Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (01): 87-94.doi: 10.13475/j.fzxb.20231002401

• Textile Engineering • Previous Articles     Next Articles

Parametric modeling of basalt/polyimide three-dimensional spacer woven fabric and numerical simulation of heat transfer in high temperature environment

LI Huimin, LIU Shuqiang(), DU Linlin, ZHANG Man, WU Gaihong   

  1. College of Textile Engineering, Taiyuan University of Technology, Jinzhong, Shanxi 030600, China
  • Received:2023-10-09 Revised:2024-05-15 Online:2025-01-15 Published:2025-01-15
  • Contact: LIU Shuqiang E-mail:liushuqiang8866@126.com

RichHTML

14

PDF (PC)

29

Abstract:

Objective Two difficulties exist when studying the thermal protection performance of three-dimensional (3-D) spacer woven fabrics, which are the low repeatbility of the test results obtained from self-built platforms by themselves, and the high cost of samples in terms of forming process complexity, long lead time, and the production cost. In order to solve the above two problems, numerical simulation was carried out to save manpower and material resources, break through the limitations of experimental conditions, and reduce the error caused by human factors.

Method Parametric modeling of basalt/polyimide 3-D spacer woven fabric was carried out, and then its heat transfer mechanism in high temperature environments was analyzed. The control equation and boundary conditions were determined, and finite element analysis software was utilized to numerically simulate the geometric model of 3-D spacer fabrics in high temperature environments, in order to predict the influence of spacer height and weft spacing on the heat transfer performance of basalt/polyimide 3-D spacer woven fabrics.

Results From the heat transfer diagram of 3-D spacer woven fabrics with different weft spacing at an external ambient temperature of 150 ℃, it was evident that as the weft spacering was increased, the temperature on the back of the fabric gradually was found to decrease when the heat balance was reached. When the weft spacing increases from 5 to 23 mm, the temperature of the point probe on the back of the fabric demonstrated a decrease from 42.63 ℃ to 42.40 ℃ at the heat transfer equilibrium state. Inside the 3-D spacer woven fabric, the spacer yarn temperature on the same horizontal plane was slightly lower than the air domain temperature, with a difference of about 0.22 ℃. From the heat transfer numerical simulation diagram of different spacer heights, it was seen that as the spacer height increases, the temperature on the back of the 3-D spacer woven fabric showed a gradual decrease when the heat transfer reached equilibrium. When the spacer height was increased from 0 to 12 mm, the temperature of the point probe on the back of the fabric showed a decrease from 51.31 ℃ to 39.91 ℃ at the heat transfer equilibrium state. Inside the 3-D spacer woven fabric, the spacer yarn temperature on the same horizontal plane was slightly lower than the air domain temperature, with a difference of about 0.15 ℃.

Conclusion Parametric modeling is carried out according to the geometric relationship of basalt/polyimide 3-D spacer woven fabric structural unit, the buckling and the interweaving of yarns. Based on the basic theory of heat transfer, a numerical model of heat transfer process of basalt/polyimide 3-D spacer woven fabric in high temperature environment is established. The finite element analysis is carried out to calculate the temperature field of basalt/polyimide 3-D spacer woven fabric in high temperature environment. The numerical simulation method is adopted to explore the influence of the weft spacing on the heat transfer performance. The spacer height is found an important parameter affecting the heat transfer performance of the 3-D spacer woven fabric. The 3-D spacer fabric, the spacer yarn temperature on the same horizontal plane at the same time is slightly lower than the air domain temperature.

Key words: three-dimensional spacer woven fabric, basalt fiber, polyimide fiber, high-performance fiber, high temperature environment, heat transfer, numerical simulation

CLC Number: 

  • TS105.1

Fig.1

Warp cross section image of basalt/polyimide 3-D spacer fabric with 5 weft spacing"

Fig.2

Geometric relation of structural unit of 3-D spacer fabric"

Fig.3

3-D model of structural unit of basalt/polyimide 3-D spacer fabric with 5 weft spacing"

Tab.1

Thermophysical parameters of materials"

材料 导热系数/
(W·m-1·K-1)		 密度/
(kg·m-3)		 比热/
(J·kg-1·K-1)
玄武岩纱线 1.33 805 940
聚酰亚胺纱线 1.56 602 470

Fig.4

Meshing of fabric system"

Fig.5

Temperature curves of fabric models with different weft spacing when heat transfer reaches equilibrium. (a)Fabric back; (b)Spacing yarn and air domain at same level"

Fig.6

Cloud map of heat flux distribution of fabric and air domain with 11 weft spacing.(a) Entire fabric system (including fabric and air domain); (b) Fabric"

Fig.7

Influence of spacer height on different variables. (a)Fabric back temperature; (b)Spacing yarn temperature; (c)Air temperature; (d)Inward heat flux; (e)Conduction heat flux in air domain; (f)Conduction heat flux in fabric domain"

Fig.8

3-D fabric weave diagram with interval height of 4 mm and 11 weft spacing"

Fig.9

Test platform construction diagram"

Fig.10

Temperature curves of fabric back (a) and comparison diagram of model and physical object (b)"

[1] 戴佳欣, 李小辉. 热防护服隔热层材料的成型工艺研究[J]. 棉纺织技术, 2022, 50(1): 13-17.
DAI Jiaxin, LI Xiaohui. Study on the molding process of thermal protective clothing insulation material[J]. Cotton Textile Technology, 2022, 50 (1): 13-17.
[2] KRAUSE K, GRÜNEFELD P, BARTH L, 等. 基于三维间隔织物的隔热服传热模拟[J]. 国际纺织导报, 2021, 49(10): 27-28, 39.
KRAUSE K, GRÜNEFELD P, BARTH L, et al. Thermal insulation suit based on three-dimensional interval fabrics[J]. Melliand China, 2021, 49(10): 27-28, 39.
[3] 芮珂, 何佳臻. 三维间隔织物隔热性能的研究进展[J]. 现代纺织技术, 2023, 31(1): 259-268.
RUI Ke, HE Jiazhen. Research progress of thermal insulation properties of three-dimensional spacer fabrics[J]. Advanced Textile Technology, 2023, 31(1): 259-268.
[4] 黄冬梅, 何松. 空气层位置对消防战斗服隔热性能的影响[J]. 纺织学报, 2015, 36(10): 113-119.
HUANG Dongmei, HE Song. Effect of air layer position on thermal insulation performance of fire fighting clothing[J]. Journal of Textile Research, 2015, 36(10): 113-119.
[5] 王汉玉, 孙润军. 间隔织物增强复合材料的隔热性能研究[J]. 合成纤维, 2020, 49(12): 44-48.
WANG Hanyu, SUN Runjun. Study on thermal insulation properties of spacer fabric reinforced composites[J]. Synthetic Fiber in China, 2020, 49(12): 44-48.
[6] 王震, 姜亚明, 刘良森, 等. 常用高性能纱线弯曲刚度的测量和表征[J]. 纺织学报, 2014, 35(5): 30-33.
WANG Zhen, JIANG Yaming, LIU Liangsen, et al. Measurement and characterization of bending stiffness of commonly used high-performance yarns[J]. Journal of Textile Research, 2014, 35(5): 30-33.
[7] PIERCE R S, FALZON B G. Simulating resin infusion through textile reinforcement materials for the manufacture of complex composite structures[J]. Engineering, 2017, 3(5): 596-607.
[8] 郑振荣, 智伟, 韩晨晨, 等. 碳纤维织物在热流冲击下的热传递数值模拟[J]. 纺织学报, 2019, 40(6): 38-44.
ZHENG Zhenrong, ZHI Wei, HAN Chenchen, et al. Numerical simulation of heat transfer of carbon fiber fabric under heat flux impact[J]. Journal of Textile Research, 2019, 40(6): 38-44.
[9] AKPOYOMARE A I, OKEREKE M I, BINGLEY M S. Generation of virtual geometric domains for woven textile composites[J]. Composite Structures, 2020. DOI: 10.1016/j.compstruct.2019.111624.
[10] 张倩, 郑振荣, 赵晓明, 等. 高温下涂层织物传热过程的数值模拟[J]. 材料导报, 2020, 34(16): 16167-16171.
ZHANG Qian, ZHENG Zhenrong, ZHAO Xiaoming, et al. Numerical simulation of heat transfer process of coated fabric at high temperature[J]. Materials Reports, 2020, 34(16): 16167-16171.
[11] 吴茜. 织物热传递性能及其数值模拟[D]. 武汉: 武汉纺织大学, 2017:11,41-44.
WU Qian. Fabric heat transfer performance and its numerical simulation[D]. Wuhan: Wuhan Textile University, 2017:11,41-44.
[12] RAJ U, WANG F. A three-dimensional conjugate heat transfer model for thermal protective clothing[J]. International Journal of Thermal Sciences, 2018, 130: 28-46.
[13] SHEN H, XU Y, WANG F, et al. Numerical analysis of heat and flow transfer in porous textiles: influence of wind velocity and air permeability[J]. International Journal of Thermal Sciences, 2020. DOI:10.1016/j.ijthermalsci.2020.106432.
[14] 郑振荣, 张玉双, 王红梅, 等. 基于纱线交织结构的织物传热模拟方法[J]. 工程热物理学报, 2016, 37(9): 1918-1925.
ZHENG Zhenrong, ZHANG Yushuang, WANG Hongmei, et al. Fabric heat transfer simulation method based on yarn interwoven structure[J]. Journal of Engineering Thermophysics, 2016, 37(9): 1918-1925.
[15] 靖逸凡. 热防护用玄武岩/聚酰亚胺三维间隔织物的结构设计与性能研究[D]. 晋中: 太原理工大学, 2022:10-11.
JING Yifan. Structural design and properties of basalt / polyimide three-dimensional spacer fabric for thermal protection[D]. Jinzhong: Taiyuan University of Technology, 2022: 10-11.
[1] ZHANG Dingtiao, WANG Qianru, QIU Fang, LI Fengyan. Simulation of flow field and fiber straightening in reconstructed fiber transport channel in rotor spinning [J]. Journal of Textile Research, 2025, 46(02): 100-105.
[2] LI Ling, SHI Qianqian, TIAN Shun, WANG Jun. Influence of fiber channel symmetry on dual-feed-opening rotor spinning flow field and yarn characteristics [J]. Journal of Textile Research, 2025, 46(02): 69-77.
[3] SONG Kaili, GUO Mingrui, GAO Weidong. Numerical simulation and experimental investigation of lattice-apron compact spinning with airflow-guiding device [J]. Journal of Textile Research, 2025, 46(01): 34-41.
[4] WANG Jue, YAN Shilin, LI Yongjing, HE Longfei, XIE Xiangyu, MENG Xiaoxu. Effect of shear deformation on principal permeability and infiltration characteristics of anisotropic fabrics [J]. Journal of Textile Research, 2024, 45(12): 109-117.
[5] XI Chuanzhi, WANG Jiayuan, WANG Yongzhi, CHEN Ge, PEI Zeguang. Numerical simulation of airflow field in nozzle of vortex spinning with low energy consumption and spinning experimentation [J]. Journal of Textile Research, 2024, 45(12): 206-214.
[6] ZHANG Dingtiao, WANG Qianru, QIU Fang, LI Fengyan. Comparison on multi-dimensional numerical simulation of airflow field in carding and trash removal zone for rotor spinning [J]. Journal of Textile Research, 2024, 45(10): 64-71.
[7] TIAN Shaomeng, ZHANG Li, SHI Haoxuan, XU Yang. Simulation and analysis of dynamic deformation of densely woven filter fabrics based on ANSYS Workbench [J]. Journal of Textile Research, 2024, 45(09): 63-69.
[8] ZHANG Qi, ZUO Lujiao, TU Jiani, NIE Meiting. Numerical simulation of air permeability of warp-knitted jacquard shoe upper materials [J]. Journal of Textile Research, 2024, 45(09): 78-83.
[9] YUE Xu, WANG Lei, SUN Fengxin, PAN Ruru, GAO Weidong. Finite element simulation of bending of plain woven fabrics based on ABAQUS [J]. Journal of Textile Research, 2024, 45(08): 165-172.
[10] LIU Qianqian, YOU Jianming, WANG Yan, SUN Chenglei, JIRI Militky, DANA Kremenakova, JAKUB Wiener, ZHU Guocheng. Influence of fiber curvature on filtration characteristics of fibrous assembly by steady-state numerical analysis [J]. Journal of Textile Research, 2024, 45(07): 31-39.
[11] XIE Hong, ZHANG Linwei, SHEN Yunping. Continuous dynamic clothing pressure prediction model based on human arm and accuracy characterization method [J]. Journal of Textile Research, 2024, 45(07): 150-158.
[12] 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.
[13] WANG Qing, LIANG Gaoxiang, YIN Junqing, SHENG Xiaochao, LÜ Xushan, DANG Shuai. Establishment of novel model and performance analysis of airflow drafting channel [J]. Journal of Textile Research, 2023, 44(11): 52-60.
[14] YANG Mengxiang, LIU Rangtong, LI Liang, LIU Shuping, LI Shujing. Heat transfer and thermal protection properties under strong thermal conditions of woven fabrics [J]. Journal of Textile Research, 2023, 44(11): 74-82.
[15] LIU Guangju, SU Yun, TIAN Miao, LI Jun. Two-dimensional transient heat transfer model for electrically heated shoe upper and experimental validation [J]. Journal of Textile Research, 2023, 44(10): 127-133.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备14006648号
Copyright 2021 © Editorial office of Journal of Textile Research
Supported by Beijing Magtech Co.Ltd