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用于高比功率内燃机的A356-T7铸造铝合金的变形与疲劳行为

Deformation and Fatigue Behaviour of A356-T7 Cast Aluminium Alloys Used in High Specific Power IC Engines.

作者信息

Natesan Elanghovan, Eriksson Stefan, Ahlström Johan, Persson Christer

机构信息

Department of Industrial and Materials Science, Chalmers University of Technology, 412 96 Göteborg, Sweden.

Volvo Car Corporation, Analysis and Verification, 405 31 Göteborg, Sweden.

出版信息

Materials (Basel). 2019 Sep 18;12(18):3033. doi: 10.3390/ma12183033.

DOI:10.3390/ma12183033
PMID:31540499
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6766307/
Abstract

The continuous drive towards higher specific power and lower displacement engines in recent years place increasingly higher loads on the internal combustion engine materials. This necessitates a more robust collection of reliable material data for computational fatigue life prediction to develop reliable engines and reduce developmental costs. Monotonic tensile testing and cyclic stress and strain-controlled testing of A356-T7 + 0.5 wt.% Cu cast aluminium alloys have been performed. The uniaxial tests were performed on polished test bars extracted from highly loaded areas of cast cylinder heads. The monotonic deformation tests indicate that the material has an elastic-plastic monotonic response with plastic hardening. The strain controlled uniaxial low cycle fatigue tests were run at multiple load levels to capture the cyclic deformation behaviour and the corresponding fatigue lives. The equivalent stress-controlled fatigue tests were performed to study the influence of the loading mode on the cyclic deformation and fatigue lives. The two types of tests exhibit similar fatigue lives and stress-strain responses indicating minimal influence of the mode of loading in fatigue testing of A356 + T7 alloys. The material exhibits a non-linear deformation behaviour with a mixed isotropic and kinematic hardening behaviour that saturates after the initial few cycles. There exists significant scatter in the tested replicas for both monotonic and cyclic loading.

摘要

近年来,朝着更高比功率和更小排量发动机的持续发展趋势,给内燃机材料带来了越来越高的负荷。这就需要收集更全面、可靠的材料数据,用于计算疲劳寿命预测,以开发可靠的发动机并降低开发成本。已对A356-T7 + 0.5 wt.% Cu铸造铝合金进行了单调拉伸试验以及循环应力和应变控制试验。单轴试验是在从铸造气缸盖高负荷区域提取的抛光试棒上进行的。单调变形试验表明,该材料具有弹塑性单调响应和塑性硬化。应变控制的单轴低周疲劳试验在多个载荷水平下进行,以获取循环变形行为和相应的疲劳寿命。进行了等效应力控制疲劳试验,以研究加载方式对循环变形和疲劳寿命的影响。这两种类型的试验表现出相似的疲劳寿命和应力-应变响应,表明加载方式对A356 + T7合金疲劳试验的影响最小。该材料表现出非线性变形行为,具有各向同性和运动硬化混合的行为,在最初几个循环后达到饱和。对于单调加载和循环加载,测试复制品中都存在显著的离散性。

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