Microstructure and Mechanical Properties of Two–phase Mg–10.73Li–4.49Al–0.52Y Alloy Processed by ECAP at Different Routes

Chin J Mater Res

2011, Vol. 25

Issue (5): 500-508 DOI:

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Microstructure and Mechanical Properties of Two–phase Mg–10.73Li–4.49Al–0.52Y Alloy Processed by ECAP at Different Routes

KANG Zhixin, KONG Jing, HOU Wenting, LI Yongxin

School of Mechanical & Automotive Engineering, South China University of Technology, National Engineering Research Center of Near–Net–Shape Forming for Metallic Materials, Guangzhou 510640

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KANG Zhixin KONG Jing HOU Wenting LI Yongxin. Microstructure and Mechanical Properties of Two–phase Mg–10.73Li–4.49Al–0.52Y Alloy Processed by ECAP at Different Routes. Chin J Mater Res, 2011, 25(5): 500-508.

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Abstract The extrusion deformation at 573 K was performed on two–phase Mg–10.73Li–4.49Al–0.52Y magnesium–lithium alloy processed by equal channel angular pressing (ECAP) from 1 pass to 4 passes through routes Bc, A and C. The pressed microstructures were investigated by using OM, SEM and XRD. The results show that the grains of both α and β phases are significantly elongated and refined after ECAP deformation with different routes. After 4 passes, flaky grains were obtained for route A, equiaxed grains were gained for route C, and structures alternated with equiaxed and lath–like features were observed for route Bc. The mechanical tensile test at room temperature indicates that route Bc gets good integrated mechanical properties, whose elongation is up to 70%. The texture of {110} crystal plane for β phase reveals that different changes exist among three pressing routes with ECAP passes, but textures of all three routes become softening, therefore the tensile strength decreases correspondingly as the texture softening is more effective than grain refining.

Key words: metallic materials Mg–Li alloy ECAP deformation route microstructure texture mechanical property

Received: 23 June 2011

ZTFLH:	TG146
	TG376

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Supported by Guangzhou Science and Technology Development Program No.2009Z2–D811.

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https://www.cjmr.org/EN/ OR https://www.cjmr.org/EN/Y2011/V25/I5/500

1 Z.Drozd, Z.Trojanov´a, S.K´udela, Deformation behaviour of Mg–Li–Al alloys, Journal of Alloys and Compounds, 378(1–2), 192(2004)

2 F.R.Cao, H.Ding, Y.L.Li, G.Zhou, J.Z. Cui, Superplasticity, dynamic grain growth and deformation mechanism in ultra–light two–phase magnesium–lithium alloys, Materials Science and Engineering, A527(9), 2335(2010)

3 J.F.Mason, C.M.Warwick, P.J.Smith, J.A.Charles, T.W.Clyne, Magnesium–lithium alloys in metal matrix composites–A preliminary report, Journal of Materials Science, 24(11), 3934(1989)

4 KANG Zhixin, PENG Yonghui, SANG Jing, JIAN Weiwei, ZHAO Haidong, LI Yuanyuan, Superplasticity and microstructure evolution in Mg–1.5Mn–0.3Ce alloy deformation by T–shape channel pressing, Acta Metallurgica Sinica, 45(9), 1117(2009)

(康志新, 彭勇辉, 桑静, 简炜炜, 赵海东, 李元元, T型通道挤压变形Mg--1.5Mn--0.3Ce合金的超塑性和组织演变, 金属学报, 45(9), 1117(2009))

5 KANG Zhixin, PENG Yonghui, LAI Xiaoming, LI Yuanyuan, ZHAO Haidong, ZHANG Weiwen, Research status and application prospect of ultrafine grained and/or nano–crystalline metallic materials processed by severe plastic deformation, The Chinese Journal of Nonferrous Metals, 20(4), 587(2010)

(康志新, 彭勇辉, 赖晓明, 李元元, 赵海东, 张卫文, 剧塑性变形制备超细晶/纳米晶结构金属材料的研究现状和应用展望, 中国有色金属学报, 20(4), 587(2010))

6 I.Balasundar, M.S.Rao, T.Raghu, Equal channel angular pressing die to extrude a variety of materials, Materials and Design, 30(4), 1050(2009)

7 K.Nakashima, Z.Horita, M.Nemoto, T.G.Langdon, Influence of channel angle on the development of ultrafine grains in equal channel angular pressing, Acta Materialia, 46(5), 1589(1998)

8 Y.Y.Li, Y.Liu, T.Ngai, D.T.Zhang, G.W.Guo, Effects of die angle on microstructures and mechanical properties of AZ31 magnesium alloy processed by equal channel angular pressing, Transactions of Nonferrous Metals Society of China, 14(1), 53(2004)

9 LI Xiao, YANG Ping, LI Jizhong, DING Hua, Precipitation behavior, texture and mechanical properties of AZ80 magnesium alloy produced by equal channel angular extrusion, Chinese Journal of Materials Research, 24(1), 1(2010)

(李萧, 杨平, 李继忠, 丁桦, 等通道挤压AZ80镁合金的析出行为和性能, 材料研究学报, 24(1), 1(2010))

10 A.Yamashita, D.Yamaguchi, Z.Horita, T.G.Langdon, Influence of pressing temperature on microstructural development in equal channel angular pressing, Materials Science and Engineering, A287(1), 100(2000)

11 Y.C.Chen, Y.Y.Z.Horita, C.P.Chang, P.W.Kao, The effect of extrusion temperature on the development of deformation microstructures in 5052 aluminium alloy processed by equal channel angular extrusion, Acta Materialia, 51(7), 2005(2003)

12 M.Furui, C.Xu, T.Aida, M.Inoue, H.Anada, T.G.Langdon, Improving the superplastic properties of a two–phase Mg–8% Li alloy through processing by ECAP, Materials Science and ngineering, A410–411, 439(2005)

13 T.Liu, S.D.Wu, S.X.Li, P.J.Li, Microstructure evolution of Mg–14%Li–1%Al alloy during the process of equal channel angular pressing, Materials Science and Engineering, A460–461, 499(2007)

14 LIU Teng, ZHANG Wei, WU Shiding, JIANG Chuanbin, LI Shouxin, XU Yongbo, Equal channel angular pressing of a two–phase alloy Mg–8Li–1Al I. Deformation modes during ECAP, Acta Metallurgica Sinica, 39(8), 790(2003)

(刘腾, 张伟, 吴世丁, 姜传斌, 李守新, 徐永波, 双相合金Mg--8Li--1Al的等通道转角挤压 I.挤压过程中的变形方式, 金属学报, 39(8), 790(2003))

15 W.J.Kim, S.I.Hong, Y.S.Kim, S.H.Min, H.T.Jeong, J.D.Lee, Texture development and its effect on mechanical properties of an AZ61 Mg alloy fabricated by equal channel angular pressing, Acta Materialia, 51(11), 3293(2003)

16 R.Z.Valiev, T.G.Langdon, Principles of equal–channel angular pressing as a processing tool for grain refinement, Progress in Materials Science, 51(7), 881(2006)

17 XIAO Jimei, Energetics of Alloys, The 1st edition, (Shanghai, Shanghai Science and Technology Press, 1985) p.257

(肖纪美, 合金能量学, 第一版, (上海, 上海科学技术出版社, 1985) p.257)

18 LI Wenxian, Magnesium and Magnesium Alloys, The 1st edition, (Changsha, Central South University Press, 2005) p.2

(黎文献, 镁及镁合金, 第一版, (长沙, 中南大学出版社, 2005) p.2)

19 K.Matsuki, T.Aida, J.Takeuchi, K.Yokoe, Microstructural characteristics and superplastic–like behavior in aluminum powder alloy consolidated by equal–channel angular pressing, Acta Materialia, 48(10), 2625(2000)

20 K.Nakashima, Z.Horita, M.Nemoto, T.G.Longdon, Development of a multi–pass facility for equal–channel angular pressing to high total strains, Materials Science and Engineering, A281(1–2), 82(2000)

21 W.J.Kim, H.G.Jeong, Mechanical properties and texture evolution in ECAP processed AZ61 Mg alloys, Materials Science Forum, 419–422, 201(2003)

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