Prediction of mass adhesive damage based on the Rousselier model: Experimental and numerical analysis

IF 3.2 3区 材料科学 Q2 ENGINEERING, CHEMICAL International Journal of Adhesion and Adhesives Pub Date : 2024-10-10 DOI:10.1016/j.ijadhadh.2024.103852
Amin Houari , Kouider Madani , Mohamed Belhouari , Salah Amroune , Stéphane Cohendoz , Bruno Preaudeau , Xavier Feaugas , Raul DSG. Campilho
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Abstract

The study of the mechanical strength of adhesives remains an important area of research for researchers. These adhesives must be prepared in the form of mass test pieces to characterize them under different mechanical stresses. However, during the preparation of the test pieces several defects are likely to be present, namely air bubbles, cavities, or impurities. The behavior of the adhesive differs depending on the presence of one of these defects and, in most cases, the real behavior of the adhesive is not precisely known. For this purpose, several tests are necessary to have a close estimate of the adhesive's behavior. To numerically model the behavior of the adhesive it is necessary to consider the presence of these types of defects. This paper proposes a damage criterion based on the Rousselier model, which describes the damage due to crack growth from the presence of cavities in an adhesive, assumed as a ductile material. The proposed damage model was developed and implemented in a user-defined subroutine in the ABAQUS finite element code. Other damage models integrated into ABAQUS were used. In addition, the extended finite element method (XFEM) was used in the numerical simulations to study automatic damage modelling by the appearance and propagation of cracks in highly stressed areas. The main objective of this work is an analysis by the finite element method to determine the elastoplastic behavior coupled with the damage in the mass adhesive, considering the size, position, and shape of the defect (porosities) by the proposed models. Initially, experimental tests were carried out on mass specimens of adhesive to characterize the tensile response and to determine their mechanical properties depending on the position and size of the defect, which may exist in the specimen following its fabrication. The numerical results were validated by uniaxial tensile tests on the mass adhesive. Comparisons with the damage models integrated into ABAQUS have proven their effectiveness in predicting the behavior of the adhesive in the presence of a cavity.
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基于 Rousselier 模型的大规模粘合剂损坏预测:实验和数值分析
研究粘合剂的机械强度仍然是研究人员的一个重要研究领域。这些粘合剂必须以大量试件的形式制备,以便在不同的机械应力下对其进行表征。然而,在制备试件的过程中很可能会出现一些缺陷,即气泡、空洞或杂质。粘合剂的行为会因其中一个缺陷的存在而不同,在大多数情况下,粘合剂的真实行为并不确切。为此,有必要进行多次测试,以便对粘合剂的行为进行近似估计。为了对粘合剂的行为进行数值建模,有必要考虑这些类型缺陷的存在。本文提出了一种基于 Rousselier 模型的损坏标准,该模型描述了假定为韧性材料的粘合剂中存在空穴时由于裂纹增长而造成的损坏。所提出的损伤模型是在 ABAQUS 有限元代码的用户自定义子程序中开发和实施的。还使用了 ABAQUS 中集成的其他损伤模型。此外,在数值模拟中还使用了扩展有限元法 (XFEM),通过高应力区域裂纹的出现和扩展来研究自动损伤建模。这项工作的主要目的是通过有限元法进行分析,以确定与质量粘合剂中的损伤相耦合的弹塑性行为,同时考虑到所建议模型中缺陷(孔隙率)的大小、位置和形状。首先,对大量粘合剂试样进行了实验测试,以确定其拉伸响应特性,并根据试样制作后可能存在的缺陷位置和大小确定其机械特性。大量粘合剂的单轴拉伸试验验证了数值结果。与 ABAQUS 中集成的损伤模型的比较证明,这些模型能有效预测存在空腔时粘合剂的行为。
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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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