氢氧化钠处理对GF/VER复合材料界面及力学性能的影响

摘要/Abstract

摘要： 为改善玻璃纤维(Glass fiber, GF)与乙烯基酯树脂(Epoxy vinyl ester resin, VER)间界面性能，使用氢氧化钠溶液对GF进行表面改性处理。借助扫描电镜、红外光谱仪、万能材料试验机、摆锤冲击试验机等，分析改性前后GF的表面形态与化学结构的变化。测试改性前后GF/VER复合材料的单丝和纤维束界面剪切强度、弯曲强度、抗冲击强度。研究氢氧化钠处理对GF/VER复合材料的界面性能和力学性能的影响。结果表明：经过氢氧化钠溶液处理后，GF浸润性得到改善，表面变得粗糙，表面活性基团增多。单丝和纤维束的界面剪切强度相比改性前分别提升了25.31%、27.48%。GF/VER复合材料的弯曲强度与抗冲击强度相比改性前分别提升了20.96%、24.48%。

关键词: 玻璃纤维, 乙烯基酯树脂, 界面改性, 力学性能, 真空辅助树脂灌注成型

Abstract: Fiber-reinforced composites have many advantages, such as good mechanical properties, corrosion resistance, high-temperature resistance, and high moldability. It is the fastest-developing and most widely used class of composite material. The technology of fiber-reinforced composites has gradually matured in all aspects since the 1960s and is one of the new materials focused on research and development worldwide. Fiber-reinforced composites continue to develop toward high performance, multifunctionality, and complexity. To meet this demand for the materials, academics at home and abroad have investigated fiber-reinforced composites in greater depth, and current research primarily focuses on modifying the interfaces of composites. The small size region of the composite interface makes it more difficult for researchers to characterize its chemical structure, physical properties, and mechanical properties. Characterization of interfacial properties is thus also one of the hot spots in academic research. There is still a need to explore and refine the relationship between the microscopic interfacial and macroscopic mechanical properties of composites.
We aimed to modify the glass fiber (GF) surface with a sodium hydroxide solution to improve the interfacial properties between GF and vinyl ester resin (VER). Glass fibers were soaked in sodium hydroxide solutions at concentrations of 1 mol/L, 2 mol/L, and 3 mol/L for 24 h, 48 h, 72 h, and 96 h. Glass fiber reinforced vinyl ester resin (GF/VER) composites were made by using vacuum-assisted resin infusion molding technique. The interfacial shear strength between the fibers and the resin matrix was investigated by using the characterization method for the interfacial property of fiber extraction. We aim to examine the effect of the modification treatment on the surface morphology and the chemical interaction of the GF by using scanning electron microscopy and infrared spectroscopy. Before and after modification, the GF/VER composites were tested for interfacial shear strength, flexural strength, and impact strength by using a single fiber strength machine, a universal material testing machine, and a pendulum impact testing machine. The effects of sodium hydroxide treatment on the interfacial and mechanical properties of GF/VER composites were investigated. It was found that after modification with a solution of sodium hydroxide (concentration of 2 mol/L, and treatment time of 48 h), the wettability of GF was improved, the surface became roughened, and the reactive groups on the surface increased. After the modification treatment, the interfacial properties of GF/VER composites were improved. The monofilament interfacial shear strength reached 5.00 MPa, and the fiber bundle interfacial shear strength reached 29.04 MPa, 25.31%, and 27.48% higher than the original samples before modification, respectively. The mechanical properties of the composites were improved, with the bending strength reaching 346.72 MPa and impact strength reaching 158 kJ/m2, which increased by 20.96% and 25.40%, respectively, compared with the initial samples before modification. Thus, it was shown that sodium hydroxide treatment positively improved the bonding strength between the fiber and the resin. These research findings provide a benchmark for modification processing methods for fiber-reinforced composites and ideas for enhancing composites' interfacial and mechanical properties.

Key words: glass fiber, vinyl ester resin, interfacial modification, mechanical properties, vacuum-assisted resin infusion molding

中图分类号:

TS15

明琳, 冯旭煌, 邵灵达, 丁昊, 孙泽宇, 马雷雷, 田伟, 祝成炎. 氢氧化钠处理对GF/VER复合材料界面及力学性能的影响[J]. 现代纺织技术, 2023, 31(6): 100-109.

MING Lin , FENG Xuhuang, SHAO Lingda, DING Hao, SUN Zeyu, MA Leilei, TIAN We, ZHU Chengyan, . Effect of sodium hydroxide treatment on the interface and mechanical properties of GF/VER composites[J]. Advanced Textile Technology, 2023, 31(6): 100-109.

参考文献

[1] 田宏飞, 李蓓智, 龚菊贤, 等. 玻璃纤维增强复合材料铣削工艺实验研究[J]. 组合机床与自动化加工技术, 2019(4): 129–132.
TIAN Hongfei, LI Beizhi, GONG Juxian, et al. Experimental study on milling process of glass fiber reinforced composites[J]. Modular Machine Tool & Automatic Manufacturing Technique, 2019(4): 129-132.
[2] RONZHIN N O, POSOKHINA E D, MIKHLINA E V, et al. A new composite material based on alumina nanofibers and detonation nanodiamonds: synthesis, characterization, and sensing application[J]. Journal of Nanoparticle Research, 2021, 23(9): 199.
[3] LIU L, JIA C Y, HE J M, et al. Interfacial characterization, control and modification of carbon fiber reinforced polymer composites[J]. Composites Science and Technology, 2015, 121: 56-72.
[4] BÉNÉTHUILIÈRE T, DUCHET-RUMEAU J, DUBOSt E, et al. Vinylester/glass fiber interface: still a key component for designing new styrene-free SMC composite materials[J]. Composites Science and Technology, 2020, 190: 108037.
[5] 牛忠旺, 曹丽丽, 李其朋. 玻璃纤维增强复合材料的应用及研究现状[J]. 塑料工业, 2021，49 (S1): 9–17.
NIU Zhongwang, CAO Lili, LI Qipeng. Application and research status of glass fiber reinforced composites[J]. China Plastics Industry, 2021, 49(S1): 9-17.
[6] TIAN J, XU T, ZHANG Z W, et al. Study on the construction of polyethyleneimine/nano-silica multilayer film on the carbon fiber surfaces to improve the interfacial properties of carbon fiber/epoxy composites[J]. Composite Interfaces, 2022, 29(4): 361-381.
[7] 解玉洁, 张晓颖, 吴智仁, 等. 改性玄武岩纤维制备及其在微生物载体的应用[J]. 合成纤维, 2019, 48(3): 19–22.
XIE Yujie, ZHANG Xiaoying, WU Zhiren, et al. The preparation of modified basalt fiber and its utilization on microorganism carrier media[J]. Synthetic Fiber in China, 2019, 48(3): 19-22.
[8] PENG G　F, ZHANG G, LEI Z　H, et al. Verification of mechanism for effect of silane coupling agent modification of polyethylene (PE) fiber's surface on strain-hardening behavior of high-strength cementitious composites[J]. Journal of Building Engineering, 2023, 67: 105870.
[9] FU Y P, LI H X, CAO W Y. Enhancing the interfacial properties of high-modulus carbon fiber reinforced polymer matrix composites via electrochemical surface oxidation and grafting[J]. Composites Part A: Applied Science and Manufacturing, 2020, 130: 105719.
[10] CHEN Y Z, XU D W, QIU H F, et al. Improvement of the interfacial properties of PBO/Epoxy composites by online continuous plasma grafting with polyurethane[J]. Progress in Organic Coatings, 2020, 143: 105610.
[11] 孙文强, 曾辉, 牛兰刚, 等. 耐高温复合材料用玻璃纤维表面处理研究(1)：酸碱刻蚀处理的研究[J]. 玻璃钢/复合材料, 2000(1): 33–35.
SUN Wenqiang, ZENG Hui, NIU Langang, et al. Study on the surface treatment of glass fiber for high performance composites(1): Acid and alkali etching treatment[J]. FRP/CM, 2000(1): 33-35.
[12] 刘龙, 梁森, 周越松, 等. 改性芳纶纤维橡胶基复合材料抗冲击性能研究[J]. 化工新型材料, 2022, 50(7): 73-77.
LIU Long, LIANG Sen, ZHOU Yuesong, et al. Study on impact resistance of modified aramid fiber rubber matrix composites[J]. New Chemical Materials, 2022, 50(7): 73-77.
[13] 曹海琳, 张春红, 张志谦, 等. 玄武岩纤维表面涂层改性研究[J]. 航空材料学报, 2007, 27(5): 77-82.
CAO Hailin, ZHANG Chunhong, ZHANG Zhiqian, et al. Study on size modification of basalt fibers[J]. Journal of Aeronautical Materials, 2007, 27(5): 77-82.
[14] LI Y H, LIU H, BAI Q S, et al. Atomistic investigation on interfacial properties of glass surfaces modeling plasma modification and the influence of wettability conditions on adhesion[J]. International Journal of Adhesion and Adhesives, 2023, 122: 103330.
[15] 夏礼栋, 张琦, 高达利, 等. 聚酰胺/碳纤维复合材料中纤维表面改性研究进展[J]. 合成树脂及塑料, 2022, 39(1): 73–78.
XIA Lidong, ZHANG Qi, GAO Dali, et al. Advances in fiber surface modification in polyamide/carbon fiber composites[J]. China Synthetic Resin and Plastics, 2022, 39(1): 73-78.
[16] 李露露, 韩立新, 王爽芳, 等. 超高分子量聚乙烯纤维表面改性及其界面性能研究进展[J]. 功能材料, 2022, 53(4): 4088–4096.
LI Lulu, HAN Lixin, WANG Shuangfang, et al. Advances in surface modification of UHMWPE fibers and their interfacial properties[J]. Journal of Functional Materials, 2022, 53(4): 4088-4096.
[17] 吕婷婷, 吕丽华. 玄武岩纤维界面改性研究进展[J]. 棉纺织技术, 2020, 48(12): 76–79.
LÜ Tingting, LÜ Lihua. Research progress on interfacial modification of basalt fibers[J]. Cotton Textile Technology, 2020, 48(12): 76-79.
[18] 李虎, 范王腾飞, 王敏涓, 等. SiCf/TC17复合材料界面剪切强度测试与有限元分析[J]. 材料工程, 2021, 49(1): 160–167.
LI Hu, FAN Wangtengfei, WANG Minjuan, et al. Interfacial shear strength testing and finite element analysis of SiC_f/tc17 composites[J]. Journal of Materials Engineering, 2021, 49(1): 160-167.
[19] SHIN P　S, KIM J　H, PARK H　S, et al. Advanced interfacial properties of glass fiber/dopamine-epoxy composites using a microdroplet pull-out test and acoustic emission[J]. The Journal of Adhesion, 2021, 97(5): 438-455.
[20] RAMANATHAN T, BISMARCK A, SCHULZ E, et al. Investigation of the influence of acidic and basic surface groups on carbon fibres on the interfacial shear strength in an epoxy matrix by means of single-fibre pull-out test[J]. Composites Science and Technology, 2001, 61(4): 599-605.
[21] 陈平, 陆春, 于祺, 等. 纤维增强热塑性树脂基复合材料界面研究进展[J]. 材料科学与工艺, 2007, 15(5): 665–669.
CHEN Ping, LU Chun, YU Qi, et al. Advances in interfacial research of fiber-reinforced thermoplastic resin matrix composites[J]. Materials Science and Technology, 2007, 15(5): 665-669.
[22] 李琴梅, 魏晓晓, 郭霞, 等. 高性能与功能化高分子材料的表征技术及其特点[J]. 分析仪器, 2020(4): 1–9.
LI Qinmei, WEI Xiaoxiao, GUO Xia, et al. Characterization techniques and characteristics of high performance and functionalized polymer materials[J]. Analytical Instruments, 2020(4): 1-9.
[23] 王恒武, 王继辉, 朱京杨, 等. 纤维增强树脂基复合材料界面粘结强度测试方法探讨[J]. 玻璃钢/复合材料, 2003(3): 42–45.
WANG Hengwu, WANG Jihui, ZHU Jingyang, et al. Exploration of interfacial bond strength test method for fiber reinforced resin matrix composites[J]. FRP/CM, 2003(3): 42-45.
[24] 程海霞, 孙宝忠. 温度对碳纤维/环氧树脂复合材料界面性能的影响[J]. 东华大学学报(自然科学版), 2016, 42(3): 318–322.
CHENG Haixia, SUN Baozhong. Effect of temperature on the interfacial properties of carbon fiber/epoxy resin composites[J]. Journal of Donghua University (Natural Science), 2016, 42(3): 318-322.
[25] 高冬, 朱骏峰, 王洪廷, 等. PVC木塑复合发泡板改性研究[J]. 现代塑料加工应用, 2013, 25(5): 27–30.
GAO Dong, ZHU Junfeng, WANG Hongting, et al. Study on the modification of PVC wood-plastic composite foam board[J]. Modern Plastics Processing and Applications, 2013, 25(5): 27-30.
[26] TANAKA K, MINOSHIMA K, GRELA W, et al. Characterization of the aramid/epoxy interfacial properties by means of pull-out test and influence of water absorption[J]. Composites Science and Technology, 2002, 62(16): 2169-2177.
[27] 葛敦世. 玻璃纤维碱侵蚀机理和耐碱性的探讨[J]. 玻璃纤维, 2007(1): 1-9，14.
GE Dunshi. Exploration of alkali erosion mechanism and alkali resistance of glass fibers[J]. Fiber Glass, 2007(1): 1-9，14.