Mechanism and Inhibition of Grain Coarsening of Al-Mg-Si Alloy in Hot Forming 被引量：4

Mechanism and Inhibition of Grain Coarsening of Al-Mg-Si Alloy in Hot Forming

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摘要 A high-Ti 6061 alloy was rolled with strains up to 0. 8 - 2. 0 and at 350 - 550 ℃ . Microstructures that developed during deformation and subsequent solution heat treatment (SHT) were observed by using optical and transmission electron microscopy. Microstructure evolution during SHT depends mainly on the initial rolling temperature,and it was found that the higher this temperature is,the coarser the grains are. After rolling at 400 ℃ ,well-defined cells and subgrains were formed, which induced further sites for recrystallization nucleation during subsequent SHT. The recrystallization mechanism was found to be subgrain rotation,with a final grain size smaller than 200 μm. Increasing the rolling temperature to 500 ℃ results in a low density of dislocations distributed uniformly in the deformed matrix and fewer nucleation sites during subsequent SHT. The recrystallization mechanism is grain boundary bulging,while the final grain size approaches several millimeters. Finally,a hot forming process of high-Ti 6061 alloy for inhibiting grain coarsening was proposed,and verified by experiments. A high-Ti 6061 alloy was rolled with strains up to 0. 8 - 2. 0 and at 350 - 550 ℃ . Microstructures that developed during deformation and subsequent solution heat treatment （SHT） were observed by using optical and transmission electron microscopy. Microstructure evolution during SHT depends mainly on the initial rolling temperature,and it was found that the higher this temperature is,the coarser the grains are. After rolling at 400 ℃ ,well-defined cells and subgrains were formed, which induced further sites for recrystallization nucleation during subsequent SHT. The recrystallization mechanism was found to be subgrain rotation,with a final grain size smaller than 200 μm. Increasing the rolling temperature to 500 ℃ results in a low density of dislocations distributed uniformly in the deformed matrix and fewer nucleation sites during subsequent SHT. The recrystallization mechanism is grain boundary bulging,while the final grain size approaches several millimeters. Finally,a hot forming process of high-Ti 6061 alloy for inhibiting grain coarsening was proposed,and verified by experiments.

作者 Ying-Ping Guan Zhen-Hua Wang Bin Wu Wei-Xin Wang Wan-Tang Fu

机构地区 Key Laboratory of Advanced Forging & Stamping Technology and Science(Yanshan University) College of Mechanical Engineering and Applied Electronic Technology CITIC Dicastal Wheel Manufacturing Co. State Key Laboratory of Metastable Materials Science and Technology

出处《Journal of Harbin Institute of Technology(New Series)》 EI CAS 2013年第3期67-74,共8页 哈尔滨工业大学学报（英文版）

基金 Sponsored by the Project of High-level Talent of Hebei Province (Post-Doctoral Research Project of Hebei Province)

关键词 aluminum alloy grain size RECRYSTALLIZATION nucleation mechanism aluminum alloy grain size recrystallization nucleation mechanism

分类号 TG111.7 [金属学及工艺—物理冶金]

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