Peridynamics–FEM coupling for interfacial delamination effected by vertical crack density in thermal barrier coatings

IF 2.9 3区工程技术 Q2 MECHANICS

International Journal of Applied Mechanics Pub Date : 2023-10-14 DOI:10.1142/s1758825124500054

Han Dong, Han Wang, Zhenwei Cai, Weizhe Wang, Yingzheng Liu

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引用次数: 0

Abstract

A coupling model of peridynamics and finite element method is proposed to study the interfacial delamination influenced by vertical crack density in thermal barrier coating (TBC) systems. Specifically, the progressive failure progress under static and fatigue loads in TBCs, including vertical cracks propagation, the evolution of vertical cracks to interfacial cracks, and interfacial delamination, is simulated by the proposed model. The difference between static failure mechanism and fatigue failure mechanism of TBCs is numerically elucidated. The simulated fracture morphology is in good agreement with the experiential observation. In both static and fatigue loads, a higher vertical crack density is found to correspond to a shorter delamination length, and there is no interfacial delamination when the vertical crack density is high enough. The results provide important insight of vertical crack density on interfacial delamination, and the durability of TBCs can be enhanced by ensuring an appropriately high vertical crack density.

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垂直裂纹密度对热障涂层界面分层影响的周动力学-有限元耦合

建立了热障涂层(TBC)中垂直裂纹密度对界面分层的耦合模型和有限元方法。具体而言，该模型模拟了静载荷和疲劳载荷作用下TBCs的渐进破坏过程，包括垂直裂纹扩展、垂直裂纹向界面裂纹演化以及界面分层。数值分析了TBCs静态破坏机制与疲劳破坏机制的区别。模拟的断口形貌与实验观察吻合较好。在静载荷和疲劳载荷下，竖向裂纹密度越高，分层长度越短，当竖向裂纹密度足够大时，界面不发生分层。研究结果为纵向裂缝密度对界面分层的影响提供了重要的依据，保证适当的纵向裂缝密度可以提高TBCs的耐久性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Applied Mechanics MECHANICS-

CiteScore

5.80

自引率

11.40%

发文量

116

审稿时长

3 months

期刊介绍： The journal has as its objective the publication and wide electronic dissemination of innovative and consequential research in applied mechanics. IJAM welcomes high-quality original research papers in all aspects of applied mechanics from contributors throughout the world. The journal aims to promote the international exchange of new knowledge and recent development information in all aspects of applied mechanics. In addition to covering the classical branches of applied mechanics, namely solid mechanics, fluid mechanics, thermodynamics, and material science, the journal also encourages contributions from newly emerging areas such as biomechanics, electromechanics, the mechanical behavior of advanced materials, nanomechanics, and many other inter-disciplinary research areas in which the concepts of applied mechanics are extensively applied and developed.