Journal of Textile Research ›› 2026, Vol. 47 ›› Issue (1): 151-158.doi: 10.13475/j.fzxb.20250502501

• Dyeing and Finishing Engineering • Previous Articles     Next Articles

Aging behavior of high-strength polyimide fabrics under various environmental factors

LAN Hanyu1,2, CHEN Xin1,2, LIANG Dongxu1,2, ZHAO Xin1,2(), ZHANG Qinghua1,2   

  1. 1. College of Materials Science and Engineering, Donghua University, Shanghai 201620, China
    2. State Key Laboratory of Advanced Fiber Materials, Donghua University, Shanghai 201620, China
  • Received:2025-05-16 Revised:2025-12-18 Online:2026-01-15 Published:2026-01-15
  • Contact: ZHAO Xin E-mail:xzhao@dhu.edu.cn

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Abstract:

Objective As a representative of advanced polymer materials, polyimide fibers show irreplaceability in extreme service environments such as military and aerospace with their unique molecular structure and performance synergy. However, the outstanding properties of polyimide will inevitably be affected by prolonged exposure to extreme conditions such as high-energy irradiation and atomic oxygen. This research is an attempt to explore in-depth the aging mechanism of polyimide fibers and fabrics under multiple environmental factors, so as to further improve the stability and reliability of the materials for the intended applications.

Method The aging test chamber was used to evaluate the radiation resistance, corrosion resistance and other properties of materials by simulating and accelerating environmental factors, from which the performance degradation of products in extreme environments was predicted. According to the GJB 150.10A-2009 standard, polyimide fabrics were placed in an aging test chamber with different experimental conditions to separately simulate mold, xenon lamp and salt spray aging environment before they were cleaned to remove surface contaminants by washing. In addition to the environmental aging tests, the fabrics underwent another abrasion aging test using a Martindale abrasion tester, referring to the GB/T 21196.2—2007 standard. The properties and structure of fabrics were analyzed by mechanical property testing, thermos gravimetric analysis (TGA), Fourier transform infrared spectroscopy (FT-IR), X-ray photoelectron spectroscopy (XPS) and scanning electron microscopy (SEM).

Results The initial polyimide fabric showed a warp tensile strength of 705.66 N/cm and an elongation at break of 9%. After undergoing mold, xenon lamp, abrasion, and salt-spray aging respectively, the tensile strength and elongation at break of the fabric decreased to various degrees. The retention rates of fabrics warp tensile strength were 91.44%, 89.35%, 87.48%, and 85.29%, respectively, still remaining at a relatively high level. The elongation at break of the different aged samples all decreased to around 7%, indicating that the flexibility of the fabric has declined. The thermal decomposition temperatures of the polyimide fabrics decreased after aging. The correlation between mechanical properties and heat resistance of fabric demonstrated that the experimental aging schemes indeed caused damage to the actual performance of the polyimide fabric to some extent. Subsequently, the chemical structures of the fabric before and after aging were investigated. The positions of different characteristic absorption peak in the FT-IR spectra of these samples did not change. In the characteristic XPS spectra of C 1s for the initial fabric, the proportions of C—O and C—N were 4.19% and 5.05%, respectively, and after different aging treatments, the proportions of both decreased. In contrast, an increase in the peak area of the C=N and the emergence of C*—C=O peak were observed, confirming that all three aging conditions affected the chemical structure of the polyimide. Mould, xenon lamp, and salt-spray aging treatments have no significant effect on the overall macroscopic morphology of the fabrics. The original surface morphology of the fiber was smooth, but the surface roughness increased after the above three aging treatments, displaying obvious etching grooves and partial peeling. After abrasion and stretching, the regularity of fabrics in warp direction deteriorated significantly. For the sample after abrasion aging, fibers showed obvious bending, the smooth surface structure was completely destroyed, and a structure similar to microfibrils emerged. For the fabric after warp tensile test, the longitudinal fibers exhibited obvious layered fracture morphology and “V-shaped” fracture notches. Finally, the possible aging mechanisms of polyimide fabrics under different environmental conditions were explored.

Conclusion The research results show that mold, xenon lamp, salt spray and abrasion aging negatively affected the mechanical properties and heat resistance of the high-strength polyimide fabrics to various degrees, and salt spray aging appears to be the most significantly damaging factor which reduced the tensile strength and elongation at break of the fabrics by 14.71% and 28.44%, respectively, and caused decrease in thermal weight loss temperature. After aging under different environmental conditions, the surface smoothness of fibers decreased, and microscopic defects such as grooves and peeling appeared. The chemical structure of fiber before and after experiment was analyzed, and the aging mechanism may be related to the destruction of chemical bonds such as C—N and C—O, as well as long molecular chains or conjugated structures in the polyimide macromolecular chain.

Key words: polyimide, mould, xenon lamp, salt-spray, aging, service performance, high performance fiber

CLC Number: 

  • TS151

Fig.1

Mechanical properties of polyimide fabrics before and after aging under different conditions. (a) Tensile strength and elongation at break; (b) Retention rate of tensile strength and elongation at break"

Fig.2

Thermal stability of PI fabrics before and after aging under different conditions. (a) TGA curves; (b) DTG curves"

Tab.1

Thermal resistance of PI fabrics treated under different aging conditions"

处理条件 Td5%/℃ Td10%/℃ Tdmax/℃ 残炭量/%
未处理 570.1 595.6 616.1 62.2
霉菌 569.5 592.7 614.9 60.9
氙灯 563.2 589.3 612.7 61.8
盐雾 554.4 585.2 609.1 62.3

Fig.3

FT-IR spectra of PI fabrics before and after aging under different condition"

Fig.4

XPS spectra of surface elements of PI fabrics before and after aging under different conditions"

Fig.5

SEM images of PI fabrics before and after aging under different conditions. (a) Untreated; (b) Mould aging; (c) Xenon lamp aging; (d) Salt-spray aging"

Fig.6

Surface morphologies of PI fabrics after abrasion (a) and stretching (b)"

Fig.7

Aging mechanism of PI fabrics under different conditions"

[1] 宋晓峰. 聚酰亚胺的研究与进展[J]. 纤维复合材料, 2007, 24(3): 33-37.
SONG Xiaofeng. Research and progress of polyimide[J]. Fiber Composites, 2007, 24(3): 33-37.
[2] ZHENG S S, DONG J, ZHOU X Y, et al. High-strength and high-modulus polyimide fibers with excellent UV and ozone resistance[J]. ACS Applied Polymer Materials, 2022, 4(6): 4558-4567.
doi: 10.1021/acsapm.2c00550
[3] JIANG S H, UCH B, AGARWAL S, et al. Ultralight, thermally insulating, compressible polyimide fiber assembled sponges[J]. ACS Applied Materials & Interfaces, 2017, 9(37): 32308-32315.
[4] 方国平, 杨艳, 何建忠. 聚酰亚胺8121高性能纤维技术及应用研究[J]. 针织工业, 2024(4): 6-11.
FANG Guoping, YANG Yan, HE Jianzhong. Technology and application of polyimide 8121 high-performance fiber[J]. Knitting Industries, 2024(4): 6-11.
[5] CHEN J, DING N W, LI Z F, et al. Organic polymer materials in the space environment[J]. Progress in Aerospace Sciences, 2016, 83: 37-56.
doi: 10.1016/j.paerosci.2016.02.002
[6] MINTON T K, ROUSSEL J F. Materials in a space environment[J]. ACS Applied Materials & Interfaces, 2010, 2(10): 2687-2688.
[7] XU S Q, LIN D L, LI R Y, et al. Effect of chemical structures and environmental factors on the thermal degradation mechanism of polyimide: experiments and molecular dynamics simulations[J]. Materials Today Chemistry, 2024, 40: 102242.
doi: 10.1016/j.mtchem.2024.102242
[8] ZHANG J L, ZHOU X Y, DONG J, et al. Intrinsically UV-resistant copolyimide: exploring the impact of UV-absorbing groups on degradation and comprehensive performance[J]. Macromolecules, 2024, 57(3): 1266-1276.
doi: 10.1021/acs.macromol.3c02170
[9] 杨传超, 徐鸿杰, 田国峰, 等. 高强高模聚酰亚胺纤维的空间环境适应性研究及在航天领域的应用前景分析[J]. 材料导报, 2022, 36(22): 184-188.
YANG Chuanchao, XU Hongjie, TIAN Guofeng, et al. Research on space environment adaptability of polyimide fiber with high-strength and high-modulus and analysis of its application prospects in aerospace field[J]. Materials Reports, 2022, 36(22): 184-188.
[10] 琚丹丹, 王馨敏, 孙承月, 等. PI纤维在空间带电粒子辐照下的力学性能损伤[J]. 装备环境工程, 2020, 17(3): 1-7.
JU Dandan, WANG Xinmin, SUN Chengyue, et al. Mechanical properties of polyimide fibers under the irradiation of space charged particles[J]. Equipment Environmental Engineering, 2020, 17(3): 1-7.
[11] HOQUE M S, DOLEZ P I. Impact of photochemical aging on high-performance fabrics used in firefighters' protective clothing[J]. Journal of Polymer Science, 2024, 62(23): 5347-5371.
doi: 10.1002/pola.v62.23
[12] EVANS S. Estimation of the uncertainties associated with XPS peak intensity determination[J]. Surface and Interface Analysis, 1992, 18(5): 323-332.
doi: 10.1002/sia.v18:5
[13] 马杰. 临近空间模拟环境下Kevlar和Vectran纤维织物损伤行为研究[D]. 天津: 河北工业大学, 2022.
MA Jie. Damage behavior of kevlar and vectran fibers in near space simulation environment[D]. Tianjin: Hebei University of Technology, 2022.
[14] ZHANG W X, JING X F, BAI Y Q, et al. Study on the aging behavior of an ultra-high molecular weight polyethylene fiber barrier net in a marine environment[J]. Materials, 2022, 15(16): 5599.
doi: 10.3390/ma15165599
[15] CHEN M H, LIANG B, GUO Y H, et al. Pyrolysis mechanism of polyimide containing bio-molecule adenine building block[J]. Polymer Degradation and Stability, 2020, 175: 109124.
doi: 10.1016/j.polymdegradstab.2020.109124
[16] 徐诗琴, 蔺道雷, 李闰月, 等. 聚酰亚胺薄膜老化过程中的结构与性能演变机理研究[J]. 化工新型材料, 2023, 51(9): 156-160, 167.
doi: 10.19817/j.cnki.issn1006-3536.2023.09.029
XU Shiqin, LIN Daolei, LI Runyue, et al. Evolution mechanism of structure and properties of polyimide films during aging[J]. New Chemical Materials, 2023, 51(9): 156-160, 167.
doi: 10.19817/j.cnki.issn1006-3536.2023.09.029
[17] ROY R, SARKAR B K, BOSE N R. Effects of moisture on the mechanical properties of glass fibre reinforced vinylester resin composites[J]. Bulletin of Materials Science, 2001, 24(1): 87-94.
doi: 10.1007/BF02704845
[18] LIU L L, JIN F, JI J, et al. Research on the quasi-static/dynamic mechanical properties and impact resistance of 3D woven composites under salt spray aging[J]. Composites Part A: Applied Science and Manufacturing, 2025, 194: 108923.
doi: 10.1016/j.compositesa.2025.108923
[19] GU J D, FORD T E, MITCHELL R. Susceptibility of electronic insulating polyimides to microbial degradation[J]. Journal of Applied Polymer Science, 1996, 62(7): 1029-1034.
doi: 10.1002/(ISSN)1097-4628
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