基于仿生结构的抗菌无缝瑜伽服研发及其热湿舒适性

doi:10.13475/j.fzxb.20250103501

Abstract

Abstract:

Objective Because yoga clothing is close to the body and has limited air permeability, it is difficult for the material to transfer sweat. The warm and humid environment provides suitable conditions for bacterial growth. However, there are few studies on the bionic structure and antibacterial properties of yoga clothing. This research aims to develop antibacterial yoga clothing with functional divisions based on bioinspired structures.

Method Seamless yoga clothing was prepared with functional divisions using antibacterial spandex added with Ag⁺ as raw material. Fifteen types of single guide wet fabrics were designed based on the stems and leaves of Dishgyi. The effects of fabric structure, yarn type, thickness and hydrophobicity on antibacterial properties, thermal-moisture comfort and fabric density were discussed with five indexes of elastic recovery rate, air permeability, moisture permeability, thermal resistance and liquid water management ability as the research objects. According to the principle of ergonomics, a yoga clothing with functional divisions was designed, and its antibacterial and thermal properties were characterized.

Results 15 fabrics were woven based on bionic Dishgyi. Among them, the first twelve were used for the project vests, and the last three were benchmarck samples used for comparison. All the comparison samples were of weft flat needle structure. The test showed that the elastic recovery of the hexagonal convex-concave structure of the fabric was the best, which was up to 86.32%, and the air permeability of the strip-strip fabric sample was as high as 596 mm/s. The moisture permeability of 1+1 false rib-wavy honeycomb fabric sample was up to 7 870 g/(m²·d), the weft flat stitch 1×1 strip structure had the lowest thermal resistance and excellent heat dissipation, and the hexagonal convex and concave structure had the best water management ability. These highly distinctive fabrics were used to form various parts of the functional modular yoga wear. For example, in the shoulder area, the elastic misaligned striped-checkered structure was selected, and for areas prone to sweating on the chest and back, 1+1 false ribbed-wavy honeycomb tissue with good breathability, moisture permeability and strong water management ability were selected. A seamless yoga clothing with a single guide wet performance was compared with an ordinary yoga clothing. Participants wearing a seamless exercise yoga vest were asked to run on a treadmill for 15 minutes, and then to be stationary for 5, 10 and 15 minutes. Antibacterial tests were carried out on the chest and back center which were the most sweaty areas. The seamless exercise yoga vest made of silver ion antibacterial spandex and hydrophobic nylon showed good overall antibacterial performance. With the increase of resting time, the antibacterial rate continues to increase, and the number of colonies increased from an average of 15 after 5 minutes of resting to 0 after 15 minutes of resting. The subject wore a seamless exercise yoga vest, jogged on the treadmill for 15 minutes, and then stood still for 15 minutes. The infrared imager recorded the temperature change of the human body surface, and stood still before pre-running. The red area of the subject vest was almost twice less than that of the control vest. With the increase of resting time, the red area decreases and the subject vest descended faster. The temperature of the chest center dropped faster after resting due to factors such as breast protrusion.

Conclusion The results showed that the prepared seamless yoga clothing with modular functions based on bioinspired structures had excellent antibacterial and thermal comfort. The body temperature was made to return to the pre-exercise temperature after 3 minutes of resting, and the antibacterial rate could reach 99.99% after 15 minutes.

Key words: bionic structure, antibacterial spandex, seamless yoga clothing, thermal-wet comfort, function modularization

CLC Number:

TS186.3

XU Weihui, ZHU Tingting, WAN Ailan, MA Pibo. Development of antibacterial seamless yoga clothes and its thermal-wet comfort based on bionic structure[J].Journal of Textile Research, 2025, 46(10): 187-196.

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

URL: http://www.fzxb.org.cn/EN/10.13475/j.fzxb.20250103501

http://www.fzxb.org.cn/EN/Y2025/V46/I10/187

Figures/Tables 16

Fig.1

Fig.2

Tab.1

Fig.3

Tab.2

Fig.4

Tab.3

Tab.4

Fig.5

Tab.5

Tab.6

Fig.6

Fig.7

Fig.8

Fig.9

Tab.7

References 16

[1]	MAILING L J, ALLEN J M, BUFORD T W, et al. Exercise and the gut microbiome: a review of the evidence, potential mechanisms, and implications for human health[J]. Exercise and Sport Sciences Reviews, 2019, 47(2): 75-85. doi: 10.1249/JES.0000000000000183 pmid: 30883471
[2]	SZOSTAK-KOTOWA J. Biodeterioration of textiles[J]. International Biodeterioration & Biodegradation, 2004, 53(3): 165-170.
[3]	汪秀琛, 吴洁莹, 吴咏鹏, 等. 含棉服装面料纳米抗菌芳香后整理工艺研究[J]. 针织工业, 2018(12): 35-38.
	WANG Xiuchen, WU Jieying, WU Yongpeng, et al. Study on nano-antibacterial aromatic finishing process of cotton-containing garment fabric[J]. Knitting Industries, 2018(12): 35-38.
[4]	张海芳, 郑伟, 高普, 等. 聚乳酸纤维与涤纶混纺织物的吸湿排汗整理[J]. 针织工业, 2015, (11): 43-47.
	ZHANG Haifang, ZHENG Wei, GAO Pu, et al. Moisture absorption and perspiration finishing of polylactic acid fiber and polyester blended fabric[J]. Knitting Industries, 2015, (11): 43-47.
[5]	THONGKERD C, POOMPIEW N, CHINAAKATAKUL K, et al. Strain sensing enhancement of 3D-printed polyurethane through surface deposition of carbon black[J]. Materials Science Forum, 2024, 1128: 45-50. doi: 10.4028/www.scientific.net/MSF
[6]	ALJAWARNEH R Y A, CHE ZAIN M S, ZAKARIA F. Macroporous polymeric resin for the purification of flavonoids from medicinal plants: a review[J]. Journal of Separation Science, 2024, 47(15): e2400372.
[7]	YUAN X H, SU Q, HAN L Y, et al. Preparation and performance of self-healing epoxy composites by microcapsulated approach[J]. Key Engineering Materials, 2014, 636: 73-77. doi: 10.4028/www.scientific.net/KEM.636
[8]	WANG W R, YU X L, CONG H L. Pressure evaluation of seamless yoga leggings designed with partition structure[J]. AUTEX Research Journal, 2023, 23(2): 300-309. doi: 10.2478/aut-2021-0053
[9]	WANG W R, CONG H L, DONG Z J, et al. Digital design model for weft-knitted seamless yoga pants based on skin deformation[J]. Journal Engineered Fibers and Fabrics, 2021, 16: 1558925021990503.
[10]	LEE H, LEE Y J. Effects of bikram yoga clothes on EEG beta spectrum[J]. Fibres & Textiles in Eastern Europe, 2022, 30(6): 45-54.
[11]	HRIDOY H M, HOSSAIN M P, ALI M H, et al. Alocasia macrorrhiza rhizome lectin inhibits growth of pathogenic bacteria and human lung cancer cell in vitro and Ehrlich ascites carcinoma cell in vivo in mice[J]. Protein Expression and Purification, 2024, 219: 106484. doi: 10.1016/j.pep.2024.106484
[12]	赵雅杰, 丛洪莲, 张静, 等. 功能性锦纶针织瑜伽服面料创新开发与应用[J]. 纺织导报, 2021(12): 22-26.
	HAO Yajie, CONG Honglian, ZHANG Jing. et al. Innovative development and application of functional nylon knitted yoga fabric[J]. China Textile Leader, 2021(12): 22-26.
[13]	ZHU T T, WAN A L. Antibacterial and yellowing performances of sports underwear fabric with polyamide/silver ion polyurethane filaments[J]. AUTEX Research Journal, 2024, 24: 20230020.
[14]	陈慧娴, 鲁虹, 李书洋, 等. 运动文胸结构设计要素对穿着舒适性的影响[J]. 纺织学报, 2019, 40(9): 159-166.
	CHEN Huixian, LU Hong, LI Shuyang, et al. The influence of structural design elements of sports bra on wearing comfort[J]. Journal of Textile Research, 2019, 40(9): 159-166.
[15]	IGARASHI T L, FERNANDES T L, HERNANDEZ A J, et al. Behavior of skin temperature during incremental cycling and running indoor exercises[J]. Heliyon, 2022, 8(10): e10889. doi: 10.1016/j.heliyon.2022.e10889
[16]	苗苗, 鲁虹, 程梦琪. 运动前后人体体表温度变化与主观热感觉评定[J]. 纺织学报, 2018, 39(4): 116-122.
	MIAO Miao, LU Hong, CHENG Mengqi. Changes in body surface temperature and subjective thermal sensation assessment before and after exercise[J]. Journal of Textile Research, 2018, 39(4): 116-122.

Related Articles 13

[1]	ZHAO Yajie, CONG Honglian, SUN Jianglong. Design and performance evaluation of knitted soft mat fabric [J]. Journal of Textile Research, 2024, 45(11): 99-105.
[2]	WANG Zhaofang, DING Bo, ZHANG Hui, CHEN Silin. Determination of sweating locations and sweating rate of young female breasts [J]. Journal of Textile Research, 2023, 44(12): 145-152.
[3]	LIU Qing, NIU Li, JIANG Gaoming, MA Pibo. Preparation and stab-resistance of bionic scale-like knitted fabrics [J]. Journal of Textile Research, 2023, 44(11): 90-97.
[4]	ZHAO Chen, WANG Min, LI Jun. Review on optimal design of personal cooling garments on cooling effect [J]. Journal of Textile Research, 2023, 44(09): 243-250.
[5]	CHU Yanyan, LI Shichen, CHEN Chao, LIU Yingying, HUANG Weihan, ZHANG Yue, CHEN Xiaogang. Research progress in bulletproof flexible textile materials and structures [J]. Journal of Textile Research, 2022, 43(12): 203-212.
[6]	WANG Jianping, MIAO Mingzhu, SHEN Deyao, YAO Xiaofeng. Development and performance evaluation of knitted fabric with bionic bird feather structure [J]. Journal of Textile Research, 2022, 43(04): 55-61.
[7]	WANG Li, ZHANG Bingjie, WANG Jianping, LIU Li, YANG Yalan, YAO Xiaofeng, LI Qianwen, LU You. Development and performance evaluation of bionic knitted winter sports fabrics [J]. Journal of Textile Research, 2021, 42(05): 66-72.
[8]	SUN Cenwenjie, NI Jun, ZHANG Zhaohua, DONG Wanting. Ventilation design and thermal-wet comfort evaluation of knitted sportswear [J]. Journal of Textile Research, 2020, 41(11): 122-127.
[9]	ZHANG Zhaohua, LI Luyao, AN Ruiping. Thermal-wet comfort evaluation of head and torso ventilation of pipe garment [J]. Journal of Textile Research, 2020, 41(08): 88-94.
[10]	ZHANG Heng, ZHEN Qi, LIU Yong, SONG Weimin, LIU Rangtong, ZHANG Yifeng. Air filtration performance and morphological features of polyethylene glycol/polypropylene composite fibrous materials with embedded structure [J]. Journal of Textile Research, 2019, 40(09): 28-34.
[11]	DU Feifei, LI Xiaohui, ZHANG Siyan. Evaluation of thermal protection performance of honeycomb sandwich structure fabric for fireproof clothing [J]. Journal of Textile Research, 2019, 40(03): 133-138.
[12]	. Comprehensive evaluation of thermal protection and comfort of outer fabrics of firefighter protective clothing [J]. JOURNAL OF TEXTILE RESEARCH, 2018, 39(08): 100-104.
[13]	WANG Li-Xin, FAN Xue-Rong, SUN You-Chang, CHAI Lei. Comparative study on thermal-wet comfort property of leather garment materials with different pores [J]. JOURNAL OF TEXTILE RESEARCH, 2012, 33(8): 97-102.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

组织编号	表层-里层组织结构	组织编号	表层-里层组织结构
1^#	纬平针-纬平针组织	7^#	芝麻点平针-波浪线方格组织
2^#	1+1 假罗纹-波浪线蜂巢组织	8^#	纬平针-1×1抽条组织
3^#	纬平针-树皮组织	9^#	纬平针-波浪线1×1抽条组织
4^#	1+1 假罗纹-波浪线树皮组织	10^#	抽条-抽条组织
5^#	纬平针-蜂巢组织	11^#	六边形凸点-凹点组织
6^#	芝麻点平针-方格组织	12^#	错位抽条-方格组织

试样编号	横密/ (纵行· (5 cm)^-1)	纵密/ (横列· (5 cm)^-1)	总密度/ (圈· (25 cm²)^-1)	面密度/ (g·m^-2)	厚度/ mm
1^#-1	70	65	4 450	384	1.38
2^#-2	78	73	5 694	412	1.36
3^#-3	80	143	11 440	432	1.38
4^#-4	80	75	6 000	444	1.52
5^#-5	78	115	8 970	372	1.30
6^#-6	83	75	6 225	340	1.35
7^#-7	83	75	6 225	348	1.37
8^#-8	90	128	11 475	360	1.40
9^#-9	90	128	11 475	372	1.38
10^#-10	58	165	9 570	320	1.41
11^#-11	65	140	9 100	494	1.72
12^#-12	85	160	13 600	443	1.59
1^#-13	75	70	5 250	390	1.40
1^#-14	70	65	4 450	384	1.38
1^#-15	70	65	4 450	384	1.38

纱线	断裂强力/cN	伸长率/%	定伸长强度/(cN·dtex^-1)	断裂强度/(cN·dtex^-1)	弹性模量/(cN·dtex^-1)
普通锦纶	315.2±2.50	22.06±4.65	10.3±1.53	40.5±2.47	215.0±2.34
疏水锦纶	366.3±3.70	31.00±5.00	10.5±6.69	47.1±3.69	250.1±2.99

试样编号	弹性回复率/%		弹性回复率CV值/%
试样编号	横向	纵向	横向	纵向
1^#-1	80.01	73.44	1.77	1.17
2^#-2	77.30	70.41	7.65	2.56
3^#-3	78.23	71.10	0.73	3.80
4^#-4	76.05	71.62	0.82	0.12
5^#-5	77.34	70.77	3.80	3.30
6^#-6	70.05	70.00	5.80	2.14
7^#-7	69.38	68.03	1.80	2.45
8^#-8	70.31	72.32	2.61	1.12
9^#-9	68.03	63.68	0.91	3.61
10^#-10	69.35	59.95	3.34	4.41
11^#-11	86.32	77.35	3.43	2.81
12^#-12	77.55	75.61	1.46	2.71
1^#-13	72.91	73.75	1.12	0.32
1^#-14	79.86	72.87	2.34	4.02
1^#-15	79.91	73.11	3.19	1.27

试样编号	热阻/ (10^-3m²·K·W^-1)	传热系数/ (W·(m²·K)^-1)	克罗值/ clo
1^#-1	33.6	29.76	0.216
2^#-2	33.1	29.24	0.212
3^#-3	33.5	30.16	0.213
4^#-4	34.1	29.74	0.219
5^#-5	31.7	31.57	0.204
6^#-6	30.7	32.60	0.198
7^#-7	30.5	32.61	0.199
8^#-8	29.8	33.55	0.192
9^#-9	32.4	30.83	0.209
10^#-10	32.2	31.01	0.208
11^#-11	43.5	23.04	0.280
12^#-12	30.4	33.44	0.196
1^#-13	34.7	28.59	0.222
1^#-14	31.3	31.94	0.202
1^#-15	30.5	32.61	0.197

Development of antibacterial seamless yoga clothes and its thermal-wet comfort based on bionic structure

RichHTML

PDF (PC)