Study on the shear failure mechanism of vulcanized rubber-metal bonding interface based on cohesive zone model

IF 3.2 3区 材料科学 Q2 ENGINEERING, CHEMICAL
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Abstract

Rubber-metal bonding interface prone to adhesive failure. Cohesive zone model (CZM) is widely used in numerical simulation analysis of fracture of interfacial mechanics. In this paper, the traction-separation curve of the bonding surface of vulcanized rubber-metal specimen was obtained by tensile shear test and dumbbell rubber uniaxial tensile test. Then, the influence of shear strain of rubber itself was removed by numerical simulation of tensile shear of rubber, so as to identify the CZM parameters of rubber-metal interface.On this basis, a numerical model of the cohesive force of vulcanized rubber-metal was established, and the stress distribution, variation and damage evolution of the interface along the shear direction were analyzed microscopically. The initiation and propagation of cracks are explained and compared with the failure process and phenomenon of the test interface. The traction-displacement relationship curve was analyzed macroscopically, which was consistent with the traction-displacement relationship curve obtained by the experiment, and the error is less than 5 %. The CZM could accurately express the interface mechanical relationship of the experimental specimen. In addition, the influence of the width and length of the bonding interface on the mechanical properties of the bonding is also analyzed. With the increase of the width or length of the bonding interface, the maximum traction force increases linearly, but the relative displacement value of the initial bonding failure remains unchanged, and the length of the bonding interface has a more significant effect on the maximum traction force. The results show that the cohesive zone model can accurately and effectively analyze the shear failure of the vulcanized rubber-metal bonding surface, which provides a reference for the study of the failure of the bonding surface of other elastic composites.

基于内聚区模型的硫化橡胶-金属粘接界面剪切破坏机理研究
橡胶-金属粘接界面易发生粘接破坏。粘合区模型(CZM)被广泛应用于界面力学断裂的数值模拟分析。本文通过拉伸剪切试验和哑铃橡胶单轴拉伸试验获得了硫化橡胶-金属试样粘接面的牵引-分离曲线。在此基础上,建立了硫化橡胶-金属内聚力数值模型,并对界面沿剪切方向的应力分布、变化及损伤演化进行了微观分析。解释了裂纹的产生和扩展,并与试验界面的破坏过程和现象进行了比较。宏观分析了牵引力-位移关系曲线,与实验得到的牵引力-位移关系曲线一致,误差小于 5%。CZM 可以准确表达实验试样的界面力学关系。此外,还分析了粘接界面的宽度和长度对粘接力学性能的影响。随着粘接界面宽度或长度的增加,最大牵引力呈线性增加,但初始粘接破坏的相对位移值保持不变,粘接界面长度对最大牵引力的影响更为显著。结果表明,内聚区模型能准确有效地分析硫化橡胶-金属粘接面的剪切破坏,为研究其他弹性复合材料粘接面的破坏提供了参考。
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来源期刊
International Journal of Adhesion and Adhesives
International Journal of Adhesion and Adhesives 工程技术-材料科学:综合
CiteScore
6.90
自引率
8.80%
发文量
200
审稿时长
8.3 months
期刊介绍: The International Journal of Adhesion and Adhesives draws together the many aspects of the science and technology of adhesive materials, from fundamental research and development work to industrial applications. Subject areas covered include: interfacial interactions, surface chemistry, methods of testing, accumulation of test data on physical and mechanical properties, environmental effects, new adhesive materials, sealants, design of bonded joints, and manufacturing technology.
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