Effect of thermo-oxidative aging on the mechanical properties of multi-layered biaxial weft knitted fabric reinforced composites

被引：0

作者：

Yang C. ^{[1
]}

Jiang Y. ^{[1
]}

Xiang H. ^{[1
]}

Li J. ^{[1
]}

机构：

[1] School of Textile Science and Engineering, Tiangong University, Tianjin

来源：

Fuhe Cailiao Xuebao/Acta Materiae Compositae Sinica | 2023年 / 40卷 / 01期

关键词：

aramid fiber; multi-layered biaxial weft knitted fabric reinforced composite; thermo-oxidative aging;

D O I：

10.13801/j.cnki.fhclxb.20220225.002

中图分类号：

学科分类号：

摘要：

Several multilayered biaxial weft knitted (MBWK) fabric reinforced composites with different shear angles were prepared by changing the orientation of preform inserting yarns. The thermo-oxidative aging test was designed based on Arrhenius model and Ozawa method. The thermal and physical properties of the samples before and after aging were characterized by mechanical properties, DSC, FTIR and DMA tests. The experimental results show that: With the change of yarns’ shearing angle, the composite mechanical properties retention rate after thermo-oxidative aging is also significantly different, because the post curing will occur for the vinyl ester resin in the thermo-oxidative aging environment. Therefore, the bending modulus of the composite materials in the aging process presents downward trend after increased first, and the tensile properties are affected by the reinforcement structure. The degradation of adhesion strength at fiber/matrix interface makes the tensile modulus decrease continuously during the aging process. With the aging time prolongation, the curing degree of resin increases gradually, and the glass transition temperature Tg increases gradually. The peak value of energy storage modulus increases at the initial stage of aging due to molecular chain crosslinking, while decreasing of the peak value is caused by molecular chain fracture at the later stage of aging. © 2023 Beijing University of Aeronautics and Astronautics (BUAA). All rights reserved.

引用

共 31 条

[1] GUPTA K B N V, SEN B, HIREMATH M M, Et al., Enhanced creep resistance of GFRP composites through interpenetrating polymer network[J], International Journal of Mechanical Sciences, 212, (2021)
[2] QIWEN Q, DENVID L., Defect detection of FRP-bonded civil structures under vehicle-induced airborne noise[J], Mechanical Systems and Signal Processing, 146, (2021)
[3] KARBHARI V M, XIAN G, HONG S., Effect of thermal exposure on carbon fiber reinforced composites used in civil infrastructure rehabilitation[J], Composites Part A: Applied Science and Manufacturing, 149, (2021)
[4] MERSCHMAN E, SALMAN A M, BASTIDAS A E, Et al., Assessment of the effectiveness of wood pole repair using FRP considering the impact of climate change on decay and hurricane risk[J], Advances in Climate Change Research, 11, 4, pp. 332-348, (2020)
[5] PRASHANTH S, SUBBAYA K M, NITHIN K, Et al., Fiber reinforced composites− A review[J], Journal of Material Sciences & Engineering, 6, 3, pp. 2-6, (2017)
[6] LI Z, LEPECH M D., Development of a multiphysics model of synergistic effects between environmental exposure and damage in woven glass fiber reinforced polymeric composites[J], Composite Structures, 258, (2020)
[7] FRANCESCO M, ANTONIO N., Durability of FRP rods for concrete structures[J], Construction and Building Materials, 18, 7, pp. 491-507, (2004)
[8] YU Yang, FAN Wei, XUE Lili, Et al., Influence of thermo-oxidative aging on the mechanical performance of three-dimensional braided carbon fiber-glass fiber/bismaleimide composites[J], Acta Materiae Compositae Sinica, 38, 12, pp. 4060-4072, (2021)
[9] WEI F, JIA L L., Rapid evaluation of thermal aging of a carbon fiber laminated epoxy composite[J], Polymer Composites, 35, 5, pp. 975-984, (2014)
[10] MLYNIEC A, KORTA J, UHL T., Structurally based constitutive model of epoxy adhesives incorporating the influence of post-curing and thermolysis[J], Composites Part B: Engineering, 86, pp. 160-167, (2016)

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