材料科学
碎屑形成
可加工性
机械加工
钛合金
有限元法
本构方程
绝热剪切带
流动应力
冶金
碳化物
钛
复合材料
粘塑性
应变硬化指数
剪切(物理)
硬化(计算)
软化
合金
结构工程
刀具磨损
工程类
图层(电子)
作者
Mohammad Sima,Tuğrul Özel
标识
DOI:10.1016/j.ijmachtools.2010.08.004
摘要
Titanium alloys present superior properties such as high strength-to-weight ratio and resistance to corrosion but, possess poor machinability. In this study, influence of material constitutive models and elastic–viscoplastic finite element formulation on serrated chip formation for modeling of machining Ti–6Al–4V titanium alloy is investigated. Temperature-dependent flow softening based modified material models are proposed where flow softening phenomenon, strain hardening and thermal softening effects and their interactions are coupled. Orthogonal cutting experiments have been conducted with uncoated carbide (WC/Co) and TiAlN coated carbide cutting tools. Temperature-dependent flow softening parameters are validated on a set of experimental data by using measured cutting forces and chip morphology. Finite Element simulations are validated with experimental results at two different rake angles, three different undeformed chip thickness values and two different cutting speeds. The results reveal that material flow stress and finite element formulation greatly affects not only chip formation mechanism but also forces and temperatures predicted. Chip formation process for adiabatic shearing in machining Ti–6Al–4V alloy is successfully simulated using finite element models without implementing damage models.
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