铈、钙和电磁搅拌对AZ91镁合金显微组织与力学性能的影响
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摘要
镁合金作为结构材料具有其它材料无法比拟的优越性,但有限的机械强度限制了它的推广应用。随着镁合金在汽车工业和IT产业中的应用越来越广泛,对镁合金的研究和应用已经引起各国生产厂商的重视。实践证明,细小等轴的晶粒组织能改善其组织性能,因此找到一种实用有效的晶粒细化剂及处理工艺来细化镁合金晶粒就显得非常重要。
本论文主要针对广泛应用的AZ91合金的晶粒细化工艺及机理进行研究。在AZ91合金中分别加入稀土元素Ce、碱土元素Ca、加交流磁场分别对AZ91和AZ91+0.8%Ce电磁搅拌。对以上几种方法获得的合金组织进行金相观察,并与未处理的AZ91合金的组织进行对比。结果表明,分别加入Ce和Ca后,AZ91合金的晶粒细化效果明显,在本试验条件下,最佳含量分别为:0.8%Ce,0.1%Ca,对应的晶粒尺寸分别减小了58%、43.7%;电磁搅拌能显著细化AZ91与AZ91+0.8%Ce合金晶粒,并产生了球化作用,加入稀土后球化效果减弱,并且有针状新相出现。最佳的励磁电压范围为75~125伏特,对应的晶粒减少了52.6%、41%。此外,对细化机理作了初步探讨。对材料的力学性能进行了测试并与未加细化剂的合金进行比较,表明晶粒细化可明显提高合金的力学性能。
Compared with other structural materials, magnesium alloys have many excellent properties, but the poor mechanical properties limit their wide use. With wider and wider applications of magnesium alloys in the automobile and IT industries, the producers all over the world have pay much attention to the researches and applications of the magnesium alloys. It is proved that the refining grain can improve mechanical properties of materials, so it is very important to find an effective grain refiner and technique for magnesium alloys.
In this paper, the grain refiner and technique for the AZ91 magnesium alloys are studied by observing their metallurgical structures at as-cast and heat treatment condition. The research methods conducted are adding Ce or Ca to the AZ91 alloy respectively and applying the electromagnetic field on the AZ91 or AZ91 + 0.8%Ce. The results show that Ce and Ca can remarkably refine the grain size of AZ91 magnesium alloy. The optimum content of Ce% and Ca% is 0.8% 0.1% respectively, and the grain size can be reduced 58% 43.7%. As expected, electromagnetic stirring can refine structure of α-Mg phase and lead to action of spheroidization. Compared with the AZ91 alloy, however, spheroidization in the AZ91 + 0.8% Ce alloy is poor, and a new needle-shaped phase precipitate. As the stirring voltage increases, the a-Mg phase size of the AZ91 and AZ91+0.8% is reduced 52.6% and 41%. The optimum voltage range is 75-125 voltage. At last, the mechanical properties of the AZ91 alloy are tested, which proves that mechanical properties of the AZ91 alloy are improved due to grain refinement.
本论文主要针对广泛应用的AZ91合金的晶粒细化工艺及机理进行研究。在AZ91合金中分别加入稀土元素Ce、碱土元素Ca、加交流磁场分别对AZ91和AZ91+0.8%Ce电磁搅拌。对以上几种方法获得的合金组织进行金相观察,并与未处理的AZ91合金的组织进行对比。结果表明,分别加入Ce和Ca后,AZ91合金的晶粒细化效果明显,在本试验条件下,最佳含量分别为:0.8%Ce,0.1%Ca,对应的晶粒尺寸分别减小了58%、43.7%;电磁搅拌能显著细化AZ91与AZ91+0.8%Ce合金晶粒,并产生了球化作用,加入稀土后球化效果减弱,并且有针状新相出现。最佳的励磁电压范围为75~125伏特,对应的晶粒减少了52.6%、41%。此外,对细化机理作了初步探讨。对材料的力学性能进行了测试并与未加细化剂的合金进行比较,表明晶粒细化可明显提高合金的力学性能。
Compared with other structural materials, magnesium alloys have many excellent properties, but the poor mechanical properties limit their wide use. With wider and wider applications of magnesium alloys in the automobile and IT industries, the producers all over the world have pay much attention to the researches and applications of the magnesium alloys. It is proved that the refining grain can improve mechanical properties of materials, so it is very important to find an effective grain refiner and technique for magnesium alloys.
In this paper, the grain refiner and technique for the AZ91 magnesium alloys are studied by observing their metallurgical structures at as-cast and heat treatment condition. The research methods conducted are adding Ce or Ca to the AZ91 alloy respectively and applying the electromagnetic field on the AZ91 or AZ91 + 0.8%Ce. The results show that Ce and Ca can remarkably refine the grain size of AZ91 magnesium alloy. The optimum content of Ce% and Ca% is 0.8% 0.1% respectively, and the grain size can be reduced 58% 43.7%. As expected, electromagnetic stirring can refine structure of α-Mg phase and lead to action of spheroidization. Compared with the AZ91 alloy, however, spheroidization in the AZ91 + 0.8% Ce alloy is poor, and a new needle-shaped phase precipitate. As the stirring voltage increases, the a-Mg phase size of the AZ91 and AZ91+0.8% is reduced 52.6% and 41%. The optimum voltage range is 75-125 voltage. At last, the mechanical properties of the AZ91 alloy are tested, which proves that mechanical properties of the AZ91 alloy are improved due to grain refinement.
引文
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34 Yuanyuan Li, Datong Zhang, etc. Microstructure and tensile behavior of hot extrudedAZ91 alloy at room temperature [J]. Journal of Beijing University of Science and Technology, 2002,9(5):352~355
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37 S Kamado, T Ashie, H Yamada, K Sanbon, Y Kojima. Improvement of tenable properties of wrought magnesium alloys by grain refining [J]. Materials Science Forum, 2000, (350~351): 65~72
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40 吴伟,张禄廷,陈立佳等.等通道角度挤压对两种镁合金拉伸性能的影响[J],沈阳工业大学学报.2003,25(1)
41 闵学刚,孙扬善,杜温文等.Ca,Si和RE对Az91合金的组织和性能的影响[J].东南大学学报,2002,32(3)
42 刘生发,郭洪河等.镁及其合金铸造组织细化[J].材料导报,2003,(10)
43 闵学刚等.Ca提高Mg_(17)Al_(12)相熔点的现象及EET理论分析[J].科学通报,2002,47(2):109~113
44 M Egev, E Aghion, A Rosen, et al. Creep studies of coarse-grained AZ91D magnesium casting [J]. Materials Science & Engineering, 1998, A252: 6~16
45 Y Anuca, N Kono, T Moj Tigi, et al. Grain Refinement of Cast Mg-Al Alloys[J]. Journal of Japan Institute of Light Metals, 1998,48(8): 395~399
46 Arne K.Dahle, Young C.Lee, etc. Development of the as-cast mierostru-cture in magnesium-aluminum alloys [J]. Journal of Light Metals, 2001, 1: 61~72
47 J F Nie, B C Mudle. Precipitation in Mg alloy WE54 during isothermal ageing at 250℃ [J]. Seripta Material,1999,(10):1089~1094
48 R Erro , A Saccone, G Borzone. 铝镁轻合金中的稀土[J]. 中国稀土学报,1997, 15(3): 262~273
49 张诗昌,段汉桥,蔡启舟等.镁合金的熔炼工艺现状及发展趋势[J].特种铸造及有色合金,2000,(6):51~54
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2 严炎样(上海乾通汽车附件有限公司).镁合金压铸件在汽车工业中的应用和发展[J].汽车材料,2001,(4)
3 郭洪河,刘生发,黄尚宇等.镁合金在汽车中的应用现状与发展趋势[J].汽车工艺与材料,2003(10)
4 刘红梅,卫爱丽,刘春莲等.MgCO_3对AZ91D镁合金的细化研究[J].铸造工程·造型材料,2002
5 张世军,黎文献,余琨.添加含碳熔剂细化镁合金晶粒的方法[J].特种铸造及有色合金,2002,(4):18~19
6 张世军,黎文献,余琨.镁合金的晶粒细化工艺[J].铸造,2001,50(7)
7 王立世,段汉桥,魏伯康等.混合稀土对AZ91镁合金组织和性能的影响[J].特种铸造及有色合金,2002,(3)
8 S Lee, S H Lee, D H Kim. Effect of Y, Sr, Nd additions on the microstructure and microstructure mechanism of squeeze-cast AZ91-X magnesium alloys [J]. Metal Trans,1998,29A (4):1221~1235
9 张世军,黎文献,余琨等.铈对镁合金AE31晶粒大小及铸态力学性能的影响[J].铸造,2002,51(12):767~771
10 周海涛,马春江.稀土元素铈对AZ61镁合金铸态显微组织及结构的影响[J].高技术通讯,2003
11 刘红梅,付珍等.稀土元素镧在镁合金细化及强化中所起的作用[J].铸造工程.造型材料,2002
12 闵学刚等.Ca对AZ91显微组织及力学性能的影响[J].材料科学与工艺,2002,10(1)
13 丁绍松,孙扬善,白晶等.Ca对AE41合金的显微组织和力学性能的影响[J].江苏冶金,2003,31(1)
14 袁晓光,刘正,许沂.电磁铸造对AZ91D合金组织及力学性能的影响[J].中国有色金属学报,2002,12(4)
14 罗治平,张少卿.稀土在镁合金熔液液中的作用热力学分析[J].中国稀土学报,1995,13(2),119~122
15 郑苏来.《铸造合金及其熔炼》[M].西安:西北工业大学出版社,1994
16 李文彬等.磁力应用工程[M].北京:兵器工业出版社,1991
17 王寿彭等.铸件成型理论及工艺基础[M].西安:西北工业大学出版社,1994,12
18 罗爱华,巴罗格,鲍威尔.镁铝钙合金应用于传动部件时的延伸蠕变与微观结构[J].上海压铸镁国际研讨会论文集[A].中国上海:2001:138~147
19 张淑芬,杜富英,李平等.富钇混合稀土-镁中间合金的制备及其物性的研究[J].中国稀土学报,1995,13(专辑)
20 张诗昌,段汉桥.主要合金元素对镁合金组织和性能的影响[J].铸造,2001,50(6)
21 胡丽萍,甄立玲,王智慧.喷射沉积稀土镁合金材料工艺研究[J].金属成形工艺,2000,18(2)
22 刘海峰,侯骏,刘耀辉等.压铸镁合金高温蠕变研究现状及进展[J].铸造,2002,51(6):330~334
23 R W卡恩主编,丁道云译.非铁金属的结构与性能[M].北京:科技出版社,1999
24 徐日瑶,刘宏专.熔融镁液铸锭时金属晶粒细化对产品质量的影响[J].轻金属,2000(5):46~48
25 S Amado, N Ikeya, R S Rudi, T Araki , Y Kojima. Application of Semi-Solid-forming to Mg-Zn-Al-Ca alloys [J]. Materials Science Forum, 2000,(350~351): 205~214
26 滕英一郎.铸造合金结晶粒微细化[J].铸造工程学,1996(12):1084~1093
27 Q.Ivind. The Effect of Sr on The Hydrogen Solubility and Hydraulic Formation in Pure Mg and AZ91 Alloy [J]. Scandinavian Journal of Metallurgy, 1998 (3): 133~140
28 刘子利,丁文江,袁广银等.镁锅基耐热铸造镁合金的进展[J].机械工程材料,2001,25(11):1~4
29 丁文江,袁广银.新型镁合金的研究开发与应用[J].有色金属加工,2002,31(3):27~38
30 刘正,张奎,曾小勤等.镁基轻质合金理论基础儿应用[M].北京:机械工业出版社,2002
31 T Motegi, E Sato, K Obata. Cast Structures and Gain Refinement of Superheat-treated Mg-Al Alloys[J].轻金属, 1994, 44(8): 427~432
32 郝士明.镁的合金化与合金相图[J].材料与冶金学报.2002,1(3)
33 Kaikun Wang, Yonglin Kang, and Kai Zhang. Effects of rare earth elements on the microstructure and properties of magnesium alloy AZ91D [J]. Journal of Beijing University of Science and Technology, 2002, 9(5):363~367
34 Yuanyuan Li, Datong Zhang, etc. Microstructure and tensile behavior of hot extrudedAZ91 alloy at room temperature [J]. Journal of Beijing University of Science and Technology, 2002,9(5):352~355
35 L. J. Plmear. Magnesium Alloys and Application[J]. Materials Science and Technology, 1994, (10):1~16
36 张景新,张奎等.电磁搅拌制备半固态材料非枝晶组织的形成机制[J].中国有色金属学报,2000,10(4)
37 S Kamado, T Ashie, H Yamada, K Sanbon, Y Kojima. Improvement of tenable properties of wrought magnesium alloys by grain refining [J]. Materials Science Forum, 2000, (350~351): 65~72
38 虞莲莲.实用有色金属材料手册[M].北京:机械工业部出版社,1995
39 朱昊,孙扬善,薛烽等.Ca的低合金化对Mg-Zn-RE系镁合金显微组织及力学性能的影响[J].江苏冶金,2002,30(6)
40 吴伟,张禄廷,陈立佳等.等通道角度挤压对两种镁合金拉伸性能的影响[J],沈阳工业大学学报.2003,25(1)
41 闵学刚,孙扬善,杜温文等.Ca,Si和RE对Az91合金的组织和性能的影响[J].东南大学学报,2002,32(3)
42 刘生发,郭洪河等.镁及其合金铸造组织细化[J].材料导报,2003,(10)
43 闵学刚等.Ca提高Mg_(17)Al_(12)相熔点的现象及EET理论分析[J].科学通报,2002,47(2):109~113
44 M Egev, E Aghion, A Rosen, et al. Creep studies of coarse-grained AZ91D magnesium casting [J]. Materials Science & Engineering, 1998, A252: 6~16
45 Y Anuca, N Kono, T Moj Tigi, et al. Grain Refinement of Cast Mg-Al Alloys[J]. Journal of Japan Institute of Light Metals, 1998,48(8): 395~399
46 Arne K.Dahle, Young C.Lee, etc. Development of the as-cast mierostru-cture in magnesium-aluminum alloys [J]. Journal of Light Metals, 2001, 1: 61~72
47 J F Nie, B C Mudle. Precipitation in Mg alloy WE54 during isothermal ageing at 250℃ [J]. Seripta Material,1999,(10):1089~1094
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