Surface micro-morphology model involved in grinding of GaN crystals driven by strain-rate and abrasive coupling effects

IF 14 1区 工程技术 Q1 ENGINEERING, MANUFACTURING International Journal of Machine Tools & Manufacture Pub Date : 2024-08-03 DOI:10.1016/j.ijmachtools.2024.104197
Chen Li , Kechong Wang , Yinchuan Piao , Hailong Cui , Oleg Zakharov , Zhiyu Duan , Feihu Zhang , Yongda Yan , Yanquan Geng
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Abstract

The complexity of the interaction between the workpiece and abrasives, the characterisation difficulty of the strain-rate effect, and the analytical difficulty of brittle-ductile coexistence removal pose significant challenges in surface micro-morphology modelling of brittle-solid grinding. To overcome these bottlenecks, a theoretical model of the normal scratching force driven by the strain-rate effect was developed to verify the strain-rate sensitivity coefficients of gallium nitride (GaN) crystals. Impact scratching tests with a single grit further emphasised that the brittle-to-ductile transition and subsurface damage behaviour of GaN crystals exhibited a distinct strain-rate dependence. Subsequently, a theoretical model of the surface micro-morphology involved in the grinding of GaN crystals was developed by comprehensively considering the strain rate, abrasive coupling effect, time evolution, abrasive randomness, and elastic-to-plastic and brittle-to-ductile transition depths. The simulated results of the model agreed well with the experimental results, with an average error of <10 %. The model indicated that the ground surface micro-morphology and roughness were insensitive to variations in the grinding depth. Under the allowable conditions of the grinder stiffness and dynamic balance, appropriately increasing the wheel speed and grinding depth, decreasing the feed speed, and refining the abrasive size could effectively improve the proportion of ductile removal during the grinding of brittle solids. The results not only enhance the understanding of the abrasive coupling effect on surface micro-morphological evolution, material removal, and damage accumulation, but also provide theoretical guidance for the parameter optimisation involved in the grinding of brittle solids.

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应变速率和磨料耦合效应驱动的氮化镓晶体研磨过程中涉及的表面微观形态模型
工件与磨料之间相互作用的复杂性、应变速率效应的表征难度以及脆性与韧性共存去除的分析难度给脆固磨削的表面微观形态建模带来了巨大挑战。为了克服这些瓶颈,我们建立了应变速率效应驱动的法向划痕力理论模型,以验证氮化镓(GaN)晶体的应变速率敏感系数。使用单粒砂砾进行的冲击划痕测试进一步强调了氮化镓晶体的脆性到韧性转变和表面下损伤行为表现出明显的应变速率依赖性。随后,通过综合考虑应变率、磨料耦合效应、时间演化、磨料随机性以及弹性到塑性和脆性到韧性转变深度,建立了氮化镓晶体磨削过程中表面微观形貌的理论模型。模型的模拟结果与实验结果吻合良好,平均误差小于 10%。模型表明,磨削表面的微观形态和粗糙度对磨削深度的变化不敏感。在磨床刚度和动平衡允许的条件下,适当提高砂轮转速和磨削深度,降低进给速度,细化磨料粒度,可以有效提高脆性固体磨削过程中的韧性去除比例。研究结果不仅加深了对磨料耦合效应对表面微观形貌演变、材料去除和损伤积累的理解,而且为脆性固体磨削过程中的参数优化提供了理论指导。
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来源期刊
CiteScore
25.70
自引率
10.00%
发文量
66
审稿时长
18 days
期刊介绍: The International Journal of Machine Tools and Manufacture is dedicated to advancing scientific comprehension of the fundamental mechanics involved in processes and machines utilized in the manufacturing of engineering components. While the primary focus is on metals, the journal also explores applications in composites, ceramics, and other structural or functional materials. The coverage includes a diverse range of topics: - Essential mechanics of processes involving material removal, accretion, and deformation, encompassing solid, semi-solid, or particulate forms. - Significant scientific advancements in existing or new processes and machines. - In-depth characterization of workpiece materials (structure/surfaces) through advanced techniques (e.g., SEM, EDS, TEM, EBSD, AES, Raman spectroscopy) to unveil new phenomenological aspects governing manufacturing processes. - Tool design, utilization, and comprehensive studies of failure mechanisms. - Innovative concepts of machine tools, fixtures, and tool holders supported by modeling and demonstrations relevant to manufacturing processes within the journal's scope. - Novel scientific contributions exploring interactions between the machine tool, control system, software design, and processes. - Studies elucidating specific mechanisms governing niche processes (e.g., ultra-high precision, nano/atomic level manufacturing with either mechanical or non-mechanical "tools"). - Innovative approaches, underpinned by thorough scientific analysis, addressing emerging or breakthrough processes (e.g., bio-inspired manufacturing) and/or applications (e.g., ultra-high precision optics).
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