Machining of long ceramic fibre reinforced metal matrix composites – How could temperature influence the cutting mechanisms?

IF 14 1区 工程技术 Q1 ENGINEERING, MANUFACTURING
Shusong Zan, Zhirong Liao, Jose A. Robles-Linares, Gonzalo Garcia Luna, Dragos Axinte
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引用次数: 4

Abstract

Metal matrix composites (MMCs) offer a unique set of properties due to the ductile-brittle combination produced by the matrix and the reinforcements. Conventional MMCs are usually particle-reinforced, and their cutting mechanisms have been thoroughly studied, showing that they tend to follow traditional cutting theory as the particles roll within the surface/chip or are pushed in/pulled out of the machined surfaces. However, while the enforcement mechanism is quite unique in fibre reinforced MMCs, very little is known about the cutting mechanisms of this kind of materials. These materials are distinguished for having a, roughly, one-to-one scale alternation of the ductile (i.e., matrix) and hard/brittle (i.e., ceramic fibres) phases; key characteristic that is likely to heavily influence the material removal mechanism. Further, there is an open question on how the (temperature-dependent) stiffness of the matrix would affect the cutting mechanism when considering the hybrid machining process (e.g., heat assisted/cryogenic machining) to improve their machinability. To elucidate these aspects, here, by means of cutting a SiCf/Ti-6Al-4V MMC, the following particularities/peculiarities of the cutting mechanism of these structures are reported: (1) the chip formation includes, up to now unobserved, extrusion of the ductile component of the MMC (Ti-6Al-4V matrix) between the fractured hard phase (SiC); (2) the properties and deformation mechanisms of the matrix (adjusted by temperature control: −180 °C; 24 °C; 400 °C) will affect the crack initiation of the SiC hard/brittle fibre which is manifested underneath the machined surface. Thus, this work is unique in its approach as it opens the understanding of how these complex and heterogeneous structures could be “activated” (e.g., by thermal means to change the stiffness of a particular phase) for improved cutting conditions.

Abstract Image

长陶瓷纤维增强金属基复合材料的加工。温度如何影响切削机制?
金属基复合材料(MMCs)由于基体和增强体产生的韧性-脆性组合而提供了一系列独特的性能。传统的MMC通常是颗粒增强的,并且已经对其切削机理进行了彻底的研究,表明当颗粒在表面/芯片内滚动或被推入/拉出加工表面时,它们倾向于遵循传统的切削理论。然而,尽管纤维增强MMCs的强化机制非常独特,但对这类材料的切割机制知之甚少。这些材料的特点是具有韧性(即基体)和硬/脆性(即陶瓷纤维)相的大致一对一的比例交替;可能严重影响材料去除机制的关键特性。此外,在考虑混合加工工艺(例如,热辅助/低温加工)以提高其可加工性时,基体的(温度相关的)刚度将如何影响切削机制,这是一个悬而未决的问题。为了阐明这些方面,本文通过切割SiCf/Ti-6Al-4V MMC,报道了这些结构的切割机制的以下特殊性/特性:(1)切屑的形成包括,到目前为止尚未观察到的,MMC的韧性组分(Ti-6Al-6V基体)在断裂的硬相(SiC)之间的挤压;(2) 基体的性质和变形机制(通过温度控制进行调整:−180°C;24°C;400°C)将影响SiC硬/脆纤维的裂纹萌生,该裂纹在加工表面下表现出来。因此,这项工作的方法是独特的,因为它开启了对如何“激活”这些复杂和异质结构(例如,通过热手段改变特定相的刚度)以改善切削条件的理解。
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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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