Development of experimental platform for reaction injection pultrusion of carbon fiber reinforced nylon 6

doi:10.19936/j.cnki.2096-8000.20221228.032

Abstract

Abstract: In this study, an experimental platform for reaction injection pultrusion of carbon fiber reinforced nylon 6 composites was designed and developed. The experimental platform was divided into two modules: the solution preparing system and the pultrusion system. Through the analysis of nylon 6 anionic polymerization reaction conditions and the calculation of feed liquid flow output, the configuration and selection of the solution preparing system and the design of the pultrusion unit heating mold were completed. The development of the experimental platform was completed in combination with the storage and pretreatment system of carbon fiber yarn and the traction system. The carbon fiber reinforced nylon 6 composite plate with complete curing and uniform distribution of resin and 47.48% fiber volume was prepared by running the experimental platform. Taking into account the demand of subsequent continuous industrial production to ensure the continuous supply of feed liquid, a design idea of continuous on-line solution preparing reaction injection machine was proposed, which provides a reference for the preparatory work of industrial production.

Key words: carbon fiber reinforced nylon 6 composite, reaction injection pultrusion, anionic polymerization, equipment design

CLC Number:

TB332

ZHOU Jiahui. Development of experimental platform for reaction injection pultrusion of carbon fiber reinforced nylon 6[J]. COMPOSITES SCIENCE AND ENGINEERING, 2023, 0(7): 120-124.

References

[1] 李伟, 周保全, 李中辉, 等. 石墨烯改性热固性树脂及其纤维复合材料的研究进展. 玻璃钢/复合材料, 2014(11): 96-101.
[2] VAIDYA U, LI J S, GUAN J M. Thermoplastic composites for aerospace applications. Aeronautical Manufacturing Technology, 2015, 8(14): 69-71.
[3] NAWAB Y, SHAHID S, BOYARD N, et al. Chemical shrinkage characterization techniques for thermoset resins and associated composites. Journal of Materials Science, 2013, 48(16): 5387-5409.
[4] 包建文, 陈祥宝. 长期贮存单组分RTM环氧树脂研究. 热固性树脂, 2001, 16(5): 18-19.
[5] 陈丰, 孙宇. 可变纤维增强反应注射成型技术研究现状. 玻璃钢/复合材料, 2010(5): 71-77.
[6] 王玉洁, 黄明福, 陈晋南. 注射成型技术研究进展. 广东化工, 2007, 34(2): 31-33.
[7] 张玉龙. 高技术复合材料制备手册. 北京: 国防工业出版社,
[8] 2003.
[9] 邓鑫, 王进, 杨军, 等. 反应注射成型尼龙6的研究进展. 化工进展, 2009, 28(8): 1382-1394.
[10] 孙华, 薛平, 陈轲, 等. RTM成型玻璃纤维增强阴离子聚合尼龙6复合材料及其性能. 复合材料学报, 2021, 38(2): 414-423.
[11] 黎敏荣, 薛平, 贾明印, 等. 连续玻纤增强原位聚合尼龙6复合板材树脂传递成型工艺及性能研究. 塑料工业, 2017, 45(7): 57-60.
[12] 沈春银, 丁焰强, 周云飞, 等. 尼龙6反应注射成型的数值模拟与工程分析. 工程塑料应用, 2018, 46(8): 63-70, 80.
[13] CHO B G, MCCARTHY S P, FANUCCI J P, et al. Fiber reinforced nylon-6 composites produced by the reaction injection pultrusion process. Polymer Composites, 1996, 17(5): 673-681.
[14] EPPLE S, BONTEN C. Production of continuous fiber thermoplastic composites by in-situ pultrusion. AIP Conference Proceeding, 2014, 1593(1): 454-457.
[15] CHEN K, JIA M, SUN H, et al. Thermoplastic reaction injection pultrusion for continuous glass fiber-reinforced polyamide-6 composites. Materials, 2019, 12(3): 463-478.
[16] 周佳慧, 李金焕, 肖军, 等. 碳纤维增强尼龙6复合材料的阴离子聚合反应注射成型工艺. 复合材料学报, 2021, 38(12): 4172-4179.
[17] WENDEL R, ROSENBERG P, WILHELM M, et al. Anionic polymerization of ε-caprolactam under the influence of water: 1. Chemistry and experiments. Journal of Composites Science, 2020, 4(7): 18-25.
[18] CHEN K, JIA M, HUA S, et al. Optimization of initiator and activator for reactive thermoplastic pultrusion. Journal of Polymer Research, 2019, 26(2): 40.
[19] 曹长兴, 李礥. 反应注射成型设备混合系统的类型与性能. 塑料科技, 2004(2): 42-45.