| 基于元胞自动机AZ31镁合金固溶处理研究 |
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| 引用本文: | 楚志兵,李伟,王环珠,薛占元,李玉贵,刘光明,胡建华.基于元胞自动机AZ31镁合金固溶处理研究[J].四川大学学报(工程科学版),2019,51(2):185-192. |
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| 作者姓名: | 楚志兵 李伟 王环珠 薛占元 李玉贵 刘光明 胡建华 |
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| 作者单位: | 太原科技大学 重型机械教育部工程研究中心, 山西 太原 030024;暨南大学 力学与建筑工程学院, 广东 广州 510632,太原科技大学 重型机械教育部工程研究中心, 山西 太原 030024,太原科技大学 重型机械教育部工程研究中心, 山西 太原 030024,太原科技大学 重型机械教育部工程研究中心, 山西 太原 030024,太原科技大学 重型机械教育部工程研究中心, 山西 太原 030024,太原科技大学 重型机械教育部工程研究中心, 山西 太原 030024,太原科技大学 重型机械教育部工程研究中心, 山西 太原 030024 |
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| 基金项目: | 国家自然科学基金资助项目(U1710113;U1610256);中国博士后科学基金资助项目(2017M622903);山西省留学基金资助项目(2017-081);山西省自然科学基金资助项目(201601D011051);山西省重点研发计划重点项目资助(201703D111003;201703D111002);山西省重点研发计划一般项目资助(201703D121008);山西省研究生优秀创新项目资助(2017SY077) |
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| 摘 要: | 镁合金具有导热导电性好、电磁屏蔽性能优越、与环境相容性良好等诸多优点。但是镁合金在室温下塑性较差,导致其在轧制过程中易出现裂纹从而影响其质量。为了有效提高其可塑性,在加工前往往需要对其进行固溶处理。基于此,通过金相实验,得到AZ31镁合金管材原始晶粒组织,基于晶粒长大的热力学机制、曲率驱动机制和能量耗散机制,建立元胞自动机模型,针对镁合金建立了三大晶粒演变规则,研究AZ31镁合金在不同温度和不同时间下晶粒演变规律与边数变化情况,最终获得晶粒均匀分布且以六边形为主的微观组织。通过晶粒长大拓扑学分析与晶粒尺寸分布统计,得出晶粒尺寸在不同温度和时间内呈正态分布,其中六边形晶粒最多;在此基础上,建立固溶情况下的晶粒长大数学模型,合理预测并控制AZ31镁合金固溶后的晶粒尺寸和最终性能,分析了晶粒长大动力学,得出镁合金生长指数为0.87,并通过实验验证了元胞自动机模型的正确性和合理性,为研究镁合金在变形过程中的晶粒演变奠定基础。
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| 关 键 词: | AZ31镁合金 元胞自动机 固溶 晶粒尺寸 |
| 收稿时间: | 2018/7/6 0:00:00 |
| 修稿时间: | 2018/9/26 0:00:00 |
Research of Solution Treatment of AZ31 Magnesium Alloy Based on Cellular Automata |
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| CHU Zhibing,LI Wei,WANG Huanzhu,XUE Zhanyuan,LI Yugui,LIU Guangming and HU Jianhua.Research of Solution Treatment of AZ31 Magnesium Alloy Based on Cellular Automata[J].Journal of Sichuan University (Engineering Science Edition),2019,51(2):185-192. |
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| Authors: | CHU Zhibing LI Wei WANG Huanzhu XUE Zhanyuan LI Yugui LIU Guangming and HU Jianhua |
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| Affiliation: | Heavy Machinery Eng. Research Center of Ministry of Education,Taiyuan Univ. of Sci. and Technol., Taiyuan 030024;School of Mechanics and Civil Eng., Jinan Univ., Guangzhou 510632, China,Heavy Machinery Eng. Research Center of Ministry of Education,Taiyuan Univ. of Sci. and Technol., Taiyuan 030024,Heavy Machinery Eng. Research Center of Ministry of Education,Taiyuan Univ. of Sci. and Technol., Taiyuan 030024,Heavy Machinery Eng. Research Center of Ministry of Education,Taiyuan Univ. of Sci. and Technol., Taiyuan 030024,Heavy Machinery Eng. Research Center of Ministry of Education,Taiyuan Univ. of Sci. and Technol., Taiyuan 030024,Heavy Machinery Eng. Research Center of Ministry of Education,Taiyuan Univ. of Sci. and Technol., Taiyuan 030024 and Heavy Machinery Eng. Research Center of Ministry of Education,Taiyuan Univ. of Sci. and Technol., Taiyuan 030024 |
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| Abstract: | Compared with traditional steel, magnesium alloy has many advantages such as small density, lightweight, high specific strength, high specific stiffness, good thermal conductivit and comprehensive performance and it has good application and broad prospects in petrochemical and information industry. However, it is poorly plastic at room temperature, which leads to cracks in the rolling process and affects their quality, therefore it is required to be solution-treated to improve its plasticity before processing. Taking into account this, the original grain structure of AZ31 magnesium alloy tube was obtained by metallographic experiment. Based on the thermodynamic mechanism of grain growth, the mechanism of curvature driving and the energy dissipation mechanism, a cellular automata model and three major grain evolution rules was established. And the grain evolution and edge number of AZ31 magnesium alloy at different temperatures and different times were studied. Finally, the microstructure with uniform grain distribution and hexagonal shape was obtained. Through the topological analysis of grain growth and grain size distribution statistics, it was found that the grain size is normally distributed at different temperatures and times, with hexagonal grains being the most. On this basis, the mathematical model of grain growth under the solid solution condition was established, and its grain size and final properties after solid solution were reasonably predicted and controlled. The analysis of the kinetics of grain growth showed that the growth index of magnesium alloy is 0.87. The correctness and rationality of the cellular automaton model were verified by experiments, which laid a foundation for studying the grain evolution of magnesium alloy during deformation. |
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| Keywords: | AZ31 magnesium alloy cellular automata solid solution grain size |
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