纳米复合陶瓷刀具材料微观断裂行为模拟

IF 3.1 3区 工程技术 Q2 ENGINEERING, MECHANICAL
Tingting Zhou, Lingpeng Meng, Mingdong Yi, Chonghai Xu
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引用次数: 0

摘要

本文通过Voronoi镶嵌表征了纳米复合陶瓷刀具材料的微观结构。在微观结构模型中引入具有断裂准则的内聚单元,建立了模拟裂纹扩展的内聚单元模型。本研究同时考虑了晶间和穿晶开裂。分别分析了纳米颗粒尺寸、微观结构类型、纳米颗粒体积含量和界面断裂能的影响。模拟结果表明,纳米颗粒将单相材料的晶间断裂模式转变为晶间-穿晶-混合断裂模式。沿晶界的纳米颗粒对纳米复合陶瓷刀具材料的断裂模式变化具有重要影响。纳米颗粒越小,沿基体晶界分布的纳米颗粒越多,组织的断裂韧性越高。纳米颗粒体积含量为15%时,穿晶断裂现象最明显,临界断裂能释放率最高。强界面有助于提高纳米复合陶瓷刀具材料的断裂韧性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulation of Microscopic Fracture Behavior in Nanocomposite Ceramic Tool Materials
In this paper, the microstructures of nanocomposite ceramic tool materials are represented through Voronoi tessellation. A cohesive element model is established to perform the crack propagation simulation by introducing cohesive elements with fracture criteria into microstructure models. Both intergranular and transgranular cracking are considered in this work. The influences of nanoparticle size, microstructure type, nanoparticle volume content and interface fracture energy are analyzed, respectively. The simulation results show that the nanoparticles have changed the fracture pattern from intergranular mode in single-phase materials to intergranular–transgranular–mixed mode. It is mainly the nanoparticles along grain boundaries that have an impact on the fracture pattern change in nanocomposite ceramic tool materials. Microstructures with smaller nanoparticles, in which there are more nanoparticles dispersed along matrix grain boundaries, have higher fracture toughness. Microstructures with a nanoparticle volume content of 15% have the most obvious transgranular fracture phenomenon and the highest critical fracture energy release rate. A strong interface is useful for enhancing the fracture toughness of nanocomposite ceramic tool materials.
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来源期刊
Lubricants
Lubricants Engineering-Mechanical Engineering
CiteScore
3.60
自引率
25.70%
发文量
293
审稿时长
11 weeks
期刊介绍: This journal is dedicated to the field of Tribology and closely related disciplines. This includes the fundamentals of the following topics: -Lubrication, comprising hydrostatics, hydrodynamics, elastohydrodynamics, mixed and boundary regimes of lubrication -Friction, comprising viscous shear, Newtonian and non-Newtonian traction, boundary friction -Wear, including adhesion, abrasion, tribo-corrosion, scuffing and scoring -Cavitation and erosion -Sub-surface stressing, fatigue spalling, pitting, micro-pitting -Contact Mechanics: elasticity, elasto-plasticity, adhesion, viscoelasticity, poroelasticity, coatings and solid lubricants, layered bonded and unbonded solids -Surface Science: topography, tribo-film formation, lubricant–surface combination, surface texturing, micro-hydrodynamics, micro-elastohydrodynamics -Rheology: Newtonian, non-Newtonian fluids, dilatants, pseudo-plastics, thixotropy, shear thinning -Physical chemistry of lubricants, boundary active species, adsorption, bonding
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