玻璃纤维/乙烯基酯复合材料在火灾条件下热解气体内压预报方法

doi:10.19936/j.cnki.2096-8000.20230528.018

复合材料科学与工程 ›› 2023, Vol. 0 ›› Issue (5): 120-128.DOI: 10.19936/j.cnki.2096-8000.20230528.018

• 应用研究 • 上一篇

玻璃纤维/乙烯基酯复合材料在火灾条件下热解气体内压预报方法

解江^1,2, 袁浩然^1,2, 韩雪飞^1,2, 李翰^1,2, 冯振宇^1,2

1.中国民航大学安全科学与工程学院,天津 300300;
2.民航航空器适航审定技术重点实验室,天津 300300

收稿日期:2022-04-18 出版日期:2023-05-28 发布日期:2023-08-22
作者简介:解江(1982—),男,博士,副研究员,研究方向为复合材料冲击动力学,xiejiang5@126.com。

Internal pressure prediction method of pyrolysis gas under fire
conditions for glass fiber/vinyl ester composites

XIE Jiang^1,2, YUAN Haoran^1,2, HAN Xuefei^1,2, LI Han^1,2, FENG Zhenyu^1,2

1. School of Safety Science and Engineering, Civil Aviation University of China, Tianjin 300300, China;
2. Key Laboratory of Civil Aviation Aircraft Airworthiness Certification Technology, Tianjin 300300, China

Received:2022-04-18 Online:2023-05-28 Published:2023-08-22

摘要/Abstract

摘要： 聚合物基复合材料在高温环境下会发生热解反应,伴随着热解气体的产生,在材料内部形成气体压强。本文通过对UMATHT子程序进行二次开发,展开高温环境下复合材料基质热解与热解产物扩散的数值模拟,建立了复合材料内压预报模型,实现了传热方程、阿伦尼乌斯方程、达西定律、理想气体状态方程的耦合计算,模拟了75 kW/m²热流作用下玻璃纤维/乙烯基酯复合材料的内压变化。结果表明:该方法得到的压强预测值与试验值吻合较好,最大压强峰值误差约为4.68%,可有效预测玻璃纤维/乙烯基酯的内压变化趋势。各位置的压强达到峰值后开始下降,且影响因素不同。3 mm位置的压强下降受分解速率、渗透率、孔隙率共同影响;6 mm位置则是孔隙率增大与初始渗透率两者导致的;9 mm位置仅受初始渗透率的影响。

关键词: 内压, 热分解, 玻璃纤维/乙烯基酯复合材料, 热响应, 重叠网格技术

Abstract: The pyrolysis reaction of polymer matrix composites will occur at high temperature. With the production of pyrolysis gas, the gas pressure will be formed in the material. In this paper, through the secondary development of UMATHT subroutine, the numerical simulation of matrix pyrolysis and pyrolysis product diffusion of composites in high temperature environment is carried out, the prediction model of internal pressure of composites is established, the coupling calculation of heat transfer equation, Arrhenius equation, Darcy’s law and ideal gas state equation is realized, and the change of internal pressure of glass fiber/vinyl ester composites under 75 kW/ m² heat flow is simulated. The results show that the pressure prediction value obtained by this method is in good agreement with the experimental value, and the maximum pressure peak error is about 4.68%, which can effectively predict the internal pressure change trend of glass fiber/vinyl ester. The pressure at each location begins to decrease after reaching its peak, and the influencing factors are different. The pressure decreasing at the 3 mm position is affected by the decomposition rate, permeability and porosity; the 6 mm position is caused by the increase of the porosity and the initial permeability; the 9 mm position is only affected by the initial permeability.

Key words: internal pressure, thermal decomposition, glass fiber/vinyl ester, thermal response, overlapping grid technology

中图分类号:

TB332

解江, 袁浩然, 韩雪飞, 李翰, 冯振宇. 玻璃纤维/乙烯基酯复合材料在火灾条件下热解气体内压预报方法[J]. 复合材料科学与工程, 2023, 0(5): 120-128.

XIE Jiang, YUAN Haoran, HAN Xuefei, LI Han, FENG Zhenyu. Internal pressure prediction method of pyrolysis gas under fire
conditions for glass fiber/vinyl ester composites[J]. COMPOSITES SCIENCE AND ENGINEERING, 2023, 0(5): 120-128.

参考文献

[1] RICCIO A, DAMIANO M, ZARRELLI M, et al. Simulating the response of composite plates to fire[J]. Applied Composite Materials, 2014, 21(3): 511-524.
[2] ZHANG L, LIU W, SUN G, et al. Two-dimensional modeling of thermomechanical responses of rectangular GFRP profiles exposed to fire[J]. Advances in Materials Science and Engineering, 2017, 1705915.
[3] ZHOU A, YU Z. Validating thermal response models using bench-scale and intermediate-scale fire experiment data[J]. Mechanics of Advanced Materials and Structures, 2014, 21(5): 412-421.
[4] GRIGORIOU K, MOURITZ A P. Influence of ply stacking pattern on the structural properties of quasi-isotropic carbonepoxy laminates in fire[J]. Composites Part A: Applied Science and Manufacturing, 2017, 99: 113-120.
[5] MCKINNON M B, DING Y, STOLIAROV S I, et al. Pyrolysis model for a carbon fiber/epoxy structural aerospace composite[J]. Journal of Fire Sciences, 2017, 35(1): 36-61.
[6] YU Z, ZHOU A. Fiber reinforced polymer composite structures in fire: Modeling and validation[J]. Mechanics of Advanced Materials and Structures, 2013, 20(5): 361-372.
[7] GRIGORIOU K, MOURITZ A P. Comparative assessment of the fire structural performance of carbon-epoxy composite and aluminium alloy used In aerospace structures[J]. Materials & design, 2016, 108: 699-706.
[8] KANDOLA B, SARKER F, LUANGTRIRATANA P, et al. Thermal protection of carbon fiber-reinforced composites by ceramic particles[J]. Coatings, 2016, 6(2): 22.
[9] Federal Aviation Administration. Composite aircraft structure: AC 20-107B[S]. United States: Federal Aviation Administration, 2011.
[10] HENDERSON J B, WIECEK T E. A mathematical model to predict the thermal response of decomposing,expanding polymer composites[J]. Journal of Composite Materials, 1987, 21(4): 373-393.
[11] HENDERSON J B, WIECEK T E. A numerical study of the thermally-induced response of decomposing, expanding polymer composites[J]. Heat & Mass Transfer, 1988, 22(5): 275-284.
[12] BUCH J D. Thermal expansion of a thermally degrading organic matrix composite[J]. Carbon, 1972, 10(3): 333.
[13] FLORIO J, HENDERSON J B, TEST F L, et al. A study of the effects of the assumption of local-thermal equilibrium on the overall thermally-induced response of a decomposing, glass-filled polymer composite[J]. International Journal of Heat & Mass Transfer, 1991, 34(1): 135-147.
[14] TINNEY E R. The combustion of wooden dowels in heated air[J]. Symposium on Combustion, 1965, 10(1): 925-930.
[15] DIMITRIENKO Y I. Thermomechanical behaviour of composite materials and structures under high temperatures: 1. Materials[J]. Composites Part A: Applied Science and Manufacturing, 1997, 28(5): 453-461.
[16] DIMITRIENKO Y I. Thermomechanical behaviour of composite materials and structures under high temperatures: 2. Structures[J]. Composites Part A: Applied Science & Manufacturing, 1997, 28(5): 463-471.
[17] KOYANAGI J, SHINBA K, FUKUKA Y, et al. A Numerical simulation of delamination caused by internal gas pressure for mid-density CFRP[J]. Composites Part A: Applied Science and Manufacturing, 2018, 115: 255-263.
[18] SULLIVAN R M, SALAMON N J. A finite element method for the thermochemical decomposition of polymeric materials-Ⅰ. Theory[J]. International Journal of Engineering Science, 1992, 30(7): 431-441.
[19] SULLIVAN R M, SALAMON N J. A finite element method for the thermochemical decomposition of polymeric materials-Ⅱ. Carbon phenolic composites[J]. International Journal of Engineering Science, 1992, 30(7): 939-951.
[20] LOOYEH M R E, SAMANTA A, JIHAN S, et al. Modelling of reinforced polymer composites subject to thermo-mechanical loading[J]. International Journal for Numerical Methods in Engineering, 2005, 63(6): 898-925.
[21] 陈海龙, 方国东, 李林杰, 等. 高硅氧/酚醛复合材料热-力-化学多物理场耦合计算[J]. 复合材料学报, 2014, 31(3): 533-540.
[22] 时圣波. 高硅氧/酚醛复合材料的烧蚀机理及热-力学性能研究[D]. 哈尔滨: 哈尔滨工业大学, 2013.
[23] 冯振宇, 范保鑫. 基于UMATHT子程序的玻璃纤维/乙烯基酯热响应数值模拟[J]. 材料导报, 2021, 35(2): 2191-2198.
[24] MOURITZ A P, GIBSON A G. Fire properties of polymer composite materials[M]. Berlin: Springer Science & Business Media, 2007.
[25] GOODRICH T W. Thermophysical properties and microstructural changes of composite materials at elevatedtemperature[D]. Virginia: Virginia Tech, 2009.
[26] ZHANG Z. Thermo-mechanical behavior of polymer composites exposed to fire[D]. Virginia: Virginia Tech, 2010.
[27] LATTIMER B Y, OUELLETTE J. Properties of composite materials for thermal analysis involving fires[J]. Composites Part A: Applied Science and Manufacturing, 2006, 37(7): 1068-1081.

玻璃纤维/乙烯基酯复合材料在火灾条件下热解气体内压预报方法

Internal pressure prediction method of pyrolysis gas under fire
conditions for glass fiber/vinyl ester composites

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 5

编辑推荐

Metrics

本文评价

[1]	王琪, 谢煜斐, 袁连忠, 高进可, 陆嘉君. 连续玻纤增强热塑性复合管内压下力学性能研究[J]. 复合材料科学与工程, 2023, 0(7): 79-85.
[2]	冯振宇, 韩雪飞, 袁浩然, 李翰, 解江. 基于UMATHT子程序的玻璃纤维环氧树脂三维热响应研究[J]. 复合材料科学与工程, 2022, 0(1): 29-35.
[3]	冯振宇, 樊茂华, 范保鑫, 王纳斯丹. 阻燃改性玻璃纤维环氧树脂的热响应预报方法[J]. 玻璃钢/复合材料, 2019, 0(9): 32-37.
[4]	冯振宇, 王纳斯丹, 樊茂华, 范保鑫. 玻璃纤维乙烯基酯树脂复合材料的热响应预报方法[J]. 复合材料科学与工程, 2019, 0(11): 24-29.
[5]	林珊颖,白勇,方攀. 内压载荷下玻璃纤维增强复合软管力学性能研究[J]. 玻璃钢/复合材料, 2017, 0(9): 13-18.

玻璃纤维/乙烯基酯复合材料在火灾条件下热解气体内压预报方法

Internal pressure prediction method of pyrolysis gas under fireconditions for glass fiber/vinyl ester composites

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 5

编辑推荐

Metrics

本文评价

Internal pressure prediction method of pyrolysis gas under fire
conditions for glass fiber/vinyl ester composites