Fusion Adhesion Debonding and Peeling Characteristics of the Interface of In-Mold Micro-Assembly Molding

被引：0

作者：

Li H. ^{[1
]}

Zhou G. ^{[1
]}

机构：

[1] School of Resources, Environmental and Chemical Engineering, Nanchang University, Nanchang

来源：

Gaofenzi Cailiao Kexue Yu Gongcheng/Polymeric Materials Science and Engineering | 2020年 / 36卷 / 07期

关键词：

Debonding and peeling; In-mold micro-assembly molding; Micro-size machine; Motion pair; Movable performance;

D O I：

10.16865/j.cnki.1000-7555.2020.0142

中图分类号：

学科分类号：

摘要：

How to predict and control the micro-assembly interface fusion adhesion debonding and peeling characteristics accurately is a key scientific and technical problem in the preparation of high-performance micro-mechanical motion in polymer in-mold micro-assembly. Aiming at this key scientific and technical problem, the simulation platform of the in-mold micro-assembly micro-mechanical motion interface fusion adhesion debonding and peeling behavior was constructed, and the relationship among injection temperature-debonding and peeling fracture toughness parameters of material pair interface-interfacial fusion adhesion debonding and peeling characteristics was built. The research shows that the crack initiation stress, critical strain energy release rate and the driving force of complete debonding and stripping in the micro assembly interface are positively correlated with the injection temperature of the secondary molding melt. The reduction of the secondary molding injection temperature can significantly reduce the crack initiation stress, critical strain energy release rate in the micro assembly interface, and inhibit the fusion adhesion of the micro-assembly interface, which is beneficial to reduce the debonding and peeling driving force of the micro-assembly interface fusion adhesion, and improve the movable performance of the micro-assembly interface. © 2020, Editorial Board of Polymer Materials Science & Engineering. All right reserved.

引用

页码：94 / 102

页数：8

共 13 条

[1] Ananthanarayanan A, Bruck H A, Gupta S K., Characterization and control of plastic deformation in premolded components in in-mold assembled mesoscale revolute joints using bi-directional filling strategy, Polymer Engineering & Science, 49, pp. 293-304, (2008)
[2] Ananthanarayanan A, Bruck H A, Gupta S K., Interfacial adhesion in multi-stage injection molded components, St Louis, Missouri: SEM Annual Conference and Exposition, (2006)
[3] Michaeli W, Opfermann D., Micro assembly injection moulding, Microsystem Technologies, 12, pp. 616-619, (2006)
[4] Michaeli W, Kamps T., Micro assembly injection moulding with plasma treated inserts, Microsystem Technologies, 14, pp. 1903-1907, (2008)
[5] Michaeli W, Rogalla A, Ziegmann C., Processing technologies for the injection moulding of hybrid microstructures, Macromolecular Materials & Engineering, 279, pp. 42-45, (2000)
[6] Wu C L, Liu B., Present situation and application of in-mold assembly technology of injection molding, Engineering Plastics Application, 6, pp. 103-106, (2013)
[7] Ackermann K, Angus S D., A resource efficient big data analysis method for the social sciences: the case of global IP activity, Procedia Computer Science, 29, pp. 2360-2369, (2014)
[8] Amirsadeghi A, Lee J J, Park S., A Simulation study on the effect of cross-linking agent concentration for defect tolerant demolding in UV nanoimprint lithography, Langmuir, 28, pp. 11546-11554, (2012)
[9] Zhou G F, Deng Q C, Jiang X N., Mechanism of viscoelastic thermal fluid structure coupling effect induced polymer deformation, Polymer Materials Science & Engineering, 34, 7, pp. 84-89, (2018)
[10] Geubelle P H, Baylor J S., Impact-induced delamination of composites: a 2D simulation, Composites Part B-Engineering, 29, pp. 589-602, (1998)

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