吴宗河等:热轧7075/AZ31B复合板的显微组织及结合性能 627 temperature formability of Mg AZ31 by high speed friction stir [18]Chen Z J,Zeng Z,Huang G J,et al.Research on the Al/Mg/Al processing.Mater Des,2014,54:980 three-layer clad sheet fabricated by hot roll bonding technology. 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Acta Metall Sinica (English Lett), 2017, 30(10): 983 [11] Zhang J, Chi C Z, Cui X L, et al. Microstructure and mechanical properties of 5052/AZ31B/5052 three-layer composite sheet prepared by hot pressing. Forging Stamping Technol, 2018, 43(12): 136 (张晶, 池成忠, 崔晓磊, 等. 热压制备5052/AZ31B/5052三层复 合板材的微观组织与力学性能. 锻压技术, 2018, 43(12):136) [12] Jafarian M, Rizi M S, Jafarian M, et al. Effect of thermal tempering on microstructure and mechanical properties of MgAZ31/Al-6061 diffusion bonding. Mater Sci Eng A, 2016, 666: 372 [13] Luo C Z, Liang W, Li X R, et al. Study on interface characteristics of Al/Mg/Al composite plates fabricated by two-pass hot rolling. Mater Sci Forum, 2013, 747: 346 [14] Zhang J J. Preparation of Al/Mg/Al Laminated Composite Fabricated by Hot Rolled and Investigation of Microstructure and Mechanical Properties[Dissertation]. Taiyuan: Taiyuan University of Technology, 2016 (张建军. Al/Mg/Al热轧复合板的制备及其微观组织和力学性能 研究[学位论文]. 太原: 太原理工大学, 2016) [15] Zhang X P, Tan M J, Yang T H, et al. Bonding strength of Al/Mg/Al alloy tri-metallic laminates fabricated by hot rolling. Bull Mater Sci, 2011, 34(4): 805 [16] Zhang X P, Yang T H, Liu J Q, et al. Mechanical properties of an Al/Mg/Al trilaminated composite fabricated by hot rolling. J Mater Sci, 2010, 45(13): 3457 [17] Chen Z J, Zeng Z, Huang G J, et al. Research on the Al/Mg/Al three-layer clad sheet fabricated by hot roll bonding technology. Rare Met Mater Eng, 2011, 40(Suppl 3): 136 [18] Liu C Y, Wang Q, Jia Y Z, et al. Microstructures and mechanical properties of Mg/Mg and Mg/Al/Mg laminated composites prepared via warm roll bonding. Mater Sci Eng A, 2012, 556: 1 [19] Yang X Y, Zhang Z L, Zhang L, et al. Influence of strain rate on dynamic recrystallization behavior of AZ61 magnesium alloy. Trans Nonferrous Met Soc China, 2011, 21(8): 1801 (杨续跃, 张之岭, 张雷, 等. 应变速率对AZ61镁合金动态再结晶 行为的影响. 中国有色金属学报, 2011, 21(8):1801) [20] Maksoud I A, Ahmed H, Rödel J. Investigation of the effect of strain rate and temperature on the deformability and microstructure evolution of AZ31 magnesium alloy. Mater Sci Eng A, 2009, 504(1-2): 40 [21] Santosh R, Das S K, Das G, et al. Three-dimensional thermomechanical simulation and experimental validation on failure of dissimilar material welds. Metall Mater Trans A, 2016, 47(7): 3511 [22] Duan X J, Sheppard T. Simulation and control of microstructure evolution during hot extrusion of hard aluminium alloys. Mater Sci Eng A, 2003, 351(1-2): 282 [23] Sauvage X, Dinda G P, Wilde G. Non-equilibrium intermixing and phase transformation in severely deformed Al/Ni multilayers. Scripta Mater, 2007, 56(3): 181 [24] Chung C Y, Zhu M, Man C H. Effect of mechanical alloying on the solid state reaction processing of Ni-36.5 at.% Al alloy. Intermetallics, 2002, 10(9): 865 [25] Valiev R Z, Islamgaliev R K, Alexandrov I V. Bulk nanostructured materials from severe plastic deformation. Progr Mater Sci, 2000, 45(2): 103 [26] Sauvage X, Wetscher F, Pareige P. Mechanical alloying of Cu and Fe induced by severe plastic deformation of a Cu –Fe composite. Acta Mater, 2005, 53(7): 2127 [27] Sato K, Yoshiie T, Satoh Y, et al. Simulation of vacancy migration energy in Cu under high strain. Mater Sci Eng A, 2003, 350(1-2): 220 [28] 吴宗河等: 热轧 7075/AZ31B 复合板的显微组织及结合性能 · 627 ·