Ti-6Al-4V合金的送丝增材制造第二部分。机械性能

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Uspekhi Fiziki Metallov-Progress in Physics of Metals Pub Date : 2023-03-01 DOI:10.15407/ufm.24.01.038

M. Vasylyev, B. Mordyuk, S. Voloshko

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引用次数: 3

摘要

目前，对金属增材制造(AM)应用的兴趣，也称为3D打印，在工业和手术的各个领域都有大量增长。与传统的减法技术相比，增材制造具有复杂几何形状的高度定制零件而不会造成显著的额外成本，具有显著的多重优势。目前，几种基于粉末的金属3D打印增材制造技术正在发展中，特别是选择性激光烧结(SLS)、选择性激光熔化(SLM)和电子束熔化(EBM)。在过去的几十年里，越来越多的研究和开发致力于Ti-6Al-4V合金零件的基于送丝的3D打印生产，在航空航天、汽车、能源、海洋工业以及假肢和骨科植入物的生产等不同领域得到了广泛的研究。由于与基于粉末的增材制造相比，基于线材的增材制造(WFAM)具有经济生产大型金属部件的可行性，并且具有相对较高的沉积速率、较低的机械成本、较高的材料效率和较短的交货时间，因此它具有生产中等几何复杂度的大型部件的能力，正在引起工业界和学术界的极大关注。近年来，根据熔丝加热源的不同，研究了三种不同的WFAM方法:线+电弧增材制造(WAAM);线激光增材制造(WLAM)和线电子束增材制造(WEBAM)。本文系统分析了电弧、激光和电子束三种加热熔融源下WFAM 3d打印Ti-6Al-4V合金样品的力学性能。特别考虑到2013-2020年的文献数据，对样品在印刷和后处理条件下的屈服强度、抗拉强度、伸长率和硬度等重要性能进行了分析。

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Wire-Feeding Based Additive Manufacturing of the Ti–6Al–4V Alloy. Part II. Mechanical Properties

Currently, the interest in the application of metal additive manufacturing (AM), also known as 3D printing, is grown massively in the various fields of the industry and surgery. AM has significant multiple advantages compared to traditional subtractive technologies for making highly customized parts with complex geometries without causing noteworthy extra costs. Now, several powder-based AM technologies for metals’ 3D printing are in progress, in particular, selective laser sintering (SLS), selective laser melting (SLM), and electron-beam melting (EBM). In the past few decades, increasing research and developments are devoted to the wire-feeding-based 3D printing production of parts made of the Ti–6Al–4V alloy, which is widely investigated in different fields such as aerospace, automotive, energy, and marine industries as well as the prosthetics and the production of orthopaedic implants. Due to the feasibility of economical producing large-scale metal components with relatively high deposition rate, low machinery cost, high material efficiency, and shortened lead-time compared to powder-based AM, wire-feeding-based AM (WFAM) is attracting significant attention in the industry and academia owing to its ability for the production of the large components of the medium geometric complexity. In recent years, three options of WFAM are intensively researched, which differ by the wire-melting heating sources: wire + arc additive manufacturing (WAAM); wire-laser AM (WLAM), and wire electron-beam additive manufacturing (WEBAM). The purpose of the present review is systematic analysis of the mechanical properties of the Ti–6Al–4V alloy samples 3D-printed by WFAM with various heating melting sources, namely, arc, laser, and electron beam. Particularly, considering the literature data for the period of 2013–2020, such important properties as yield strength, tensile strength, elongation, and hardness are analysed for the samples in the as-printed and post-processed conditions.

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来源期刊

Uspekhi Fiziki Metallov-Progress in Physics of Metals Multiple-

CiteScore

3.10

自引率

18.80%

发文量

审稿时长

13 weeks

期刊介绍： The review journal Uspehi Fiziki Metallov (abbreviated key-title: Usp. Fiz. Met.) was founded in 2000. In 2018, the journal officially obtained parallel title Progress in Physics of Metals (abbreviated title — Prog. Phys. Met.). The journal publishes articles (that has not been published nowhere earlier and are not being considered for publication elsewhere) comprising reviews of experimental and theoretical results in physics and technology of metals, alloys, compounds, and materials that possess metallic properties; reviews on monographs, information about conferences, seminars; data on the history of metal physics; advertising of new technologies, materials and devices. Scope of the Journal: Electronic Structure, Electrical, Magnetic and Optical Properties; Interactions of Radiation and Particles with Solids and Liquids; Structure and Properties of Amorphous Solids and Liquids; Defects and Dynamics of Crystal Structure; Mechanical, Thermal and Kinetic Properties; Phase Equilibria and Transformations; Interphase Boundaries, Metal Surfaces and Films; Structure and Properties of Nanoscale and Mesoscopic Materials; Treatment of Metallic Materials and Its Effects on Microstructure and Properties.