Mg-4Zn-2Al-2Sn合金动态再结晶行为动力学数值模拟

Mg-4Zn-2Al-2Sn合金动态再结晶行为动力学数值模拟

利用Gleeble 3800热模拟试验机研究ZAT422合金在变形温度为498~648 K、应变速率为0.01~5 s^-1、压下量为60%的热变形行为。基于Arrhenius方程和Avramit方程对该合金流变行为进行分析,得到变形激活能为155.652 k J/mol,并构建该合金的本构方程和动态再结晶模型。组织观察表明:变形温度低至498 K,真应变为0.9163时,合金发生不完全动态再结晶;温度升高至648 K时,较低的应变速率易导致部分晶粒的异常长大。...

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Bibliographic Details
Published in:中国有色金属学报:英文版 Vol. 28; no. 2; pp. 340 - 347
Main Author: 赵东清;杨院生;周吉学;刘玉;唐守秋
Format: Journal Article
Language:English
Published: 2018
Subjects:
Mg-4Zn-2Al-2Sn合金;热变形;流变应力;动态再结晶
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Summary:利用Gleeble 3800热模拟试验机研究ZAT422合金在变形温度为498~648 K、应变速率为0.01~5 s^-1、压下量为60%的热变形行为。基于Arrhenius方程和Avramit方程对该合金流变行为进行分析,得到变形激活能为155.652 k J/mol,并构建该合金的本构方程和动态再结晶模型。组织观察表明:变形温度低至498 K,真应变为0.9163时,合金发生不完全动态再结晶;温度升高至648 K时,较低的应变速率易导致部分晶粒的异常长大。
Bibliography:In order to have a better understanding of the hot deformation behavior of the as-solution-treated Mg-4 Zn-2 Sn-2 Al(ZAT422) alloy, a series of compression experiments with a height reduction of 60% were performed in the temperature range of 498-648 K and the strain rate range of 0.01-5 s~(-1) on a Gleeble 3800 thermo-mechanical simulator. Based on the regression analysis by Arrhenius type equation and Avrami type equation of flow behavior, the activation energy of deformation of ZAT422 alloy was determined as 155.652 k J/mol, and the constitutive equations for flow behavior and the dynamic recrystallization(DRX) kinetic model of ZAT422 alloy were established. Microstructure observation shows that when the temperature is as low as 498 K, the DRX is not completed as the true strain reaches 0.9163. However, with the temperature increasing to 648 K, the lower strain rate is more likely to result in some grains' abnormal growth.
43-1239/TG
Mg-4Zn-2Al-2Sn alloy; hot deformation; flow stress; dynamic recrystallization
Dong-qing ZHAO1,2, Yuan-sheng YANG1,2, Ji-xue ZHOU1,3, Yu LIU1, Shou-qiu TANG1,3 (1. Shandong Provincial Key Laboratory for High Strength Lightweight Metallic Materials, Advanced Materials Institute, Qilu University of Technology (Shandong Academy of Sciences), Ji'nan 250014, China; 2. Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China; 3. Shandong Engineering Research Center for Lightweight Automobiles Magnesium Alloy, Advanced Materials Institute, Qilu University of Technology (Shandong Academy of Sciences), Ji'nan 250014, China)
ISSN:1003-6326