超声振动对玻璃纤维增强聚酰胺6注塑制件力学性能的影响

doi:10.19491/j.issn.1001-9278.2024.07.002

中国塑料 ›› 2024, Vol. 38 ›› Issue (7): 9-14.DOI: 10.19491/j.issn.1001-9278.2024.07.002

超声振动对玻璃纤维增强聚酰胺6注塑制件力学性能的影响

刘莹, 孙昊, 杨勇, 姜开宇, 于同敏, 马赛, 祝铁丽()

大连理工大学机械工程学院，高性能精密制造全国重点实验室，辽宁大连 116024

收稿日期:2023-11-21 出版日期:2024-07-26 发布日期:2024-07-24
通讯作者: 祝铁丽（1973—），博士，讲师，主要从事聚合物成型加工及模具设计制造技术研究，zhutieli@dlut.edu.cn
E-mail:zhutieli@dlut.edu.cn
基金资助:
国家重点研发计划项目(2022YFB3806203);国家自然科学基金资助项目(52205339)

Effect of ultrasonic vibration on mechanical properties of injection⁃molded parts of glass⁃fiber⁃reinforced polyamide 6

LIU Ying, SUN Hao, YANG Yong, JIANG Kaiyu, YU Tongmin, MA Sai, ZHU Tieli()

State Key Laboratory of High?performance Precision Manufacturing，School of Mechanical Engineering，Dalian University of Technology，Dalian 116024，China

Received:2023-11-21 Online:2024-07-26 Published:2024-07-24
Contact: ZHU Tieli E-mail:zhutieli@dlut.edu.cn

摘要/Abstract

摘要：

为提高纤维增强复合材料的力学性能，对玻璃纤维增强聚酰胺6（PA6/GF）复合材料进行了矩形平板制件超声辅助注射成型实验。通过对制件进行X射线衍射测试、扫描电子显微镜观测、傅里叶红外光谱分析以及拉伸性能测试，研究了超声施加时间和超声功率对制件的结晶度、玻璃纤维的取向程度、玻璃纤维与基体的结合强度以及制件力学性能的影响；并研究了经过超声振动的制件在吸水后其内部结晶度及力学性能的变化。结果表明，施加400 W超声振动，可以明显提高制件的结晶度；施加560 W超声时，玻璃纤维的取向形态得到改善，纤维与基体的结合强度有所提高，充填阶段施加超声所得制件的拉伸强度与弯曲强度比无超声振动的情形分别提高了11.9 %与10.1 %；但是如果继续增加超声功率，将会使制件的力学性能开始变差。制件吸水后，结晶度和力学性能下降，对制件的成型引入超声振动则能减小这种下降的幅度。

关键词: 超声振动, 玻璃纤维增强聚酰胺6, 凝聚态结构, 结晶度, 力学性能

Abstract:

To improve the mechanical properties of fiber⁃reinforced thermoplastic composites， ultrasonic assisted injection molding experiments were carried out for rectangular flat parts based on polyamide 6 （PA6） reinforced by glass fiber （GF）. Ultrasonic vibration was applied in the following two situations：（1） filling stage，（2） filling and packing stages. X⁃ray diffraction， scanning electron microscopy， Fourier⁃transform infrared spectroscopy， and tensile experiments were performed to investigate the effects of ultrasonic application time and ultrasonic power on the crystallinity and mechanical performance of the parts， the orientation degree of glass fibers， and the bonding strength between glass fibers and the matrix. The changes in the internal crystallinity and mechanical properties of the parts subjected to ultrasonic vibration after water absorption were also studied. The results indicated that crystallinity of the parts was significantly improved by applying ultrasonic vibration with a power of 400 W. When 560 W ultrasound was applied， both the orientation morphology of glass fiber and the bonding strength between the matrix and fibers were improved. Moreover， the tensile strength and bending strength of the parts molded by applying ultrasound during the filling stage were increased by 11.9 % and 10.1 %， respectively. However， the mechanical properties of the parts tended to drop with continuously increasing the ultrasonic power. After absorbing water， the parts showed a decrease in the crystallinity and mechanical properties. Such a reduction could be depressed by introducing ultrasonic vibration into the molding process of the parts.

Key words: ultrasonic vibration, glass?fiber?reinforced polyamide 6, condensed matter structure, crystallinity, mechanical property

中图分类号:

TQ323.6

刘莹, 孙昊, 杨勇, 姜开宇, 于同敏, 马赛, 祝铁丽. 超声振动对玻璃纤维增强聚酰胺6注塑制件力学性能的影响[J]. 中国塑料, 2024, 38(7): 9-14.

LIU Ying, SUN Hao, YANG Yong, JIANG Kaiyu, YU Tongmin, MA Sai, ZHU Tieli. Effect of ultrasonic vibration on mechanical properties of injection⁃molded parts of glass⁃fiber⁃reinforced polyamide 6[J]. China Plastics, 2024, 38(7): 9-14.

图/表 12

图1 制件结构及尺寸

Fig.1 The size and structure of the parts

图2 注塑模具的装配

Fig.2 Assembly of the injection mold

图3 超声功率为0 W时制件的XRD谱图及分峰拟合图样

Fig.3 XRD spectrum and peak fitting pattern of the workpiece with ultrasonic power of 0 W

图4 不同阶段施加超声振动所得制件的结晶度

Fig.4 The crystallinity of the product obtained by applying ultrasonic vibration at different stages

图5 不同阶段施加超声振动所得制件的力学性能

Fig.5 Mechanical properties of parts obtained by applying ultrasonic vibration at different stages

图6 充填阶段施加超声振动所得制件拉伸断裂面的SEM照片

Fig.6 SEM of the tensile fracture surface of the workpiece obtained by applying ultrasonic vibration during the filling stage

图7 充填与保压阶段施加超声振动所得制件拉伸断裂面的SEM照片

Fig.7 SEM of tensile fracture surface of parts during filling and pressure holding stage

图8 未施加超声振动所得制件在吸水前后的FTIR谱图

Fig.8 FTIR of the parts obtained without ultrasonic vibration before and after water absorption

图9 未施加超声振动所得制件在吸水前后的力学性能

Fig.9 Comparison of mechanical properties of parts obtained without ultrasonic vibration before and after water absorption

图10 未施加超声振动所得制件在吸水前后的拉伸断裂面的SEM照片

Fig.10 SEM of the tensile fracture surface of the workpiece before and after water absorption without applying ultrasonic vibration

图11 不同阶段施加超声振动所得制件在吸水后的结晶度

Fig.11 Crystallinity of the product obtained by applying ultrasonic vibration at different stages after water absorption

图12 不同阶段施加超声振动所得制件在吸水后的力学性能

Fig.12 Mechanical properties of parts obtained by applying ultrasonic vibration at different stages after water absorption

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超声振动对玻璃纤维增强聚酰胺6注塑制件力学性能的影响

Effect of ultrasonic vibration on mechanical properties of injection⁃molded parts of glass⁃fiber⁃reinforced polyamide 6

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