Engineering, Textile Engineering Department, 16059, Nilüfer, Bursa, Turkey 
    Corresponding Author: Gizem KARAKAN GÜNAYDIN (ggunaydin@pau.edu.tr) 
61 
Günaydın G.K., Çeven E.K.: Effect of Wet Laundering on Stretching and Air Permeability Properties of 
Polyester Warp Knitted Fabrics with Different Fabric Weights 
 
1. INTRODUCTION 
 
Knitted textiles are made of stitches where the loops are intersecting one another. A stitch 
structure can be made of one yarn end (a weft knitted fabric) or it can be made of a sheet of 
parallel yarn ends (warp knitted fabric). Today warp knitted is defined as a loop forming process 
in which the yarn is fed into knitting zone, parallel to the fabric selvedge. In warp knitting, 
fabric is made by forming loops from yarns coming in parallel sheet form which run in the 
direction of fabric formation (like warp in weaving). Every needle is fed by a separate yarn in 
warp knitted machines where the yarns are shogged (shifted) between the needles. The new loop 
formed is drawn through the previous loop formed by the another yarn as the production 
principle. Number of guide bars in a machine is the same with the number of warp beams. The 
guides which are fitted on the guide bars are feeded with the yarns of equal number of each 
warp beam. Although yarns may vary in color and composition; all guides on the guide bar 
should provide same identical lapping motion with the same warp tension (Ray, 2011). Figure 1 
reveals the individual yarn guides set in a solid bar. The front-to-back movements are called 
swings. The first swing from front to back is followed by a lateral shog: the overlap, which 
wraps the yarn in the needle hook. The next movement is a swing from back to front followed 
by the underlap that may be from 0 to 8 needle spaces depending on the fabric structure being 
knitted (Spencer, 2001).  The loop can be closed or open in warp knitting. If the direction of the 
incoming thread (overlap) is the same as the direction of the outgoing thread (underlap), we call 
it an open loop. In case of opposite direction, we call it a closed loop. It is also essential to 
emphasize the preparation of warp beams from where large numbers of yarns in parallel sheet 
form are supplied. Warp knitting machines are flat and comparatively more complicated than 
weft knitting machines. Today tricot and Raschel warp knitting machines are the most 
frequently used ones. A stitch comb and knock-over comb bar in Raschel machines whereas a 
sinker bar is used in Tricot machines. Double-bar raschel machines are also used for producing 
three-dimensional textiles including spacer textiles. However, warp knitting have limited elastic 
properties in longitudinal directions which can only be improved by subsequent finishing. A 
few of the popular warp knitted structures are locknit, sharkskin, queens’cord, double atlas, 
velour etc. (Ray, 2011; Spencer, 2001).   
 
 
 
                                 
 
 
 
 
 
 
 
 
 
Figure 1: 
 Lapping movement of guide bar  (Spencer, 2001) 
 
It is important to select suitable materials and structures for warp knitted fabrics for 
ensuring the required comfort characteristics as well as with the tensile properties. In the 
commercial warp knitted products, polyester which provides a wide range of applications allows 
a quick response to the demands of the market. Those products may include upholstery fabrics, 
sportswear, coating substrates and velours produced with tricot machine and plush fabrics, 3D 
62 
Uludağ University Journal of The Faculty of Engineering, Vol. 23, No. 3, 2018       
spacer fabrics, nets and seamless articles produced with raschel machine 
(www.karlmayer.com/en/products/warp-knitting-machines, 2018). In the early literature, there 
are some studies related to influences of fabric production parameters on mechanical properties 
of the warp knitted fabrics. Abrasion resistance of warp knitted carpets were investigated for 
analysing the effect of pile yarn count, silicone resin and tuft density in Değirmenci’s study 
(2016). Chen et al. evaluated the comfort and abrasion properties of polyester warp knitted 
fabrics which reveal differential shrinkage (Chen et al., 2016).  Lee (2006) investigated the 
changes of pulling-out length and shrinkage ratio in polyester/spandex power net warp knitted 
fabrics. The researcher declared that as the treatment temperature increased, extensibility 
increased proportionally to the sample length. The shrinkage ratio (%) also increased in the wale 
and course direction so the pulling out length proportionally. Influence of fabric structure on 
stress relaxation of two bar warp knitted fabrics (reverse locknit, sharkskin, queens’cord) was 
evaluated in Hashemi et al.’s study (2016). The authors concluded that fabric structure was one 
of the important factor affecting the stress, stress relaxation percent of the fabric. Some 
researches related to special warp knitted fabrics for technical textiles applications have also 
been conducted (Blaga et al., 2013; Wang and Hu, 2014). Peled et al. searched the influence of 
different textile characteristics of the warp knitted fabrics made from multifilament yarns on 
tensile properties of textile reinforced cement elements and on the bonding quality between the 
fabrics and the cement matrix. Loop size, bundle size (number of filaments) and fiber type (high 
density, polyethylene, polypropylene, AR-glass and aramid) were investigated in order to 
evaluate the bond strengths with the cement matrix (Peled et al., 2008). Ye et al. (2007) made a 
study about the application of warp knitted spacer fabrics in car seats as a substitute for 
polyurethane foam as padding in car seats. The results revealed that relatively to polyurethane 
foam, warp knitted spacer fabrics indicated better recovery to compression, thermal properties 
and breathability as well as with the properties of easy recycling and keeping their original 
thickness for a longer period (Ye et al., 2007).  Liu et al.  (2012) presented a study of the impact 
compressive behavior of warp-knitted spacer fabrics which were developed for human body 
protections. It was declared that all structural parameters significantly affected impact 
compressive behavior of the warp knitted spacer fabrics in terms of peak contact force, peak 
transmitted force and energy absorbed at different impact compressive stages. A decrease of 
peak contact force about 33.16% was provided with the warp-knitted spacer fabrics. Yip and Ng 
(2008) investigated the physical and mechanical properties of the special “spacer fabrics” which 
are three dimensional knitting for industrial applications. The characteristics of different spacer 
fabrics including low-stress mechanical properties, air permeability and thermal conductivity 
were analyzed in the study. They concluded that tensile, bending and compression properties 
influenced from the fabric type (warp or weft knitting), spacer yarn used (monofilament or 
multifilament), spacer yarn configuration. Additionally, air permeability and thermal 
conductivity of spacer fabrics were found related with the fabric density as well (Yip and Ng, 
2008). 
Warp knitted fabrics have been studied in aspects for many years, however to the best of our 
knowledge; Very little research work has been done related to evaluation of washing effect on 
stretching ratios (%) and air permeability values of the warp knitted fabrics which are produced 
at different weights. Since the warp knitted textiles include textile products which may require 
caring processes; it was thought to be useful to consider the warp knitted polyester fabrics’ 
stretching ratios (%) with the washing effect within this study. Additionally, air permeability 
properties of the samples were also evaluated in order to have some idea about their 
breathability features 
 
 
 
 
63 
Günaydın G.K., Çeven E.K.: Effect of Wet Laundering on Stretching and Air Permeability Properties of 
Polyester Warp Knitted Fabrics with Different Fabric Weights 
2. MATERIAL METHOD 
In order to evaluate the influence of washing process on stretching ratios (%) and air 
permeability properties of polyester warp knitted fabrics produced in different weights; Warp 
knitted fabrics were produced on Karl Mayer HKS 3 model Tricot warp knitting machine 
(Figure 2) by using three guide bars. Polyester yarns with different yarn linear densities were 
fed to the guide bars according to experimental design indicated in Table 1. After the relaxation 
process of the warp knitted fabrics, the 50x50 cm samples were exposed to laundering cycles of 
1, 5 and 20 at 30° C by using the 5.85 gram 3.94 gram and 1.98 gram standard reference 
detergent respectively (ISO 6330, 2012).  Home drying process was applied for 40 minutes after 
each washing cycle.  Before the measurements, all fabric samples were conditioned for 24 hours 
in standard atmospheric conditions (at a temperature of 20 ± 2 °C and relative humidity of 65 ± 
2%).  
Table 1. Experimental design of the study 
 Fabric Number 
 Fabric   Yarn Yarn 
stitch type: 2 x 1 weight of yarn 
Fabric Appearance Code 2 *wpc *cpc count Type open lap (tuch) (g/m ) guide 
   
2 Guide 
  75 Denier 
Bar Polyester 
   /36 fil  
  
B 
174   75 
8 8 1Guide Denier/34 Polyester 
 Bar  fil 
   
  75 Denier 
   2 Guide Polyester /30 fil 
W1  Bar 
 128 8  
6 75 1 Guide 
Denier/36 Polyester 
Bar 
 fil  
    2 Guide 50  
 Bar Denier Polyester 
108 10   /24 fil 
10 
W2 
75 
1Guide 
Denier/36 Polyester 
Bar 
 fil  
 
                                                *wpc: wale per cm  *cpc: course per cm 
 
 
Figure 2: 
Karl Mayer HKS 3 warp knitting machine 
 
The extensibility of the warp knitted fabrics was tested in both wale and course direction, 
using a Fryma Fabric Extensometer under a 30 N tensile force which is considered to be in the 
range of the regular strain (Figure 3). Fyrma fabric extensometer is a stretch testing instrument 
for determining the stretching ratio (%), permanent stretching ratio (%) and elastic recovery 
properties according to test standard of BS 14704 (BS 14704, 2005). The specimens were 
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Uludağ University Journal of The Faculty of Engineering, Vol. 23, No. 3, 2018       
prepared so that they would be (85±1.0) mm in longitudinal and (75±1.0) mm wide wise. 
Stretching tests were evaluated for the non-washed warp knitted fabrics, for the warp knitted 
fabrics applied to 1 washing cycle, for the warp knitted fabrics applied to 5 washing cycles and 
for the warp knitted fabrics applied to 20 washing cycles.  
 
 
 
 
 
 
 
 
 
 
  
 
 
 
 
 
 
 
 
  
Figure 3: 
 FRYMA Fabric Extensometer Device (SDL Atlas) 
 
Stretching ratio (%) is described as the ratio of extension of the test specimen to its initial 
length expressed as a percentage (%). In the Fryma fabric extensometer device, the test 
specimens (85x75 mm) were subjected to 5 cycling between gauge length and the required force 
of 3kg by using cross-head in motion.  The stretching ratios (%) were recorded after ten seconds 
according to equation 1.  
𝐸−𝐿  
                                         S=    
𝐿 (1) 
th
where E: is the extension (mm) at maximum force on the 5  cycle 
           L: is the initial length  (mm) 
For the permanent stretching calculation; the specimens were marked 5 mm inside the short 
edge of the fabric and a 3 kg of load was applied for 2 hours. At the end of 2 hours, the fabrics 
were exposed to relaxation for one minute and the permanent stretching was calculated. For the 
warp knitted fabrics, the permanent stretching percentage shouldn’t be more than 3 %; For 
obtaining the elastic recovery ratios (%), the fabrics exposed to permanent stretching test were 
released for 30 minutes and the shortening distance of marked points were calculated.  
Warp knitted polyester fabrics were also measured for their air permeability (mm/s) by 
using SDL Atlas Digital Air Permeability Tester Model M 021A which was provided from 
textile laboratory of Textile Engineering Department in Uludağ University. The air permeability 
2
values of the fabrics were measured in a 20 cm  test area at 100 Pa air pressure according to EN 
ISO 9237:1997 standard. Five different areas from the front of each fabric were measured for 
the air permeability test. The air permeability (mm/s) was determined as follows (EN ISO 9237, 
1995): 
?̅?
𝑅 = ( 𝑣) . 167                                                      (2) 
𝐴
65 
Günaydın G.K., Çeven E.K.: Effect of Wet Laundering on Stretching and Air Permeability Properties of 
Polyester Warp Knitted Fabrics with Different Fabric Weights 
where: ?̅? 3 2𝑣 : an arithmetical average of the debit of air flow ,dm /min; A: Test area, cm ; and 
3 3
167: coefficient of conversation from dm /min to cm /s and then from cm/s to mm/s. Results 
were expressed as “mm/s” 
 
3. RESULTS&DISCUSSION 
2
3.1. Fabric Weight (g/m ) 
160
140
120
100 non-washed
80 1st washing cycle
5th washing cycle
60
20th washingcycle
40
20
0
B W1 W2
 
Figure 4: 
2
Weight of the warp knitted fabrics (g/m ) versus washing cycles  
 
Figure 4 reveals the change in knitted fabrics’ weight regarding to washing cycles. As it is 
expected, B”, “W1” and “W2” knitted fabrics revealed an increasing trend for the fabric weights 
with the washing cycle without depending on their structural parameters. “B” coded knitted 
2
fabrics revealed the highest fabric weights (g/m ) where “W2” and “W1” coded knitted fabrics 
followed it mannerly. 
3.2. Stretching Ratios (%) 
 
140
120
100
non-washed
80
1st washing cycle
60 5th washing cycle
40 20th washing cycle
20
0
B W1 W2
 
Figure 5: 
Stretching ratio (%) in wale direction (after 10 seconds) 
66 
stretching ratio (%)  in wale direction Fabric weight (gr/m2) 
Uludağ University Journal of The Faculty of Engineering, Vol. 23, No. 3, 2018       
 
Figure 5 indicates the stretching ratio (%) in wale direction (after 10 seconds). Considering 
2
the “B” samples which have the highest fabric weight (g/m ), maximum value was obtained in 
the samples treated to 5 washing cycle as 64 % whereas the lowest values were found among 
the non-washed and the samples treated to 20 washing cycle as the same value of 25 % among 
the “B” coded fabrics. The non-washed samples revealed a prominent high stretching ratio (%) 
st
as “130” comparing to others whereas the samples treated to 1  washing cycle and treated to 5 
washing cycle revealed the lowest values among the “W1” samples of medium weight. When it 
2
comes to “W2” coded fabrics of the lowest weight (g/m ), maximum stretching ratio (%) was 
st
obtained from non-washed warp knitting fabrics as 53 % whereas the samples treated to 1  
washing cycle indicated the lowest value as 33 %.  
 
120
100
80
non-washed
60 1st washing cycle
5th washing cycle
40 20th washing cycle
20
0
B W1 W2
 
Figure 6: 
Stretching ratio (%) in course direction (after 10 seconds) 
 
Stretching ratio (%) in course direction (after 10 seconds) is indicated in figure 6. Among 
2
the “B” coded fabrics with highest fabric weight (g/m ); maximum stretching ratio (%) was 
th
obtained from 20  washing cycle as 74.5 % whereas minimum stretching ratio % was found in 
st th
the samples treated to 1  washing cycle as 29 %. The samples treated to 5  washing cycle and 
non-washed samples follow it from lowest to highest. Considering “W1” coded warp knitted 
2
fabrics of medium weight (g/m ); Non-washed and samples treated to 20 washing cycle 
revealed the same stretching ratio (%) in course direction as a maximum value whereas the 
st
samples treated to “1 ” washing cycle indicated the lowest value as 33%. When it comes to 
“W2” coded fabrics of the lowest weight, the highest stretching ratio (%) in course direction 
was obtained from samples to treated 20 washing cycle as 48 % whereas the lowest value (%)  
was found among the non-washed samples as 34.5 %.  
According to Figure 7; the highest permanent stretching ratios in wale direction was found 
th
in the 5  washing cycle among all “B, W1 and W2” coded fabric groups. Considering the “B” 
coded knitted samples of the highest fabric weight; Maximum permanent stretching (%) was 
th
obtained from the samples treated to 5  washing cycle whereas the lowest stretching ratio (%) 
st
was found among the fabric groups of non-washed and subjected to 1  washing cycle as 1.29 %. 
st
Considering “W1” fabric groups of medium weight; the non-washed, treated to 1  washing 
th
cycle and treated to 20  washing cycle fabric samples all revealed the same permanent 
stretching ratio (%) as 1.29. When it comes to “W2” coded fabric groups of lowest fabric 
67 
stretching ratio (%) in course direction 
Günaydın G.K., Çeven E.K.: Effect of Wet Laundering on Stretching and Air Permeability Properties of 
Polyester Warp Knitted Fabrics with Different Fabric Weights 
st
weight; Non-washed, subjected to 20 washing cycle and subjected to 1  washing cycle samples 
th
followed the highest permanent stretching (%) indicating fabric groups (treated to 5  washing 
cycle) orderly. 
 
12
10
8
non-washed
6 1st washing cycle
5th washing cycle
4 20th washing cycle
2
0
B W1 W2
 
Figure 7:  
Permanent stretching (%) in wale direction  
  
14
12
10
non-washed
8
1st washing cycle
6 5th washing cycle
20th washing cycle
4
2
0
B W1 W2
 
Figure 8: 
Permanent stretching (%) in course direction 
 Figure 8 indicates the permanent stretching ratios (%) in course direction. Considering “B” 
coded fabrics of maximum fabric weight; the highest values were obtained from the samples 
subjected to “20” washing cycle as 6.49 % whereas the lowest values were found among the 
warp knitted samples subjected to “1” and “5” washing cycles as 1.94 %. When it comes to W1 
coded samples; the highest permanent stretching ratios (%) were found among the fabric groups 
th
of non-washed and which are treated to 20  washing cycle as 10.3 % whereas the lowest value 
was found among the samples subjected to 5 washing cycle as 1.29 %. Considering “W2” fabric 
68 
permenant stretching (%) in course Permenant stretching (%) in wale 
direction direciton 
Uludağ University Journal of The Faculty of Engineering, Vol. 23, No. 3, 2018       
samples of lowest weight; the highest permanent stretching (%) was obtained from the samples 
st
subjected to 1  washing cycle whereas the lowest value was found among the samples treated to 
 
5 washing cycle.   
9
8
7
6
non-washed
5
1st washing cycle
4 5th washing cycle
3 20th washing cycle
2
1
0
B W1 W2
 
Figure 9: 
 Elastic recovery (%) in wale direction 
According to figure 9, the highest elastic recovery (%) in wale direction was found in the 
samples treated to 20 washing cycle whereas the lowest value was found in the samples treated 
to 5 washing cycle among the “B” and “W1” coded fabric groups which have the highest and 
2
medium fabric weight (g/m ) respectively. When it comes to “W2” coded fabric samples of 
lowest weight; the highest elastic recovery (%) was found in the non-washed and treated to 20 
washing cycle samples as 3.89 % again whereas the lowest value belonged to samples treated to 
st
1  and 5 washing cycle as 0.64 %.  
9
8
7
6
non-washed
5
1st washing cycle
4 5th washing cycle
3 20th washing cycle
2
1
0
B W1 W2
 
Figure 10:  
Elastic recovery (%) in course direction 
69 
elastic recovery (%) in wale direction  
elastic recovery in course direction (%) 
Günaydın G.K., Çeven E.K.: Effect of Wet Laundering on Stretching and Air Permeability Properties of 
Polyester Warp Knitted Fabrics with Different Fabric Weights 
Figure 10 indicates the elastic recovery (%) of the samples in course direction. As a general 
trend; “B” coded warp knitted fabrics of highest weight indicated lower values comparing to 
“W1” and “W2” coded fabrics for all washing cycles. There was not any prominent change in 
elastic recovery (%) in course direction for the washing cycles among “B” coded knitted fabrics 
however the samples treated to “5” washing cycle indicated slightly lower values. Considering 
“W1” coded fabrics of medium weight; non-washed samples revealed the highest ratio as 7.79 
th 
% whereas the samples subjected to 5 washing cycle indicated the lowest elastic recovery (%) 
as 0.56 % in course direction. When it comes to “W2” coded fabric groups of lowest weight; the 
st 
highest recovery ratio (%) was found in the samples treated to 1 washing cycle as 7.14 %. The 
non-washed samples and the samples treated to 5 washing cycle indicated the same recovery 
ratio (%) as 6.49 % whereas the samples treated to 20 washing cycle followed them as 5.49 %.   
3.3. Air permeability  
Figure 11 indicates the air permeability (mm/s) of the warp knitted fabrics. Non-washed 
warp knitted samples revealed the highest air permeability (mm/s) values among all fabric 
groups. Considering “B” coded samples of highest weight; fabric groups treated to 20 washing 
cycles, fabric groups treated to 5 washing cycle and fabric groups treated to 1 washing cycle 
followed non-washed samples with maximum air permeability values orderly. When “W1” 
fabric groups are considered, non-washed samples revealed the highest air permeability (mm/s) 
st
values whereas the samples subjected to 1  washing cycle indicated the lowest value. When it 
st
comes to “W2” coded samples of lowest weight, the samples treated to 1  washing cycle 
indicated the minimum air permeability (mm/s) where the non-washed samples revealed the 
highest air permeability (mm/s) values.  
 
3000
2500
2000
non-washed
1500 1st washing cycle
5th washing cycle
1000 20th washing cycle
500
0
B W1 W2
 
Figure 11:  
Air permeability (mm/s) 
 
 
 
 
70 
air pemeability (mm/s) 
Uludağ University Journal of The Faculty of Engineering, Vol. 23, No. 3, 2018       
4. CONCLUSION 
According to subjected tests and the evaluations; it should be emphasized that laundering 
effect should be considered for the warp knitting fabrics’ stretching (%) and air permeability 
2
values (mm/s). Warp knitted samples’ fabric weight (g/m ) revealed an increasing trend with the 
washing cycles among “B”, “W1” and “W2” coded knitted fabrics. Maximum stretching ratios 
(%) after 10 seconds in wale direction was found in the non-washed “W1” coded fabrics of 
th
medium weight. Samples treated to 20  washing cycle indicated the maximum stretching ratio 
(%) after 10 seconds in course direction among all fabric groups of different weight. The highest 
th
permanent stretching ratios (%) in wale direction was found in the fabric samples treated to 5  
th
washing cycles. However, all fabric groups treated to 5  washing cycles indicated the lowest 
values for the permanent stretching ratios (%) in course direction. The highest elastic recovery 
th
(%) in wale direction was found among the samples treated to 20  washing cycle among “B”, 
2
“W1” and “W2” knitted fabrics. Non-washed “W1” samples of medium fabric weight (g/m ) 
indicated higher elastic recovery (%) in course direction prominently. “B” coded warp knitting 
samples of highest weight indicated the lowest elastic recovery values (%) when compared with 
the other fabric groups. Finally, regarding to air permeability; Non-washed warp knitted 
samples revealed the highest air permeability (mm/s) values among all fabric groups of “B, W1 
st
and W2” whereas the samples treated to 1  washing cycle indicated the lowest values (mm/s) 
Disclaimer 
Mention of trade names or commercial products in this manuscript is solely for the 
purpose of providing specific information and does not imply recommendation or 
endorsement. 
Acknowledgement 
 The authors wish to express their thanks to Emre AKDEMİR ,Ahmet GÜLER and İlker 
SERİNDAĞ for their contributions to the study. 
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