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基于焊接管坯的多道次强力旋压对TiAlNb基合金微观组织均匀化及力学性能强化的影响

Effect of Multi-Pass Power Spinning on Microstructure Homogenization and Mechanical-Property Strengthening of TiAlNb-Based Alloy Using Welded Tube Blank.

作者信息

Wang Sibing, Xu Wenchen, Wang Bo, Yang Guoping, Shan Debin

机构信息

School of Materials Science and Engineering & National Key Laboratory for Precision Hot Processing of Metals, Harbin Institute of Technology, Harbin 150001, China.

Department of Technology Development, Beijing Spacecrafts, Beijing 100094, China.

出版信息

Materials (Basel). 2022 Jan 28;15(3):1013. doi: 10.3390/ma15031013.

DOI:10.3390/ma15031013
PMID:35160959
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8840336/
Abstract

Long seamless tubes of TiAlNb-based alloys are difficult to manufacture through conventional forming methods. In this study, a multi-pass power spinning process was first utilized to fabricate thin-walled tube of Ti-22Al-24Nb-0.5Mo alloy using welded thick tube blank, assisted by on-line electro-magnetic induction heating to maintain high spinning temperature during the whole spinning process. After six-pass hot power spinning at 950 ± 30 °C, the microhardness difference of BM (base metal), HAZ (heat affect zone) and FZ (fusion zone) became much smaller, and the microhardness fluctuation ΔHV dropped to 32 from 122 of the as-welded joint due to the phase composition and microstructure homogenization. The grain size of B2 phase was refined to 0.4/0.6 μm from 2.7/10.8 μm of the as-received BM/FZ, respectively. Meanwhile, the B2 phase <111>//ND texture of the as-received rolled sheet weakened during multi-pass spinning due to recrystallization, which co-existed with <001>//ND texture in final pass. The ultimate tensile strength in axial/tangential direction was increased to 1245/1299 MPa from 1206/1010 MPa of the as-received rolled sheet, respectively, mainly due to the effect of fine grain strengthening. This study provides an effective way to manufacture high-performance tubular workpieces with low cost and high efficiency.

摘要

基于TiAlNb的合金长无缝管难以通过传统成型方法制造。在本研究中,首次采用多道次强力旋压工艺,以焊接厚管坯为原料制备Ti-22Al-24Nb-0.5Mo合金薄壁管,并辅以在线电磁感应加热,以在整个旋压过程中保持较高的旋压温度。在950±30°C下进行六道次热强力旋压后,由于相组成和微观组织均匀化,母材(BM)、热影响区(HAZ)和熔合区(FZ)的显微硬度差异变得小得多,显微硬度波动ΔHV从焊态接头的122降至32。B2相的晶粒尺寸分别从原始BM/FZ的2.7/10.8μm细化至0.4/0.6μm。同时,由于再结晶,原始轧制板材的B2相<111>//ND织构在多道次旋压过程中减弱,最终道次中与<001>//ND织构共存。轴向/切向的极限抗拉强度分别从原始轧制板材的1206/1010MPa提高到1245/1299MPa,主要是由于细晶强化作用。本研究提供了一种低成本、高效率制造高性能管状工件的有效方法。

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