针织结构温度传感器设计及其着装传感性能

doi:10.13475/j.fzxb.20250601001

Abstract

Abstract:

Objective The changes in human skin temperature can indirectly reflect the functional status of the circulatory system, nervous system, or local tissues. At present, sensors that can monitor human temperature signals are mainly divided into non-fabric type and fabric type. Non-fabric temperature sensors have problems such as poor comfort and fit, limited wearability, insufficient environmental adaptability, and high cost. Therefore, fabric based temperature sensors have become a hot research topic. This study aims to optimize the design of knitted flexible temperature sensors for monitoring human skin temperature during wearing. Additionally, the influence of wearing factors (e.g., body surface curvature, wearing pressure, and outer clothing layers) on the linearity and sensitivity of the sensors is investigated to enhance the understanding for their design and applications.

Method By using silver-plated polyamide yarn and jacquard plating technology, an orthogonal experimental design is employed to analyze the relationships between yarn linear density, fabric structure, plating rows/columns, and the sensing performance of knitted temperature sensors. Silver-plated polyamide yarn (with linear densities of 77.78, 111.11, and 155.56 dtex) and jacquard plating technology are used to fabricate 16 knitted sensor samples with 1+1, 1+2 and 2+2 rib structures, varying plating rows (6,12, 18, 24) and columns (24, 36, 48, 60). A orthogonal experiment is conducted to test static resistance, linearity, sensitivity and stability. Wearing simulations involve measuring sensors on curved surfaces (scapula convex and lumbar concave areas), applying pressures (1.175 1-3.1 751 kPa), and adding 1-3 outer clothing layers.

Results The static resistance is within 26.872 Ω, negatively correlating with fabric grammage and plating rows, but positively with thickness. Linearity improves with increased thickness (quadratic fit, R²=0.611) and plating rows (logarithmic fit, R²=0.412). Sensitivity is positively related to yarn linear density and plating rows, described by a multiple linear regression (R²=0.617). The optimal parameters are 155.56 dtex yarn, 1+2 rib structure, 24 plating rows/columns, with static resistance of 2.813 Ω, linearity of 99.57%, sensitivity of 0.014 4 ℃^-1, and stability of 1.79%. Wearing experiments show that linearity and sensitivity decrease at the sunken lumbar region due to contact gaps, while increasing at the convex scapular region due to close contact. Increasing wearing pressure and outer fabric layers can improve sensor linearity and sensitivity.

Conclusion This study establishes quantitative relationships between process parameters and sensing performance, providing optimal design guidelines for knitted temperature sensors. Findings highlight multi-factor (synergy of yarn, structure, plating) significantly affects sensor performance, surpassing single-factor analyses in prior studies. Innovative consideration of wearing dynamics reveals body curvature, pressure, outer clothing layers are critical for practical use. These results enable development of wearable sensors with enhanced adaptability to human physiology and clothing environments, offering foundation for intelligent health-monitoring textiles. Future work is expected to explore dynamic motion effects and long-term durability under repeated wearing.

Key words: knitted structure, temperature sensor, temperature signal monitoring, silver-plated polyamide yarn, sensing performance, dressing factor, flexible sensor, smart clothing

CLC Number:

TS181

ZHANG Ying, GUO Mingjing, WANG Lijun. Design of knitted temperature sensors and their sensing performance under wearing conditions[J].Journal of Textile Research, 2025, 46(12): 123-132.

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URL: http://www.fzxb.org.cn/EN/10.13475/j.fzxb.20250601001

http://www.fzxb.org.cn/EN/Y2025/V46/I12/123

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纱线线密度/dtex	复丝根数	捻度/ (捻·(10 cm)^-1)	原料及含量
77.78	24	17.44	银17%、锦纶83%
111.11	36	17.33	银17%、锦纶83%
155.56	48	17.27	银17%、锦纶83%

纱嘴编号	连接纱线种类	作用
1	弹性纱线	辅助编织的临时纱线,织出起底部分(为废纱)
3	镀银锦纶纱线	织造传感区域(为添纱)
5	涤纶/棉混纺纱	织造非传感区域(为主纱)
7	锦纶纱线	作为主纱与废纱的连接纱

组合编号	组合条件	质量/g	压力/ kPa	组合层数	厚度/ mm
0	基础对照组	8.755	0.175 1	0	0
1	橡皮+50 g砝码	58.755	1.175 1	1	0.30
2	橡皮+100 g砝码	108.755	2.175 1	2	0.56
3	橡皮+150 g砝码	158.755	3.175 1	3	0.86

因素	静态电阻		线性度		灵敏度
因素	相关系数	显著性	相关系数	显著性	相关系数	显著性
面密度	-0.533^*	0.034	0.185	0.494	0.753^**	0.001
厚度	-0.629^**	0.009	0.684^**	0.003	0.426	0.100
横密	-0.261	0.329	0.464	0.070	-0.017	0.950
纵密	0.601^*	0.014	-0.605^*	0.013	-0.463	0.071
线圈长度	-0.257	0.337	-0.013	0.961	0.180	0.506
纱线线密度	-0.348	0.186	0.171	0.528	0.569^*	0.021
组织结构	0.001	0.991	0.022	0.868	0.041	0.761
添纱行数	-0.702^**	0.002	0.656^**	0.006	0.584^*	0.018
添纱列数	0.371	0.157	-0.229	0.393	-0.440	0.088

因变量	自变量	模型	调整后R²	F	P值	常数	b₁	b₂	b₃
静态电阻	添纱行数/面密度	线性函数	0.593	11.908	0.000	102.174	-3.162	-0.382	—
	厚度	二次函数	0.611	10.193	0.002	-5.339	11.583	-5.301	—
		S函数	0.481	12.975	0.003	0.234	-0.271	—	—
线性度	线密度	二次函数	0.310	4.372	0.035	1.025	-0.059	0.016	—
		三次函数	0.310	4.372	0.035	0.993	已排除	-0.016	0.005
	添纱行数	次方函数	0.413	11.532	0.004	0.970	0.014	—	—
		对数函数	0.412	11.501	0.004	0.970	0.014	—	—
灵敏度	添纱行数/线密度	线性函数	0.617	13.088	0.000	0.007	0.001	0.001	-

Design of knitted temperature sensors and their sensing performance under wearing conditions

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