Journal of Textile Research ›› 2024, Vol. 45 ›› Issue (01): 90-98.doi: 10.13475/j.fzxb.20221006301

• Textile Engineering • Previous Articles     Next Articles

Thermal and moisture comfort of polybutylene terephthalate/polyethylene terephthalate weft-knitted sports T-shirt fabrics

YAO Chenxi, WAN Ailan()   

  1. Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Jiangsu, Wuxi 214122, China
  • Received:2022-10-31 Revised:2023-08-04 Online:2024-01-15 Published:2024-03-14

Abstract:

Objective Leisure, sports, and fitness have become a life fashion. Increasing number of people participate in sports and fitness, and as a result people's requirements for sports and leisure clothing fabrics are gradually changing. Lightweight, permeable, soft, and comfortable sports fabrics with features such as diverse styles, environmental friendliness, and health benefit are favored by consumers. As people pay more attention to human health and comfort, textiles with thermal and moisture comfort performance have gained attention in the global market, and attracted research attention. The wearing comfort is largely affected by the thermal and moisture comfort performance of the fabric. Air permeability, moisture permeability, thermal resistance, water evaporation rate, and liquid moisture management ability are considered to be the key factors affecting the wearer's thermal and moisture comfort performance.

Method In order to study the thermal and moisture comfort performance of sports and leisure T-shirt materials, 13 kinds of polybutylene terephthalate/polyethylene terephthalate(PBT/PET) weft knitted sports T-shirt fabrics with different structure parameters were developed. By using a fabricair permeability tester, fabric moisture permeability tester, thermal resistance, moisture resistance tester, and liquid moisture management tester, five indexes of the polybutylene terephthalate/polyethylene terephthalate 13 kinds of PBT/PET weft knitted sports T-shirt fabrics, which are air permeability, moisture permeability, thermal resistance, moisture evaporation rate, and liquid moisture management ability, were tested. The influences of fabric structure and monofilament size on fabric thickness, surface density, porosity, and thermal and moisture comfort performance were investigated. The thermal and moisture comfort performance of 13 kinds of weft knitted single-side knitted fabrics was evaluated through gray cluster analysis based on five individual indexes.

Results Using SPSS statistical software to conduct a one-way analysis of variance and correlation score, it was found that fabric structure and raw material monofilament size affected fabric porosity, and the correlation coefficients were 0.831 and 0.757 (p<0.05), respectively. Fabric thickness and surface density were also important factors affecting the porosity. The correlation coefficients were -0.768 and -0.710 (p<0.05). The microstructure and filament size were also found to affect the fabric's porosity, thickness, and surface density, and then affect the fabric's thermal and wet comfort properties such as air permeability, moisture permeability, thermal resistance, water evaporation rate, and liquid water management ability. The fabric structure was significantly correlated with the fabric's air permeability, moisture permeability, and thermal resistance, and the correlation coefficients were 0.783, 0.631, and 0.684, respectively. The thickness of fabrics was significantly correlated with the moisture permeability and thermal resistance of the fabrics, and the correlation coefficients were 0.771 and 0.761, respectively. The air permeability, water evaporation rate, and overall water management ability of fabrics were significantly correlated with the monofilament size, and the correlation coefficients were 0.544, -0.628, and 0.692, respectively. The porosity of fabrics was significantly correlated with the air permeability, thermal resistance, and overall water management ability of the fabrics, and the correlation coefficients were 0.654, 0.748, and 0.735, respectively. The surface density of fabrics was significantly correlated with the air permeability and overall water management ability of the fabrics, and the correlation coefficients were -0.688 and 0.709, respectively.

Conclusion The gray cluster analysis was adopeed to comprehensively evaluate the thermal and moisture comfort performance of the 13 weft knitted sports T-shirt fabrics, and it was concluded that the single-sided weft knitted sports T-shirt fabrics with single jersay, jacquard (1) and single-bead mesh had better thermal and moisture comfort performance, which was more suitable for the sports and leisure field.

Key words: weft-knitted single sports T-shirt fabric, thermal and moisture comfort, air permeability, moisture permeability, polybutylene terephthalate/polyethylene terephthalate fiber

CLC Number: 

  • TS186.2

Fig.1

Fabric weaving diagram. (a) Plain stitch; (b) Pique; (c) Lacoste; (d) Jacquard (1); (e) Pearl net; (f) Jacquard (2); (g) Jacquard (3); (h) Plain weave + half cardigan"

Tab.1

Basic specification parameters of fabrics"

织物
编号
织物组织 原料 单丝线密度/
tex
面密度/
(g·m-2)
厚度/mm 孔隙率/% 线圈密度/(线圈·(5 cm)-1)
纵密 横密
1# 平纹 8.89 tex(60 f) 0.15 112 0.43 80.7 100 170
2# 单珠地 8.89 tex(60 f) 0.15 123 0.47 80.6 90 190
3# 双珠地 8.89 tex(60 f) 0.15 109 0.62 87.0 100 150
4# 平纹 8.89 tex(96 f) 0.09 139 0.45 77.1 85 120
5# 平纹 8.89 tex(96 f) 0.09 112 0.46 82.0 85 115
6# 单面提花(1) 8.89 tex(96 f) 0.09 122 0.55 83.6 80 115
7# 单面提花(1) 8.89 tex(96 f) 0.09 121 0.52 82.8 85 115
8# 单面提花(2) 8.89 tex(96 f) 0.09 126 0.58 83.9 85 115
9# 单面提花(3) 8.89 tex(96 f) 0.09 141 0.49 78.7 100 110
10# 平纹+珠地(1) 8.89 tex(168 f) 0.05 148 0.41 73.3 130 180
11# 平纹+珠地(2) 8.89 tex(168 f) 0.05 142 0.43 75.5 125 200
12# 平纹+珠地(3) 8.89 tex(168 f) 0.05 146 0.42 74.3 130 180
13# 珠地+网眼 8.89 tex(168 f) 0.05 167 0.60 79.4 125 210

Fig.2

Air permeability of fabric"

Fig.3

Moisture permeability of fabrics"

Fig.4

Thermal resistance values of fabrics"

Fig.5

Moisture evaporation rates of fabric"

Tab.2

MMT test results"

织物编号 浸水面(T)与
渗透面(B)
浸湿时间/
s
吸水速率/
(%·s-1)
最大浸湿半径/
mm
液态水扩散速度/
(mm·s-1)
单向传递指数/
%
OMMC值
1# T 3.86 96.80 18.0 4.02 152.82 0.66
B 0.33 77.70 21.5 15.93
2# T 13.30 30.63 16.5 6.50 889.28 0.94
B 0.29 128.87 17.0 16.54
3# T 2.71 85.75 21.5 5.34 584.29 0.97
B 0.29 499.17 21.5 17.22
4# T 2.18 51.55 25.0 5.63 765.10 0.90
B 0.31 62.43 25.5 16.55
5# T 2.14 54.65 25.0 7.17 601.78 0.89
B 0.30 58.80 25.0 16.98
6# T 2.67 52.36 22.0 4.94 616.00 0.88
B 0.28 57.87 21.0 16.92
7# T 2.32 55.97 23.5 5.27 596.61 0.88
B 0.31 58.27 23.0 16.32
8# T 2.95 50.39 20.5 4.21 722.86 0.89
B 0.31 59.76 20.5 15.39
9# T 2.75 52.51 21.5 4.78 636.59 0.88
B 0.32 56.05 21.0 15.36
10# T 2.40 83.17 27.5 5.72 -11.43 0.48
B 0.31 78.44 26.0 17.79
11# T 2.47 97.40 28.5 5.70 -71.15 0.45
B 0.31 78.83 25.5 17.57
12# T 2.68 96.14 27.0 5.37 -94.84 0.45
B 0.29 80.72 25.5 18.10
13# T 2.83 95.13 24.0 4.55 -78.17 0.44
B 0.30 72.09 24.5 17.10

Fig.6

OMMC of fabrics"

[1] SENTHILKUMAR P, SRIDHARAN G. Recent development in textile for sportswear application[J]. Esrsa Publications, 2016, 44(8): 283-288.
[2] 孙岑文捷, 倪军, 张昭华, 等. 针织运动服的通风设计与热湿舒适性评价[J]. 纺织学报, 2020, 41(11):122-127,135.
SUN Cenwenjie, NI Jun, ZHANG Zhaohua, et al. Knitted sportswear ventilation design and the thermal comfort evaluation[J]. Journal of Textile Research, 2020, 41 (11): 122-127, 135.
[3] DI Domenico I, HOFFMANN S M, COLLINS P K. The role of sports clothing in thermoregulation, comfort, and performance during exercise in the heat: a narrative review[J]. Sports Medicine-Open, 2022, 8(1): 1-25.
doi: 10.1186/s40798-021-00382-y
[4] DAS A, ALAGIRUSAMY R, KUMAR P. Study of heat transfer through multilayer clothing assemblies: a theoretical prediction[J]. AUTEX Research Journal, 2011, 11(2): 54-60.
doi: 10.1515/aut-2011-110205
[5] ÖZDİL N, ANAND S. Recent developments in textile materials and products used for activewear and sportswear[J]. Electronic Journal of Vehicle Technologies, 2014, 8: 68-83.
[6] GAO S, CUI Y, YAO W, et al. Analysis of thermal and wet comfort properties of hygroscopic and exothermic knitted fabrics[J]. Textile Research Journal 2022, 92(13/14): 2327-2339.
doi: 10.1177/00405175221076030
[7] LEI Z. Review of application of thermal manikin in evaluation on thermal and moisture comfort of clothing[J]. Journal of Engineered Fibers and Fabrics, 2019, 14: 1-10.
[8] CHEN Q, TANG K P M, MA P, et al. Thermophysiological comfort properties of polyester weft-knitted fabrics for sports T-shirt[J]. The Journal of the Textile Institute, 2017, 108(8): 1421-1429.
doi: 10.1080/00405000.2016.1255122
[9] TEYEME Y, MALENGIER B, TESFAYE T, et al. Comparative analysis of thermophysiological comfort-related properties of elastic knitted fabrics for cycling sportswear[J]. Materials, 2020. DOI:10.3390/ma13184024.
[10] KUMAR C B S, KUMAR B S. Study on thermal comfort properties of Eri silk knitted fabrics for sportswear application[J]. Journal of Natural Fibers, 2021, 19(14): 1-12.
doi: 10.1080/15440478.2020.1726247
[11] 钱娟, 谢婷, 张佩华, 等. 聚乙烯针织物的热湿舒适性能[J]. 纺织学报, 2022, 43(7):60-66.
QIAN Juan, XIE Ting, ZHANG Peihua, et al. Thermal and wet comfort properties of polyethylene knitted fabrics[J]. Journal of Textile Research, 2022, 43(7): 60-66.
doi: 10.1177/004051757304300111
[12] KADOGLU H, DIMITROVSKI K, MARMARAL A, et al. Investigation of elasticised woven fabric characteristics using PBT filament yarns[J]. AUTEX Research Journal, 2016, 16(2): 109-117.
doi: 10.1515/aut-2015-0025
[13] ZUPIN Ž, DIMITROVSKI K, HLADNIK A, et al. Elongation properties of woven fabrics with incorporated PBT yarns[J]. The Journal of The Textile Institute, 2022, 113(5): 846-856.
doi: 10.1080/00405000.2021.1907971
[14] 陈晴, 冒海文, 马丕波, 等. PBT和PET交织经编织物的染整工艺对织物弹性的影响[J]. 纺织导报, 2018(1):55-58.
CHEN Qing, MAO Haiwen, MA Pibo, et al. Effect of dyeing and finishing process of PBT and PET interwoven warp knitted fabrics on fabric elasticity [ J ]. China Textile Leader, 2018 (1): 55-58.
[15] TIAN J, YU B, YU D, et al. Missing data analyses: a hybrid multiple imputation algorithm using gray system theory and entropy based on clustering[J]. Applied Intelligence, 2014, 40(2): 376-388.
doi: 10.1007/s10489-013-0469-x
[16] 王厉冰, 胡心怡, 齐素祯. 灰色聚类分析在纺织材料性能综合评价中的应用[J]. 天津工业大学学报, 2006, 25(3):23-26.
WANG Libing, HU Xinyi, QI Suzhen. Application of grey cluster analysis in comprehensive evaluation of textile material properties[J]. Journal of Tianjin Polytechnic University, 2006, 25(3):23-26.
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