基于松香酸酐的生物质树脂基体湿热性能研究

复合材料科学与工程 ›› 2021, Vol. 0 ›› Issue (1): 85-91.

基于松香酸酐的生物质树脂基体湿热性能研究

黎迪晖¹, 仝建峰¹, 张旭锋^1,2*, 益小苏^1,2*

1.中航复材(北京)科技有限公司,北京101300;
2.绿色复合材料北京市工程实验室,北京101300

收稿日期:2020-02-27 出版日期:2021-01-28 发布日期:2021-01-25
通讯作者: 益小苏(1953-),教授,主要从事高分子材料、复合材料方面的研究,yi_xiaosu@sina.com;张旭锋(1978-),博士,高级工程师,主要从事树脂基复合材料方面的研究,010xufeng@sina.com。
作者简介:黎迪晖(1992-),男,硕士,主要从事树脂基复合材料方面的研究。
基金资助:
中航复材创新基金(GSCXJJ-2017-12)

HYGROTHERMAL PROPERTIES OF BIOMASS RESIN MATRIX BASED ON ROSIN ANHYDRIDE UNDER DIFFERENT HYGROTHERMAL CONDITIONS

LI Di-hui¹, TONG Jian-feng¹, ZHANG Xu-feng^1,2*, YI Xiao-su^1,2*

1. ACC (Beijing) Science and Technology Co., Ltd., Beijing 101300, China;
2. Beijing Engineering Laboratory of Green Composites, Beijing 101300, China

Received:2020-02-27 Online:2021-01-28 Published:2021-01-25

摘要/Abstract

摘要： 研究了室温和70 ℃条件下松香酸酐生物质树脂基体(AGMP3600)在蒸馏水和海水中的吸水性能,通过经典Fick模型模拟了树脂基体的水吸收过程,并与双氰胺固化环氧树脂基体(AP2300)的吸水性能进行了对比,对吸水前后试样的动态力学性能及微观形貌进行了分析。结果表明AGMP3600具有较好的耐水性能,在70 ℃海水环境中的准平衡吸水率为2.01%,扩散系数为1.77×10^-6 mm²/s,AP2300准平衡吸水率为6.60%,扩散系数为0.46×10^-6 mm²/s。AGMP3600浇注体储能模量随浸泡时间增加先下降后上升,力学损耗对应的峰值温度(T_g)随浸泡时间增加略有降低;AP2300浇注体随树脂浸泡时间增加,储能模量和玻璃化转变温度T_g都有所下降。由显微金相照片可看出水吸收对AGMP3600树脂微孔破坏程度小,而AP2300树脂由于水吸收率高,微孔孔隙增大、增多。

关键词: 生物质树脂, 松香酸酐, 环氧树脂, 水吸收与扩散, 复合材料

Abstract: The water absorption property of bio-based resin matrix based on rosin-sourced anhydride was studied under room and 70 ℃ temperature in the environment of distilled water and nature sea water, and also the water absorption course was simulated by Fick model. The water absorption results of AGMP3600 were compared with those of epoxy resin system cured by dicyandiamide. The dynamical mechanic property and micromorphology for both resin before and after water absorption were investigated. The results show that AGMP3600 resin matrix has good water resistant, the quasi equilibrium water absorption rate at 70 ℃ in sea water is 2.01%, the diffusion coefficient is 1.77×10^-6 mm²/s. For AP2300 resin matrix , the quasi equilibrium water absorption rate at 70 ℃ in sea water is 6.60%, and the diffusion coefficient is 0.46×10^-6 mm²/s. With the soak time of casting sample lasting, the storage modulus of AGMP3600 first decreases and then increases, and the glass transition temperature corresponding to the peak value of mechanical loss decreases slightly. On the contrary, for the AP2300 resin matrix, the storage modulus and glass transition temperature are both decrease. From the micro metallographic photographs, the water absorption has little damage on the micropores of AGMP3600. But for AP2300 resin matrix, the water absorption made the number of micropore increasing and the volume enlarged.

Key words: bio-based resin, rosin-sourced anhydride, epoxy resin, water absorption and diffusion, composites

中图分类号:

TB332

黎迪晖, 仝建峰, 张旭锋, 益小苏. 基于松香酸酐的生物质树脂基体湿热性能研究[J]. 复合材料科学与工程, 2021, 0(1): 85-91.

LI Di-hui, TONG Jian-feng, ZHANG Xu-feng, YI Xiao-su. HYGROTHERMAL PROPERTIES OF BIOMASS RESIN MATRIX BASED ON ROSIN ANHYDRIDE UNDER DIFFERENT HYGROTHERMAL CONDITIONS[J]. COMPOSITES SCIENCE AND ENGINEERING, 2021, 0(1): 85-91.

参考文献

[1] DAI S J. High Performance Fiber Composites[M]. Shanghai: East China University of Science and Technology Press, 2013: 126-176.
[2] 丁遗福, 李华, 刘墨君, 等. 吸水过程对环氧树脂的动态松弛行为的影响[J]. 高等化学学报, 2002,(23): 965-969.
[3] 边立平, 肖加余, 曾竟成, 等. 极性基团对环氧树脂基体力学性能及吸水特性的影响[J]. 国防科技大学学报, 2011(4): 55-59.
[4] 杨青, 陈新, 兰逢涛, 等. 固化度对环氧树脂湿热性能的影响[J]. 热固性树脂, 2016(5): 44-47.
[5] 陈春露, 纪丹阳, 孙海洋, 等. 湿热环境对树脂基复合材料拉伸性能的影响[J]. 科学技术创新, 2019(11): 21-22.
[6] YI X S, LI Y. Biomass Resin, Fiber and Bio composites[M]. Beijing: China Building Materials Industry Press, 2017.
[7] ZHANG X, WU Y, YI X S, et al. Curing kinetics and mechanical properties of bio-based composite using rosin-sourced anhydrides as curing agent for hot-melt prepreg[J]. Science China Technological Sciences, 2017(60): 1318-1331.
[8] WU F, ZHOU X P, YU X H. Reaction mechanism, cure behavior and properties of a multifunctional epoxy resin, TGDDM, with latent curing agent dicyandiamide[J]. RSC Adv., 2018, 8(15): 8248-8258.
[9] 陈旭, 尹鹏, 益小苏, 等. 苎麻纤维增强酚醛树脂基复合材料的湿热性能研究 [J]. 航空材料学报, 2013(33): 58-65.
[10] XIAN G J, KARBHARI V M. DMTA based investigation of hygro-thermal ageing of an epoxy system used in rehabilitation[J]. Journal of Applied Polymer Science, 2007, 104(2): 1084-1094.
[11] KORKEES F, CRIS A, ALSTON S. An investigation of the long-term water uptake behavior and mechanisms of carbon fiber/977-2 epoxy composites[J]. Polym. Eng. Sci., 2018, 58: 2175-2184.
[12] 黎迪晖. 水碱浸泡条件下环氧树脂的性能演化与分子动力学模拟[D]. 哈尔滨: 哈尔滨工业大学, 2015.
[13] ANDREA A, KATHARINA R F, ARUNJUNAI R M, et al. Anhydride cured bio-based epoxy resin: Effect of moisture on thermal and mechanical properties[J]. Macromol. Mater. Eng., 2019, 304:
1900031.
[14] KARBHARI V M, XIAN G J. Hygrothermal effects on high VF pul-truded unidirectional carbon/epoxy composites: Moisture uptake[J]. Composites Part B: Engineering, 2009, 40(1): 41-49.
[15] ABDELMOLA F, CARLSSON L A. Water uptake in epoxy matrix with voids: Experiments and modeling[J]. Journal of Composite Materials, 2019, 53(8): 1049-1065.
[16] 关胤. 浅析环氧材料的耐水性和耐湿热性[J]. 科技视界, 2015(1): 387.