Towards high-temperature applications of aluminium alloys enabled by additive manufacturing

IF 16.8 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY International Materials Reviews Pub Date : 2021-07-16 DOI:10.1080/09506608.2021.1951580

Richard A. Michi, A. Plotkowski, A. Shyam, R. Dehoff, S. Babu

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引用次数: 93

Abstract

ABSTRACT Research on powder-based additive manufacturing of aluminium alloys is rapidly increasing, and recent breakthroughs in printing of defect-free parts promise substantial movement beyond traditional Al–Si–Mg) systems. One potential technological advantage of aluminium additive manufacturing, however, has received little attention: the design of alloys for use at T > ~200°C, or ~1/2 of the absolute melting temperature of aluminium. Besides offering lightweighting and improved energy efficiency through replacement of ferrous, titanium, and nickel-based alloys at 200–450°C, development of such alloys will reduce economic roadblocks for widespread implementation of aluminium additive manufacturing. We herein review the existing additive manufacturing literature for three categories of potential high-temperature alloys, discuss strategies for optimizing microstructures for elevated-temperature performance, and highlight gaps in current research. Although extensive microstructural characterisation has been performed on these alloys, we conclude that evaluations of their high-temperature mechanical properties and corrosion responses are severely deficient.

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通过增材制造实现铝合金的高温应用

摘要：对铝合金粉末增材制造的研究正在迅速增加，最近在无缺陷零件印刷方面取得的突破有望大大超越传统的Al–Si–Mg）系统。然而，铝增材制造的一个潜在技术优势很少受到关注：设计在T>~200°C或铝绝对熔融温度的1/2下使用的合金。除了通过在200–450°C下更换铁基、钛基和镍基合金来实现轻量化和提高能效外，此类合金的开发还将减少广泛实施铝增材制造的经济障碍。我们在此回顾了三类潜在高温合金的现有增材制造文献，讨论了优化高温性能微观结构的策略，并强调了当前研究中的空白。尽管对这些合金进行了广泛的微观结构表征，但我们得出的结论是，对其高温力学性能和腐蚀响应的评估严重不足。

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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来源期刊

International Materials Reviews 工程技术-材料科学：综合

CiteScore

28.50

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： International Materials Reviews (IMR) is a comprehensive publication that provides in-depth coverage of the current state and advancements in various materials technologies. With contributions from internationally respected experts, IMR offers a thorough analysis of the subject matter. It undergoes rigorous evaluation by committees in the United States and United Kingdom for ensuring the highest quality of content. Published by Sage on behalf of ASM International and the Institute of Materials, Minerals and Mining (UK), IMR is a valuable resource for professionals in the field. It is available online through Sage's platform, facilitating convenient access to its wealth of information. Jointly produced by ASM International and the Institute of Materials, Minerals and Mining (UK), IMR focuses on technologies that impact industries dealing with metals, structural ceramics, composite materials, and electronic materials. Its coverage spans from practical applications to theoretical and practical aspects of material extraction, production, fabrication, properties, and behavior.