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[1]王琪,李智,張海軍,等.增材制造Ti6Al4V基復合材料研究進展[J].中國材料進展,2023,42(05):375-390.[doi:10.7502/j.issn.1674-3962.202109010]
 WANG Qi,LI Zhi,ZHANG Haijun,et al.Progress in Additive Manufacturing of Ti6Al4V-Based Composites[J].MATERIALS CHINA,2023,42(05):375-390.[doi:10.7502/j.issn.1674-3962.202109010]
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增材制造Ti6Al4V基復合材料研究進展()
分享到:

中國材料進展[ISSN:1674-3962/CN:61-1473/TG]

卷:
42
期數:
2023年第05期
頁碼:
375-390
欄目:
出版日期:
2023-05-30

文章信息/Info

Title:
Progress in Additive Manufacturing of Ti6Al4V-Based Composites
文章編號:
1674-3962(2023)05-0375-16
作者:
王琪李智張海軍劉江昊
武漢科技大學 省部共建耐火材料與冶金國家重點實驗室,湖北 武漢 430081
Author(s):
WANG QiLI ZhiZHANG HaijunLIU Jianghao
The State Key Laboratory of Refractories and Metallurgy, Wuhan University of Science and Technology, Wuhan 430081, China
關鍵詞:
Ti6Al4V基復合材料增材制造原位合成陶瓷增強相加工參數顯微形貌力學性能
Keywords:
Ti6Al4V-based composite additive manufacturing in-situ form ceramic reinforcing phase processing parameter microscopic morphology mechanical properties
分類號:
TG148; TB333; TP391. 7
DOI:
10.7502/j.issn.1674-3962.202109010
文獻標志碼:
A
摘要:
Ti6Al4V基復合材料具有高楊氏模量、高比強度、良好的耐磨性和高溫耐久性等一系列優異的性能,在航空航天、汽車制造和石油化工等高端結構材料領域具有廣闊的應用前景。然而,Ti6Al4V基復合材料的傳統減材制造方法存在能耗高、效率低、工藝復雜、材料利用率低和后處理加工成本高等共性缺點,無法滿足規模化應用的需要。在此情況下,增材制造(additive manufacturing, AM)技術因具有能耗低、效率高、材料利用率高及對復雜形狀制品可實現近凈成型等優點,在制備Ti6Al4V等合金及其復合材料方面具有顯著的應用優勢和重要的科研價值。綜述了現有Ti6Al4V基復合材料的增材制造方法,包括選區激光熔融(selective laser melting, SLM)、激光定向能量沉積(laser directed energy deposition, LDED)、電子束熔融(electron beam melting, EBM)、絲材電弧增材制造(wire arc additive manufacturing, WAAM)和電子束自由成形(electron beam freeform fabrication, EBFF)法,總結了上述方法的技術原理和優缺點,以及以原位合成陶瓷增強相為主的Ti6Al4V基復合材料的適宜加工參數、顯微形貌特征及力學性能特點,并展望了增材制造Ti6Al4V基復合材料領域的技術發展趨勢。
Abstract:
Owing to their multiple outstanding properties including high Young‘s modulus, high specific strength, good wear resistance and high temperature durability, Ti6Al4V-based composites had broad prospects in various high-end structural application-fields such as aerospace, automotive manufacturing and petrochemical engineering. However, conventional subtractive manufacturing methods for preparation of Ti6Al4V-based composites were unable to satisfy the requirement of mass production, due to their common disadvantages including high energy consumption, low efficiency, complex processes, low material utilization ratio and the requirement of cost-intensive post treatments. In respect of this, additive manufacturing (AM) technology with a series of merits including low energy consumption, high efficiency, high material utilization ratio and the capability of near-net forming complex-shaped products, had obvious applicating advantage and important researching value in the field of preparing Ti6Al4V-based composites. This paper reviewes the present additive manufacturing methods for preparation of Ti6Al4Vbased composites, including selective laser melting (SLM), laser directed energy deposition (LDED), electron beam melting (EBM), wire arc additive manufacturing (WAAM)and electron beam freeform fabrication (EBFF), summarizes their technical principles and advantages/disadvantages,appropriate processing parameters, microscopic morphology characteristics and featuring mechanical properties of the Ti6Al4Vbased composites containing in-situ formed ceramic reinforcing phases, and outlooks the future development trends in the field of additive manufacturing Ti6Al4V-based composites.

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備注/Memo

備注/Memo:
收稿日期: 2021-09-13  修回日期: 2021-11-29 基金項目: 國家自然科學基金項目(52072274, 51872210
更新日期/Last Update: 2023-05-06
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