Microstructure Evolution Mechanism of AISI 1045 Steel Under High Speed Deformation

IF 0.7 4区材料科学 Q4 METALLURGY & METALLURGICAL ENGINEERING

Archives of Metallurgy and Materials Pub Date : 2023-12-19 DOI:10.24425/amm.2023.146219

Lingen Luo, Jianming Pang, Yaoxin Song, ShuLan Liu, hao Peng, Chunlei Pu, Yinhe Lin, Jingwei Li, Shi

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引用次数: 0

Abstract

aiSi 1045 steel has the characteristics of high strain rate, large strain, and sharp rise in temperature during high-speed deformation process, resulting in a concentrated deformation band and fine structure. in this work, the microstructure of submicron-sized grains in aiSi 1045 steel material formed under 10 6 s –1 during a high speed cutting process was examined. To reveal the dynamic evolution mechanism of the aiSi 1045 microstructure, the continuous dynamic recrystallization theory was introduced. The results show a high dislocation density which favor the formation of small angle grain boundaries during the high speed cutting process. Kinetics calculations that use continuous dynamic recrystallization mechanisms prove that the recrystallization size is constant when the strain rate increases from 10 3 s –1 to 10 6 s –1 , and the transition time is reduced from 6×10 –5 s to 4×10 –8 s. The recrystallization grains were gradually formed during the deformation of the material, not generated after the deformation.

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高速变形下 AISI 1045 钢的显微组织演变机理

aiSi 1045 钢在高速变形过程中具有应变率高、应变量大、温度急剧升高的特点，从而形成了集中的变形带和精细的组织结构。本文研究了 aiSi 1045 钢材料在 10 6 s -1 高速切削过程中形成的亚微米尺寸晶粒的微观组织结构。为了揭示 aiSi 1045 显微结构的动态演化机制，引入了连续动态再结晶理论。结果表明，在高速切削过程中，高位错密度有利于小角度晶界的形成。利用连续动态再结晶机制进行的动力学计算证明，当应变速率从 10 3 s -1 增加到 10 6 s -1 时，再结晶尺寸不变，过渡时间从 6×10 -5 s 缩短到 4×10 -8 s。

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

Archives of Metallurgy and Materials 工程技术-冶金工程

CiteScore

1.20

自引率

0.00%

发文量

审稿时长

4.5 months

期刊介绍： The Archives of Metallurgy and Materials is covered in the following Institute for Scientific Information products: SciSearch (the Science Citation Index - Expanded), Research Alert, Materials Science Citation Index, and Current Contents / Engineering, Computing and Technology. Articles published in the Archives of Metallurgy and Materials are also indexed or abstracted by Cambridge Scientific Abstracts.