Age-Hardening Response of AlMgZn Alloys with Cu and Ag Additions

EngRN: Metals & Alloys (Topic) Pub Date : 2020-08-01 DOI:10.2139/ssrn.3559983

Lukas Stemper, M. Tunes, P. Oberhauser, P. Uggowitzer, S. Pogatscher

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引用次数: 53

Abstract

Abstract A recurrent challenge with aluminum alloys is their longstanding trade-off between mechanical strength and formability. Recently recyclability has put further pressure on the development of single-alloy concepts for solving this challenge. This study addresses an AlMg-based system featuring additional elements to facilitate age-hardening but retaining a high Mg content for inherent pronounced strain hardening as a potential candidate. Age-hardening was enabled by T-phase based precipitation in the commercial alloy EN AW-5182 via the addition of 3.5 wt.% of Zn. The investigation shows that minor additions of Cu and Ag enhance and accelerate it. The study also compares single-step and double-step artificial aging. Hardness and tensile testing and scanning transmission electron microscopy methods were deployed to characterize the alloys investigated, mechanically and microstructurally. An alloy with added Zn, Cu and Ag showed improved strain hardening and reduced serrated flow in the soft state, while exhibiting an age-hardening response of up to 326 MPa in yield strength leading to an ultimate tensile strength of 550 MPa in peak-aged condition. The study discusses the evolution of the microstructure during artificial aging in the light of Zn, Cu and Ag additions and their effect on the precipitation process.

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添加Cu和Ag的AlMgZn合金的时效硬化响应

铝合金的一个反复出现的挑战是它们长期以来在机械强度和成形性之间的权衡。最近，可回收性给单合金概念的发展带来了进一步的压力，以解决这一挑战。本研究提出了一种基于almg的体系，该体系具有额外的元素来促进时效硬化，但保留了高Mg含量的固有明显的应变硬化，作为潜在的候选材料。在工业合金EN AW-5182中加入3.5% wt.%的Zn，通过t相析出实现时效硬化。研究表明，微量的Cu和Ag的加入增强和加速了这一过程。该研究还比较了单步和双步人工老化。采用硬度、拉伸测试和扫描透射电镜等方法对合金进行了力学和显微组织表征。添加Zn、Cu和Ag后，合金在软态下的应变硬化得到改善，锯齿状流动减少，屈服强度达到326 MPa，峰值时效状态下的极限抗拉强度达到550 MPa。研究了Zn、Cu和Ag的加入对人工时效过程中微观组织的演变及其对析出过程的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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EngRN: Metals & Alloys (Topic)

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