聚合物-金属直接成型技术

doi:10.16183/j.cnki.jsjtu.2018.02.008

上海交通大学学报（自然版） ›› 2018, Vol. 52 ›› Issue (2): 176-181.doi: 10.16183/j.cnki.jsjtu.2018.02.008

聚合物-金属直接成型技术

樊聪，胡广洪，凌成智

上海交通大学塑性成型技术与装备研究院，上海 200030

出版日期:2018-03-01 发布日期:2018-03-01
基金资助:
上海市自然科学基金项目（13ZR1420500）

Polymer-Metal Direct Molding Technology

FAN Cong,HU Guanghong,LING Chengzhi

Institute of Plastic Molding Technology and Equipment, Shanghai Jiao Tong University, Shanghai 200030, China

Online:2018-03-01 Published:2018-03-01

摘要/Abstract

摘要： 聚合物-金属直接成型作为一种将金属与聚合物直接粘接在一起的成型工艺，其组合件同时具有金属与聚合物的材料特性，因而具有广泛的发展前景.介绍了聚合物-金属直接成型技术原理及其关键技术，总结了目前该领域关于直接成型组合件粘接强度的研究进展，并综述了影响其粘接强度的一些重要因素，为今后关于组合件粘接强度的研究打好基础.

关键词: 聚合物-金属直接成型, 粘接力, 金属表面处理

Abstract: Polymer-metal direct forming, as a kind of forming process which combines metal and polymer directly, has a wide range of development prospects because of its combination of metal and polymer material characteristics. This paper mainly introduced the theory of polymer-metal direct molding technology and its key technology as well, summarized the latest research progress of bonding strength of compounds, and pointed out some key factors influencing the bonding strength. These lay a good foundation for the future research on bonding strength of the composite parts.

Key words: polymer-metal direct molding, bonding strength, metal surface treatment

中图分类号:

TQ 32

樊聪，胡广洪，凌成智. 聚合物-金属直接成型技术[J]. 上海交通大学学报（自然版）, 2018, 52(2): 176-181.

FAN Cong,HU Guanghong,LING Chengzhi. Polymer-Metal Direct Molding Technology[J]. Journal of Shanghai Jiaotong University, 2018, 52(2): 176-181.

参考文献

［1］胡广洪, 杜彦丽. 聚合物-金属组合成型及其关键技术［J］. 上海塑料, 2015(4): 6-10. HU Guanghong, DU Yanli. Polymer-to-metal hybrid technology and its key ［J］. Shanghai Plastics, 2015 (4): 6-10. ［2］GRUJICIC M, SELLAPPAN V, OMAR M A, et al. An overview of the polymer-to-metal direct-adhesion hybrid technologies for load-bearing automotive components［J］. Journal of Materials Processing Technology, 2008, 197(1-3): 363-373. ［3］MERTENS A J, SENTHILVELAN S. Effect of mating metal gear surface texture on the polymer gear surface temperature［J］. Materials Today Proceedings, 2015, 2(4/5): 1763-1769. ［4］FABRIN P A, HOIKKANEN M E, VUORINEN J E. Adhesion of thermoplastic elastomer on surface treated aluminum by injection molding［J］. Polymer Engineering & Science, 2007, 47(8): 1187-1191. ［5］KIM J Y, AHN K, JEONG S Y, et al. Enhancement of adhesion between polyphenylene sulfide and copper by surface treatments［J］. Current Applied Physics, 2014, 14(1): 118-121. ［6］OCHOA-PUTMAN C, VAIDYA U K. Mechanisms of interfacial adhesion in metal-polymer composites—Effect of chemical treatment［J］. Composites Part A: Applied Science & Manufacturing, 2011, 42(8): 906-915. ［7］KIM W S, YUN I H, LEE J J, et al. Evaluation of mechanical interlock effect on adhesion strength of polymer-metal interfaces using micro-patterned surface topography［J］. International Journal of Adhesion & Adhesives, 2010, 30(6): 408-417. ［8］YEH R Y, HSU R Q . Application of porous oxide layer in plastic/metal direct adhesion by injection molding［J］. Journal of Adhesion Science & Technology, 2015, 29(15): 1617-1627. ［9］RAMANI K, MORIARTY B. Thermoplastic bonding to metals via injection molding for macro-composite manufacture［J］. Polymer Engineering & Science, 1998, 38(5): 870-877. ［10］SALGIN B, ZKANAT , MOL J M C, et al. Role of surface oxide properties on the aluminum/epoxy interfacial bonding［J］. The Journal of Physical Chemistry C, 2013, 117(9): 4480-4487. ［11］KIM W S, KIM K H, JANG C J, et al. Micro-and nano-morphological modification of aluminum surface for adhesive bonding to polymeric composites［J］. Journal of Adhesion Science and Technology, 2013, 27(15): 1625-1640. ［12］FEISTAUER E E, GUIMARES R P M, EBEL T, et al. Ultrasonic joining: A novel direct-assembly technique for metal-composite hybrid structures［J］. Materials Letters, 2016, 170: 1-4. ［13］YEH R Y, HSU R Q. Development of ultrasonic direct joining of thermoplastic to laser structured metal［J］. International Journal of Adhesion & Adhesives, 2015, 65: 28-32. ［14］刘斌, 陈昌乾, 张步进. 金属与塑料一体化的纳米成型技术及应用［J］. 模具工业, 2015, 41(7): 1-4. LIU Bin, CHEN Changqian, ZHANG Bujin. The application of nano-moulding technology for metal and plastic’s integration ［J］. Die & Mould Industry, 2015, 41 (7): 1-4. ［15］宫清, 张雄, 张宜虎, 等. 一种金属树脂一体化成型方法和一种金属树脂复合体: CN103286910A［P］. 2013-09-11［2017-01-10］. ［16］张绍华, 雷霆, 王长明, 等. 铝或铝合金表面微纳米加工方法及铝或铝合金结构: CN103276435A［P］. 2013-09-04［2017-01-10］.

[1]	刘晓东，吴磊，孔谅，王敏，陈一东. 空气等离子处理对碳纤维增强复合材料表面特性及胶接性能的影响[J]. 上海交通大学学报, 2019, 53(8): 971-977.
[2]	薛超凡1，于敏1，姚举禄2，姬科举1，戴振东1. 碳纤维增强树脂基复合材料在低温条件下的微动摩擦磨损性能[J]. 上海交通大学学报（自然版）, 2018, 52(5): 604-611.
[3]	王梦寒，李雁召，刘晓，夏知姿，陈明亮. 工艺参数对高光制品收缩及翘曲变形的影响[J]. 上海交通大学学报（自然版）, 2016, 50(02): 235-240.
[4]	徐媛媛，桂宗彦，杲云，陆冲，程树军. 柠檬酸基聚酯/聚乳酸共混物的力学性能[J]. 上海交通大学学报（自然版）, 2013, 47(05): 806-810.
[5]	陆跃，饶炬，龚飞荣，陈建定. 聚己内酯型聚羟基氨基甲酸酯的合成[J]. 上海交通大学学报（自然版）, 2013, 47(05): 827-833.
[6]	尹红灵, 孙懋, 徐宗剑, 陈军. 大型复杂多孔塑件注塑模拟关键技术[J]. 上海交通大学学报（自然版）, 2012, 46(03): 504-508.

聚合物-金属直接成型技术

Polymer-Metal Direct Molding Technology

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 6

编辑推荐

Metrics

本文评价