分别在空气、循环水和干冰酒精混合溶液中对AZ31镁合金板进行搅拌摩擦加工,研究了冷却介质对AZ31镁合金搅拌摩擦加工组织和性能的影响.结果表明:搅拌摩擦加工过程中峰值温度和150℃以上持续时间按照空气、循环水、干冰酒精混合溶液顺序依次递减.冷却介质对晶粒长大抑制效果明显,空气、循环水、干冰酒精混合溶液中搅拌区晶粒大小分别为3.9,3.0,1.8μm,和峰值温度变化趋势一致.由于晶界滑移的主导作用,干冰酒精混合溶液中搅拌区的硬度和强度低于循环水中,延伸率最高.空气和循环水冷却介质中,拉伸断口均表现为准解理断裂,但循环水中解理断裂所占比例明显高于空气中,在干冰酒精混合溶液中拉伸断口表现为微孔聚合型断裂.
参考文献
| [1] | MISHRA R S;MAHONEY M W;McFadden S X et al.High strain rate superplasticity in a friction stir processed 7075 alloy[J].Scripta Materialia,1999,42(02):163-168. |
| [2] | R.S. Mishra;M.W. Mahoney .Friction Stir Processing: A New Grain Refinement Technique to Achieve High Strain Rate Superplasticity in Commercial Alloys[J].Materials Science Forum,2001(0):507-514. |
| [3] | I. Charit;R. S. Mishra .High strain rate superplasticity in a commercial 2024 Al alloy via friction stir processing[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2003(1/2):290-296. |
| [4] | Mishra RS.;Ma ZY.;Charit I. .Friction stir processing: a novel technique for fabrication of surface composite[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2003(1/2):307-310. |
| [5] | Hofmann DC;Vecchio KS .Submerged friction stir processing (SFSP): An improved method for creating ultra-fine-grained bulk materials[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2005(1/2):234-241. |
| [6] | Wei Wang;Qing-yu Shi;Peng Liu;Hong-ke Li;Ting Li .A novel way to produce bulk SiCp reinforced aluminum metal matrix composites by friction stir processing[J].Journal of Materials Processing Technology,2009(4):2099-2103. |
| [7] | S. R. Sharma;Z. Y. Ma;R. S. Mishra .Effect of friction stir processing on fatigue behavior of A356 alloy[J].Scripta materialia,2004(3):237-241. |
| [8] | Mishra RS;Ma ZY .Friction stir welding and processing[J].Materials Science & Engineering, R. Reports: A Review Journal,2005(1/2):III-0. |
| [9] | C. G. Rhodes;M. W. Mahoney;W. H. Bingel;M. Calabrese .Fine-grain evolution in friction-stir processed 7050 aluminum[J].Scripta materialia,2003(10):1451-1455. |
| [10] | SU J Q;NELSON T W;STERLING C J .Friction stir processing of large-area bulk UFG aluminum alloys[J].Scripta Materialia,2005,52(02):135-140. |
| [11] | C.I. Chang;X.H. Du;J.C. Huang .Achieving ultrafine grain size in Mg–Al–Zn alloy by friction stir processing[J].Scripta materialia,2007(3):209-212. |
| [12] | Chang CI;Lee CJ;Huang JC .Relationship between grain size and Zener-Holloman parameter during friction stir processing in AZ31 Mg alloys[J].Scripta materialia,2004(6):509-514. |
| [13] | C.I. Chang;X.H. Du;J.C. Huang .Producing nanograined microstructure in Mg-Al-Zn alloy by two-step friction stir processing[J].Scripta materialia,2008(3):356-359. |
| [14] | 路君,靳丽,董杰,曾小勤,丁文江,姚真裔.等通道角挤压变形AZ31镁合金的变形行为[J].中国有色金属学报,2009(03):424-432. |
| [15] | Wang YN;Chang CI;Lee CJ;Lin HK;Huang JC .Texture and weak grain size dependence in friction stir processed Mg-Al-Zn alloy[J].Scripta materialia,2006(7):637-640. |
| [16] | 毛卫民;赵新兵.金属的再结晶与晶粒长大[M].北京:冶金工业出版社,1994:201-203. |
| [17] | Hiroyuki Watanabe;Akira Takara;Hidetoshi Somekawa .Effect of Texture on Tensile Properties at Elevated Temperatures in an AZ31 Magnesium Alloy[J].Scripta materialia,2005(6):449-454. |
| [18] | SHI J;ZIKRY M A .Grain size,grain boundary sliding,and grain boundary interaction effects on nanocrystalline behavior Materials[J].Science and Engineering (A),2009,520(1/2):121-133. |
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