AN IN SITU SURFACE COMPOSITE AND GRADIENT MATERIAL OF Al-Si ALLOY PRODUCED BY ELECTROMAGNETIC FORCE 被引量：3

AN IN SITU SURFACE COMPOSITE AND GRADIENT MATERIAL OF Al-Si ALLOY PRODUCED BY ELECTROMAGNETIC FORCE

下载PDF

导出

摘要 Because of the different conductivities between the primary phase (low electric conduc tivity) and the metal melt, electromagnetic force scarcely acts on the primary phase. Thus, an electromagnetic repulsive force applied by the metal melt exerts on the pri mary phase when the movement of the melt in the direction of electromagnetic force is limited. As a result, the repulsive force exerts on the primary phase to push them to move in the direction opposite to that of the electromagnetic force when the metal melt with primary phase solidifies under an electromagnetic force field. Based on this, a new method for production of in situ surface composite and gradient material by electromagnetic force is proposed. An in situ primary Si reinforced surface composite of Al-15wt%Si alloy and gradient material of Al-l9wt%Si alloy were produced by this method. The microhardness of the primary Si is HV1320. The reinforced phase size is in the range from 40μm to 100μm. The wear resistance of Al-Si alloy gradient material can be more greatly increased than that of their matrix material. Because of the different conductivities between the primary phase (low electric conduc tivity) and the metal melt, electromagnetic force scarcely acts on the primary phase. Thus, an electromagnetic repulsive force applied by the metal melt exerts on the pri mary phase when the movement of the melt in the direction of electromagnetic force is limited. As a result, the repulsive force exerts on the primary phase to push them to move in the direction opposite to that of the electromagnetic force when the metal melt with primary phase solidifies under an electromagnetic force field. Based on this, a new method for production of in situ surface composite and gradient material by electromagnetic force is proposed. An in situ primary Si reinforced surface composite of Al-15wt%Si alloy and gradient material of Al-l9wt%Si alloy were produced by this method. The microhardness of the primary Si is HV1320. The reinforced phase size is in the range from 40μm to 100μm. The wear resistance of Al-Si alloy gradient material can be more greatly increased than that of their matrix material.

作者 Z.M. Xu, T.X. Li, Z.L. Zhu and Y.H. Zhou School of Materials Science and Engineering, Shanghai Jiao Tong University, Shanghai 200030, China

出处《Acta Metallurgica Sinica(English Letters)》 SCIE EI CAS CSCD 2001年第5期335-340,共6页 金属学报（英文版）

基金 supported by the National Natural Science Foundation of China(Grant No.50001008) the China Postdoctoral Science Foundation.

关键词 Al-Si alloy electromagnetic force in situ surface composite gradient material Al-Si alloy, electromagnetic force, in situ surface composite, gradient material

分类号 TG146.21 [金属学及工艺—金属材料]

引文网络
相关文献

参考文献12

1[1]E.Z.Wang,Y.Q.Zheng and J.D.Xing,Acta Mater.Comp.Sin.15(2) (1998) 12 (in Chinese).
2[2]X.L.Zhang,N.S.Hu and J.W.He,Foundry (12) (1998) 10 (in Chinese).
3[3]Z.Q.Cao,L.P.Zhang and J.Z.Jin,J.Mater.Sci.27 (1992) 4663.
4[4]Z.Q.Cao,L.P.Zhang and J.Z.Jin,J.Mater.Sci.Lett.11 (1992) 1579.
5[5]X.Q.Wu,Y.S.Yang,J.S.Zhang,G.L.Jia and Z.Q.Hu,Journal of Materials Engineering and Performance 18(5) (1999) 525.
6[6]Y.F.Zhu,W.Q.Zhang,Y.S.Yang,Q.M.Liu and Z.Q.Hu,Acta Metall.Sin.(English Lett.) 10(2)(1997) 105.
7[7]W.Q.Zhang,Y.S.Yang,Y.F.Zhu,Q.M.Liu and Z.Q.Hu,Metall.Mater.Trans.A 29(1) (1998)404.
8[8]Q.D.Wang,W.J.Ding and J.Z.Jin,Acta Mater,Comp.Sin.15 (1998) 7 (in Chinese).
9[9]D.Leenov and A.Kolin,J.Chem.Phy.22(4) (1954) 683.
10[10]P.Marty and A.Alemany,in: Metallurgical Applications of Magnetohydrodynarnics,Proceedings of a Symposium of the IUTAM (The Metals Society,1984) p.245.

同被引文献21

1TANG Guo-an~1, Josef Strobl~2, GONG Jian-ya~3, ZHAO Mu-dan~1, CHEN Zhen-jiang~1 (1. Department of Geography, Northwest University, Xi’an 710069, China,2. Department of Geography and Geoinformation, Salzburg University, Hellbrunnerstr. 34, A-5020 Salzb.Evaluation on the accuracy of digital elevation models[J].Journal of Geographical Sciences,2001,11(2):209-216. 被引量：13
2袁继兵,梁万里,苏树江,石建新,龚孟濂.一种蓝色有机发光材料的合成及性质[J].应用化学,2005,22(2):207-209. 被引量：6
3曹志强,金俊泽.电磁复合铸造新工艺[J].大连理工大学学报,1996,36(6):756-758. 被引量：2
4陈楠,王钦敏,汤国安.基于单个栅格的DEM坡度与分辨率关系研究[J].中国矿业大学学报,2007,36(4):499-504. 被引量：8
5王林同,王世华,赵新华.含Eu^(2+)固体的荧光光谱研究及其应用[J].化学通报,1997(5):30-37. 被引量：8
6杨丽格,周泊,陆天虹,蔡称心.稀土磷酸盐纳米发光材料的研究进展[J].应用化学,2009,26(1):1-6. 被引量：18
7闾国年,钱亚东,陈钟明.黄土丘陵沟壑区沟谷网络自动制图技术研究[J].测绘学报,1998,27(2):131-137. 被引量：42
8闾国年,钱亚东,陈钟明.基于栅格数字高程模型提取特征地貌技术研究[J].地理学报,1998,53(6):562-570. 被引量：101
9金俊泽,张永安,曹志强.电磁搅拌自生表面复合材料的组织与性能[J].材料研究学报,1998,12(4):446-448. 被引量：8
10刘勇,王义祥,潘保田.夷平面的三维显示与定量分析方法初探[J].地理研究,1999,18(4):391-399. 被引量：22

引证文献3

1刘向阳,梁高飞,宋长江,许振明.应用外力场制备自生梯度复合材料的研究进展[J].材料导报,2004,18(8):43-45. 被引量：1
2陈巧平,高峰,谢鸿芳,肖艳春,陈震.高温固相法合成长余辉发光材料Sr_(0.96)Al_2O_4:Eu_(0.02)^(2+),Dy_(0.02)^(3+)[J].化学通报,2011,74(4):372-375. 被引量：2
3TANG GuoAn,LI FaYuan,LIU XueJun,LONG Yi & YANG Xin Key Laboratory of Virtual Geographic Environment,Nanjing Normal University,Ministry of Education,Nanjing 210046,China.Research on the slope spectrum of the Loess Plateau[J].Science China(Technological Sciences),2008,51(S1):175-185. 被引量：25

二级引证文献28

1高毅平,汤国安,周毅,李发源.陕北黄土地貌正负地形坡度组合研究[J].南京师大学报（自然科学版）,2009,32(2):135-140. 被引量：7
2杨昕,汤国安,刘学军,李发源,祝士杰.数字地形分析的理论、方法与应用[J].地理学报,2009,64(9):1058-1070. 被引量：95
3ZHOU Yi,TANG Guo＇an,YANG Xin,XIAO Chenchao,ZHANG Yuan,LUO Mingliang.Positive and negative terrains on northern Shaanxi Loess Plateau[J].Journal of Geographical Sciences,2010,20(1):64-76. 被引量：35
4刘红艳,杨勤科,王春梅,李俊.坡度随水平分辨率变化及其空间格局研究[J].武汉大学学报（信息科学版）,2012,37(1):105-109. 被引量：15
5张磊,汤国安,李发源,熊礼阳.黄土地貌沟沿线研究综述[J].地理与地理信息科学,2012,28(6):44-48. 被引量：21
6宋春美,职爱民,贾国超,胥传来,张改平.稀土发光材料及其在食品安全检测中的应用[J].食品科学,2013,34(11):300-304. 被引量：3
7刘兵,黄建国,刘坐镇.稀土掺杂无机长余辉发光材料研究概况[J].材料导报（纳米与新材料专辑）,2013,27(1):178-182. 被引量：6
8陈楠.基于信息损失量的坡度精度分析[J].地球信息科学学报,2014,16(6):852-858. 被引量：12
9徐明,张健,刘国彬,张婷.黄土丘陵区不同植被恢复模式对沟谷地土壤碳氮磷元素的影响[J].草地学报,2015,23(1):62-68. 被引量：8
10褚永彬,朱利东,唐斌,黎新裕.疏勒河上游流域地面坡谱特征[J].干旱区地理,2015,38(2):345-350. 被引量：7

1谢鲲,曹梅青,夏鹏成,岳丽杰.Improving wear resistance of magnesium by droplet spraying of Al-Si alloy[J].Journal of Central South University,2013,20(7):1781-1785. 被引量：1
2SHI, GQ,DING, PD,ZHOU, SZ,TANG, JX.Study of Iron-based Surface Composite Materials[J].Journal of Materials Science & Technology,1995,11(3):232-234.
3苏彦庆,徐严谨,赵雷,郭景杰,傅恒志.Effect of electromagnetic force on melt induced by traveling magnetic field[J].Transactions of Nonferrous Metals Society of China,2010,20(4):662-667. 被引量：5
4梁工英,苏俊义,黄俊达,胡仲豪.Amorphous structure in a laser clad Ni-Cr-Al coating on Al-Si alloy[J].中国有色金属学会会刊：英文版,2000,10(2):220-223.
5MI Guo-fa,WANG Kuang-fei,WEN Tao,ZHANG Ming,WANG Hong-wei,ZENG Song-yan.On grain refinement and titanium segregation in Al-Si alloy[J].China Foundry,2007,4(4):273-275.
6He Lijia Wang Jianzhong Qi Jingang Du Huiling Zhao Zuofu.Influences of electric pulse on solidification structure of LM-29 Al-Si alloy[J].China Foundry,2010,7(2):153-156. 被引量：5
7Chen, ZH,Kang, ZT.Solid liquid Mixed Casting of Al-Si Alloy[J].Journal of Central South University,2000,12(3):133-135. 被引量：1
8Du Yongsheng Zhang Hongxia Zhang Xuefeng Liu Yongzhuang Chen Shiming.Effect of Magnetic Suspension Force in Electromagnetic Stirring on Microstructure of Al-Si Alloy[J].稀有金属材料与工程,2009,38(A03):88-90.
9Guangrning XU,Jiawei ZHENG,Yong LIU,Jianzhong CUI.Effect of electric current on the cast micro-structure of Al-Si alloy[J].China Foundry,2005,2(3):171-175. 被引量：1
10润滑耐磨梯度材料LGM（Lubrication Gradient Material）及低温离子渗硫技术[J].热处理,2004,19(4):25-25.

Acta Metallurgica Sinica(English Letters)

2001年第5期

浏览历史

内容加载中请稍等...

AN IN SITU SURFACE COMPOSITE AND GRADIENT MATERIAL OF Al-Si ALLOY PRODUCED BY ELECTROMAGNETIC FORCE 被引量：3

参考文献12

同被引文献21

引证文献3

二级引证文献28

相关作者

相关机构

相关主题

浏览历史