期刊文献+

Effect of superheat and solidified layer on achieving good metallic bond between A390/A356 alloys fabricated by cast-decant-cast process 被引量:2

采用铸造-倾析-铸造技术制备A390/A356铝合金功能梯度复合材料时过热和凝固层厚度对其界面接合的影响(英文)
在线阅读 下载PDF
导出
摘要 The cast-decant-cast is a new method for the preparation of the functionally graded components that has been developed in recent years. The functionally graded cylindrical shape component with a radial gradient, e.g. the first alloy (A390) with high wear resistance on the surface of the piece and toughness and the second alloy (A356) of low machining costs in the core of the piece can be produced via this melt process. The effect of the second alloy superheat at temperatures of 750, 820 and 860 ℃ as well as the effect of the first alloy solidified layer at 25, 35 and 45 s decanting time on achieving the perfect interface between the two alloys was investigated. The characterization of the interface was carded out by optical microscopy and scanning electron microscopy, and its width was measured by the microhardness test. The results showed that the best interface was obtained at 860 ℃ and 35 s decanting time with a width of 500 ~tm. Also, the wear resistance test was performed to measure and compare the surface wear resistance to the core. 铸造-倾析-铸造技术是近年来发展起来的一种制备功能梯度材料的新方法。采用这种方法制备在径向具有梯度功能的圆柱形试样,其外表层为具有高耐磨性的A390铝合金,芯部为具有较高韧性和加工性能的A356铝合金。研究芯部熔体在不同过热温度(750,820和860°C)和表层在不同倾析时间(25,35和45 s)下的A390/A356合金界面接合情况。采用光学显微镜和扫描电镜对界面进行表征,对界面区的显微硬度进行测量。结果表明,在过热温度为860°C,倾析时间为35 s的条件下,可以获得一宽度约为500μm的接合良好的界面层。比较了试样表面层和芯部的耐磨性能。
出处 《Transactions of Nonferrous Metals Society of China》 SCIE EI CAS CSCD 2014年第3期665-672,共8页 中国有色金属学报(英文版)
关键词 A390 alloy A356 alloy functionally graded material cast-decant-cast process A390铝合金 A356铝合金 功能梯度材料 铸造-倾析-铸造技术
作者简介 Correspondingauthor:S.GHOLAMISHIRI;Tel:+98-9173327857;Fax:+98-2166165717;Email:sgholami85@yahoo.com
  • 相关文献

参考文献13

  • 1MORTENSEN A, SURESH S. Functionally graded metals and metal-ceramic composites: Part I, Processing [J]. International Material Review, 1995, 40(6): 239-265.
  • 2RAJAN T P D, PILLAI R M, PAl B C. Characterization of centrifugal cast functionally graded aluminum-silicon carbide metal matrix composites [J]. Material Characterization, 2010, 61: 923-928.
  • 3ZHANG Zhong-tao, LI Ting-ju, YUE Hong-yun, ZHANG Jian, LI Jie. Study on the preparation of AI-Si functionally graded materials using power ultrasonic field [J]. Materials and Design, 2009, 30: 851 856.
  • 4SOHRABI BABA HEIDARY D, AKHLAGHI F. Theoretical and experimental study on settling of SiC pieceicles in composite slurries of aluminum A356/SIC [J]. Acta Materialia, 201 I, 59: 4556-4568.
  • 5SONG Chang-jiang, XU Zhen-ming, LI Jian-guo. Structure of in situ A|/Si functionally graded materials by electromagnetic separation method [J]. Materials and Design, 2007, 28: 1012-1015.
  • 6ZHOU Zhang-jian, SONG Shu-xiang, DU Juan, ZHONG Zhi-hong, GE Chang-chun. Performance of W/Cu FGM based plasma facing components under high heat load test [J]. Journal of Nuclear Materials, 2007, 363-365: 1309-1314.
  • 7SCANLAN M, BROWNE D J, BATES A. New casting route to novel functionally gradient light alloys [J]. Materials Science and Engineering A, 2005, 413-414:66-71.
  • 8CHIRITA G, SOARES D, SILVA F S. Advantages of the centrifugal casting technique for the production of structural components with A1-Si alloys [J]. Materials and Design, 2008, 29: 20-27.
  • 9SHABESTARI S G, GHODRAT S. Assessment of modification and formation of intermetallic compounds in aluminum alloy using thermal analysis [J]. Materials Science and Engineering A, 2007, 467: 150-158.
  • 10BARLOW J O, STEFANESCU D M. Computer-aided cooling curve analysis revisited [J]. Transactions of the American Foundrymen's Society, 1997, 104: 349-354.

同被引文献33

  • 1A.M. Kovalchenko,O.I. Fushchich,S. Danyluk.The tribological properties and mechanism of wear of Cu-based sintered powder materials containing molybdenum disulfide and molybdenum diselenite under unlubricated sliding against copper[J]. Wear . 2012
  • 2M Orme.Method for Droplet Stream Manufacturing[P].US Patent5171360,1992.
  • 3M Orme.On the Genesis of Droplet Stream Micro Speed Dispersions[J].Physics of Fluids A-Fluid Dynamics,1991,3(12):2 936-2 947.
  • 4M Orme,A Novel Technique of Rapid Solidification Net-Form Materials Synthesis[J].Journal of Materials Engineering and Performance,1993,2(3):399-407.
  • 5Rice C S,Mendez P F,Brown S B.Metal Solid Freeform Fabrication Using Semi-solid Slurries[J].JOM,2000,52(12):31-33.
  • 6HAQUE M M,SHARIF A.Study on Wear Properties of Aluminiumsilicon Piston Alloy[J].Journal of Materials Processing Technology,2001,118(1/3):69-73.
  • 7ATKINSON H V.Modelling the Semisolid Processing of Metallic Alloys[J].Progress in Materials Science,2005,50(3):341-412.
  • 8YANG Xiao-rong,MAO Wei-min,PEI Sheng.Preparation of Semisolid A356 Alloy Feedstock Cast Through Vertical Pipe[J].Materials Science and Technology,2007,23(9):1 049-1 053.
  • 9LUO Shou-jing,TIAN Wen-tong,XIE Shui-sheng,et al.Semi-solid Processing Technology and Application[J].The Chinese Journal of Nonferrous Metals,2000,10(6):765-769.
  • 10LUKASSON M,APELIAN D,DASGUPTA R.Alloy Characterization for the New UBE Rheocasting Process[J].AFS Transactions,2002,110:271-284.

引证文献2

二级引证文献4

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部