双金属热压缩复合行为及界面组织演变

李宇焕; 秦芳诚; 刘崇宇; 亓海全; 王鑫; 翁凯航

doi:10.15980/j.tzzz.2021.11.021

研究·复合材料 | 浏览量 : 0 下载量: 82 CSCD: 0

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双金属热压缩复合行为及界面组织演变
Hot Compression Composited Behavior and Interface Microstructure Evolution of Bimetal
2021年41卷第11期页码：1430-1435
纸质出版日期： 2021 ，
DOI： 10.15980/j.tzzz.2021.11.021

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李宇焕, 秦芳诚, 刘崇宇, 等. 双金属热压缩复合行为及界面组织演变[J]. 特种铸造及有色合金杂志, 2021,41(11):1430-1435.

Li Yuhuan, Qin Fangcheng, Liu Chongyu, et al. Hot Compression Composited Behavior and Interface Microstructure Evolution of Bimetal[J]. Special Casting & Nonferrous Alloys, 2021,41(11):1430-1435.
李宇焕, 秦芳诚, 刘崇宇, 等. 双金属热压缩复合行为及界面组织演变[J]. 特种铸造及有色合金杂志, 2021,41(11):1430-1435. DOI： 10.15980/j.tzzz.2021.11.021.

Li Yuhuan, Qin Fangcheng, Liu Chongyu, et al. Hot Compression Composited Behavior and Interface Microstructure Evolution of Bimetal[J]. Special Casting & Nonferrous Alloys, 2021,41(11):1430-1435. DOI： 10.15980/j.tzzz.2021.11.021.

摘要

采用ABAQUS有限元软件对40Cr/Q345B双金属在不同变形温度、应变速率和变形量下进行热压缩模拟研究

分析热压缩过程中双金属界面等效应变、残余应力和温度场的变化

探讨变形参数对界面复合效果的影响。结果表明

热压缩温度较高时

双金属界面的回复和再结晶程度增大

有利于界面结合;增大变形量可以增加界面结合程度;减小应变速率使热压缩复合时间增加

界面反应更充分

进而提高界面结合效果;通过正交试验法确定了最佳试验参数

变形温度为1 150℃、应变速率为0.1 s

-1

和变形量为65%。结果发现

双金属结合界面元素扩散充分

结合层厚度约为22μm

界面冶金结合良好。

Abstract

The 40 Cr/Q345 B bimetal was compressed and simulated by ABAQUS finite element software under different deformation temperature

strain rate and deformation. The changing law of equivalent strain

residual stress and temperature distributions in bimetal interface were analyzed

and the effects of deformation parameters on the composited interface were explored. The results indicate that the degree of interface recovery and recrystallization are increased at a higher temperature

which is beneficial to interface bonding

and the degree of interface bonding is enhanced with the deformation strain increasing. As the rate increases

the composited time is prolonged and interface reaction is sufficient

further strengthening the degree of interface bonding. By means of orthogonal tests

the optimum temperature of 1 150 ℃

strain rate of 0.1 s

-1

and strain of 65% are provided. The experimental results reveal that the element diffusion in bimetal interface is sufficient with a thickness of 22 μm

achieving desirable metallurgical bonding.