Wool/polyester mixed knitted fabrics with three-layer double-side structure for personal heat and humidity management

Abstract

Unidirectional moisture-transfer knitted fabrics play a crucial role in regulating body heat and moisture comfort. However, conventional moisture-conducting knitted fabrics primarily rely on single-sided plated stitches or double-sided fabrics connected by loops or tucks, lacking innovative multilayer structure designs. This study employed integrated knitting technology to fabricate three-layer double-sided moisture-conducting fabrics by incorporating the plated structure into the double-sided stitches. Two structures (A and B) were designed using ordinary polyester, ultrafine polyester, and wool yarns, with 10 fabrics knitted by varying the yarn types and layer positioning. A systematic evaluation of their properties was conducted. Results indicated that wool-containing fabrics exhibited better thermal insulation but reduced air permeability, moisture permeability, and moisture conductivity in comparison to wool-free fabrics. The positioning of wool yarns (inner, middle, and outer layers) significantly influenced fabric performance. Fabrics with wool plated in the inner layer demonstrated better performance compared with other wool-containing fabric configurations. The comprehensive evaluation results showed that structure B fabrics performed superior overall performance for garment applications compared with structure A. Furthermore, this knitting process presents a new approach to gradient moisture-conducting knitted fabric design.

Keywords

Three-layer fabric plated structure unidirectional moisture transfer pore/wetting gradient design evaluation of thermal and humidity performance

Get full access to this article

View all access options for this article.

References

Daniël

van Loon

LJC

Marken Lichtenbelt

WD.

Thermoregulation during exercise in the heat. Sports Med 2007; 37: 669–682.

Zhou

Zhao

Guo

, et al. Personal wearable thermal and moisture management clothing: A review on its recent trends and performance evaluation methods. Processes 2023; 11: 3063.

Fang

Zhao

Chen

, et al. Smart polyethylene textiles for radiative and evaporative cooling. Joule 2021; 5: 752–754.

Fang

Chen

Bick

, et al. Smart textiles for personalized thermoregulation. Chem Soc Rev 2021; 50: 9357–9374.

Chang

Wang

Sweat and odor in sportswear – a review. iScience 2023; 26: 107067.

Gavin

TP.

Clothing and thermoregulation during exercise. Sports Med 2003; 33: 941–947.

Pakdel

Naebe

Sun

, et al. Advanced functional fibrous materials for enhanced thermoregulating performance. ACS Appl Mater Interfaces 2019; 11: 13039–13057.

Min

Zhan

Niu

, et al. Multi-inspired Janus fabrics with asymmetric coolmax patterns for rapid sweat diffusion and effective sweat-shedding. Colloids Surf Physicochem Eng Asp 2024; 686: 133300.

Cui

Gao

Zhang

, et al. Preparation of hygroscopic fabric with a uniform and slow exothermic effect and its thermoregulation evaluation. Text Res J 2024; 94: 583–597.

10.

Tian

Bioinspired green fabricating design of ultra-breathable and moisture-wicking fabric via a sustainable route. J Clean Prod 2024; 461: 142690.

11.

Kuang

Zhang

, et al. Advances in directional liquid transport textiles: Mechanism, construction, and applications. Adv Funct Mater 2024; 34: 2406906.

12.

Shi

Dong

, et al. Bioinspired stable single-layer Janus fabric with directional water/moisture transport property for integrated personal cooling management. Adv Fiber Mater 2023; 5: 138–153.

13.

Wang

Huang

Miao

, et al. Biomimetic fibrous Murray membranes with ultrafast water transport and evaporation for smart moisture-wicking fabrics. ACS Nano 2019; 13: 1060–1070. doi: 10.1021/acsnano.8b08242.

14.

Miao

Huang

Wang

, et al. Continuous, spontaneous, and directional water transport in the trilayered fibrous membranes for functional moisture-wicking textiles. Small 2018; 14: 1801527.

15.

Yang

Wang

Fan

, et al. Preparation and properties of biodegradable directional water transport composite fabrics. Polym Eng Sci 2024; 64: 3617–3628.

16.

Xia

Xin

JH.

Durable moisture/thermal management self-adhesive coating for polyester fabric. Mater Sci Forum 2022; 1063: 203–208.

17.

Lin

Liu

Babar

, et al. Sweat gland-inspired skin-like fabric with directional water transport and durability for efficient personal moisture management. ACS Appl Mater Interfaces 2023; 15: 53105–53112.

18.

Min

Huang

, et al. 3D wetting gradient Janus sports bras for efficient sweat removal: A strategy to improve women’s sports comfort and health. Small 2024; 20: 2404137.

19.

Zou

Lao

Chen

, et al. Nature-inspired moisture management fabric for unidirectional liquid transport and surface repellence and resistance. Energy Build 2021; 248: 111203.

20.

Shi

, et al. Continuous homogeneous thin liquid film on a single cross-shaped profiled fiber with high off-circularity: toward quick-drying fabrics. Adv Mater 2024; 36: 2403316.

21.

Liu

Kang

Luo

, et al. Unidirectional wettability performances of weft-knitted fabric based on yarn structure. Fibers Polym 2022; 23: 827–835.

22.

Zeng

Zhang

, et al. Janus hygroscopic-cooling fabric (J-HCF) based on filament/bamboo core yarns for personal thermal-moisture management. Cellulose 2025; 32: 1339–1354.

23.

Dong

Ding

Cong

, et al. Research on plated structure design in weft knitting seamless fabric and sweat management. Text Res J 2024; 94: 36–48.

24.

Dong

Fang

Ding

, et al. Fixed position varying pore structure of weft-knitted seamless fabric and heat/moisture transfer mechanism. Text Res J 2024; 94: 1692–1702.

25.

Soltani

Lahir

Shabanian

, et al. Surface-engineered double-layered fabrics for continuous, passive fluid transport. Mater Horiz 2023; 10: 4293–4302.

26.

Qing

Chen

Jin Tu

Fan

Manas Kumar

Sarkar

, et al. Plant-based biomimetic branching structures in knitted fabrics for improved comfort-related properties. Text Res J 2011; 81: 1039–1048.

27.

Shen

Liu

, et al. Two-way nonparametric ANOVA using SPSS for analyzing data with non-normal distribution and unequal variances. Chin J Health Statist 2013; 30: 913–914.