织物-空气层-皮肤三维结构建模及其传热模拟

doi:10.13475/j.fzxb.20231004701

纺织学报 ›› 2024, Vol. 45 ›› Issue (02): 198-205.doi: 10.13475/j.fzxb.20231004701

织物-空气层-皮肤三维结构建模及其传热模拟

韩烨¹, 田苗¹^,²^,³(), 蒋青昀¹, 苏云¹^,², 李俊¹^,²

1.东华大学服装与艺术设计学院, 上海 200051
2.东华大学现代服装设计与技术教育部重点实验室, 上海 200051
3.东华大学高性能纤维及制品教育部重点实验室, 上海 201620

收稿日期:2023-10-16 修回日期:2023-11-05 出版日期:2024-02-15 发布日期:2024-03-29
通讯作者: 田苗(1989—),女,副教授,博士。主要研究方向为功能服装数值模拟及人体工效学。E-mail:tianmiao@dhu.edu.cn。
作者简介:韩烨(2000—),女,硕士生。主要研究方向为功能服装数值模拟。
基金资助:
中央高校基本科研业务费专项基金(2232023D-06/2232023G-08);上海市级大学生创新创业训练计划项目(S202110255124)

Three dimensional modeling and heat transfer simulation of fabric-air gap-skin system

HAN Ye¹, TIAN Miao¹^,²^,³(), JIANG Qingyun¹, SU Yun¹^,², LI Jun¹^,²

1. College of Fashion and Design, Donghua University, Shanghai 200051,China
2. Key Laboratory of Clothing Design and Technology, Ministry of Education, Donghua University, Shanghai 200051, China
3. Key Laboratory of High Performance Fiters & Products, Ministry of Education, Donghua University, Shanghai 201620, China

Received:2023-10-16 Revised:2023-11-05 Published:2024-02-15 Online:2024-03-29

摘要/Abstract

摘要：

热防护服装是消防员面对火灾环境的重要屏障,为分析织物组织对其热防护能力的影响,构建了消防服外层阻燃织物的三维几何模型,并考虑实际着装状态建立“织物-空气层-皮肤”流固耦合传热模型。根据实验结果验证模型,并选取外界环境、织物组织结构及纱线导热系数进行参数研究,对比织物表面温度分布及真皮层热流密度、温度变化曲线。结果表明,该模型能较好地拟合实验结果,随着热暴露峰值温度的上升及纱线宽度的增大,纱线表面温度、真皮层热流密度、真皮层温度均上升。纱线的导热系数对真皮层温度影响较小。纱线宽度对真皮层温度的影响与热环境相关。有必要针对热暴露环境设计织物结构,在保障热防护性能的同时减小热防护服装质量,降低消防员热应激。

关键词: 热传递, 数值模拟, 织物组织, 消防服, 低热辐射

Abstract:

Objective Excessive thermal protection of thermal protective clothing will lead to heat stress, which is detrimental to health and even poses safety risks to firefighters. Reducing the weight and increasing the permeability of firefighting clothing can reduce their heat stress. The purpose of this study was to investigate the effects of fabric panel structure on its thermal protective performance based on numerical simulation, so as to provide a theoretical basis for improving fabric structure design.

Method Both experimental and numerical methods were adopted in this study. The experiments were performed by SET (stored energy tester) with the fabrics used as the outer shell of firefighting clothing, which provided initial and boundary conditions for numerical models. The three dimensional geometric model was developed based on the real fabric structure. On this basis, a fluid-solid conjugated heat transfer model of fabric, air gap and skin was built considering the actual wearing state. The model was validated by the experiment results and a mesh independence test was performed. The validated model was used to carry out parameter studies taking into consideration of the ambient temperature, yarn count and thermal conductivity of yarn as parameters.

Results The simulation results were in correspondence with the testing results. The mesh independence test indicated that the computational results were insensitive to the mesh sizes used in this study. Throughout the entire heat exposure process, the temperature within the air gap beneath the clothing decreased rapidly. The presence of fabric and the air gap significantly contributed to the thermal protection of the skin. Under different ambient temperatures, the skin temperature remained consistent. As the heat exposure progressed, heat continually transferred to the dermis, leading to a continuous increase in dermal heat flux, which plateaued at around 45 s. With increasing peak heat exposure temperature, the surface temperature of the yarn, dermal heat flux, and dermal temperature all increased. Among all the parameters studied in this research, ambient temperature had the most substantial impact on the heat transfer process. At the microscale, yarn count had a minimal impact on skin temperature and heat flux, but this effect was temperature-dependent. Under low heat exposure conditions (758 K, 873 K), increasing yarn count resulted in reduced skin temperature and heat flux. However, as the peak heat exposure temperature rose to 988 K, increasing yarn count led to higher skin temperature and heat flux. An increase in yarn thermal conductivity had a minor effect on skin temperature and heat flux, with limited impact. Treating the yarn layer as a uniform medium resulted in lower yarn surface temperature and heat flux compared to the yarn structure model.

Conclusion To investigate the heat transfer process and thermal protective performance of the fabric used in firefighting clothing, both experiments and numerical simulation were performed in this study. The models were validated by the experimental results and a parameter study was conducted. The effects of ambient temperature, yarn count and yarn thermal conductivity on yarn surface temperature, dermal temperature and dermal heat flux were simulated. The findings of this study indicate that the presence of the fabric and air gap effectively reduces skin temperature. The yarn count in the fabric layer has a complex influence on the heat transfer within the fabric-air gap-skin' system, which varies with changes in ambient temperature. For a single-layer fabric system, the air gap beneath the clothing plays a more crucial role in thermal protection, thereby mitigating the relatively weaker impact caused by variations in the fabric's thermal conductivity. Therefore, the design of the fabric panel structure should take into consideration the heat exposure environment. This approach not only contributes to minimizing the weight of thermal protective clothing but also serves to mitigate the risk of heat stress on firefighters. It ultimately enhances the occupational safety of firefighters in high-temperature environments while ensuring the thermal protection performance of the clothing.

Key words: heat transfer, numerical simulation, fabric structure, firefighter's clothing, low-level radiation

中图分类号:

X924.3

韩烨, 田苗, 蒋青昀, 苏云, 李俊. 织物-空气层-皮肤三维结构建模及其传热模拟[J]. 纺织学报, 2024, 45(02): 198-205.

HAN Ye, TIAN Miao, JIANG Qingyun, SU Yun, LI Jun. Three dimensional modeling and heat transfer simulation of fabric-air gap-skin system[J]. Journal of Textile Research, 2024, 45(02): 198-205.

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参考文献 15

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编号	纱线宽度/ mm	纱线高度/ mm	织物厚度/ mm	纤维占比/%
S1	0.65	0.1	0.2	45.86
S2	0.8	0.1	0.2	53.72
S3	均匀介质	-	0.2	100

模型层	厚度/ mm	比热容c_p/ (J·(kg·K)^-1)	导热系数k/ (W·(m·K)^-1)	密度ρ/ (kg·m^-3)
阻燃纱线	0.1	1 570	多项式	605.5
衣下空气层	6.4	多项式	多项式	多项式
表皮层	0.08	3 590	0.24	1 200
真皮层	2	3 330	0.45	1 200
皮下组织	10	2 500	0.19	1 000

峰值温度/K	最大温度/K		热流密度/(W·m^-2)
峰值温度/K	S1	S2	S1	S2
758	320.65	320.49	2 787.22	2 761.87
873	325.91	325.84	3 762.32	3 758.06
988	331.59	331.72	4 818.11	4 858.12

导热系数/(W·m^-1·K^-1)	温度/K	热流密度/(W·m^-2)
0.1	325.59	3 713.19
0.3	325.77	3 744.77
0.5	325.81	3 752.01

织物-空气层-皮肤三维结构建模及其传热模拟

Three dimensional modeling and heat transfer simulation of fabric-air gap-skin system

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