SiC纤维增强钛基复合材料研究现状与展望

摘要
参考文献
相关文章 (15)

全文: PDF (1210 KB)
输出: BibTeX | EndNote (RIS)

摘要连续SiC纤维增强钛基复合材料（SiCf/Ti）是一种重要的高推重比发动机（推重比>12）用结构材料，它的应用为发动机设计和制造带来了革命性的变革。SiCf/Ti复合材料代表了高推重比发动机用结构材料的发展方向，欧美国家设立了多项研究计划来发展SiCf/Ti复合材料，技术水平已经达到或接近于实用状态。介绍了国内外对连续纤维增强钛基复合材料的研究现状及国内研究存在的一些问题，并对国内SiCf/Ti复合材料的未来发展提出了一些建议。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	曹秀中
	韩秀全
	赵冰
	侯红亮

关键词 ： SiC纤维, SiCf/Ti复合材料, 界面, 力学性能

引用本文:

曹秀中，韩秀全，赵冰，侯红亮. SiC纤维增强钛基复合材料研究现状与展望[J]. 航空制造技术, 2014, 57(22): 109-112.

链接本文:

http://www.amte.net.cn/CN/ 或 http://www.amte.net.cn/CN/Y2014/V57/I22/109

[1] Djanarthany S, Viala J C, Bouix J. Development of SiC/TiAl composites: processing and interfacial Phenomena. Materials Science and Engineering, 2001, 300 (1-2 ): 211-214.
[2] 梁春华.连续纤维增强的金属基复合材料部件杂航空涡扇发动机上的应用.航空制造技术, 2009(15): 32-36.
[3] 张国定,赵昌正. 金属基复合材料.上海:上海交通大学出版社,1995:32-53.
[4] 刘翠霞, 杨延清, 徐婷, 等. 化学气相沉积法连续SiC纤维的研究现状和发展趋势. 材料导报, 2006, 20(8): 35-37, 40.
[5] Clyne T W. Comprehensive composite material, Volume 3 Metal matrix composite. London: Cambridge University Press, 2000: 492-538.
[6] Merrick H F, Aksoy S Z, Costen M, et al. TMC behavior modeling and life prediction under multiaxial stresses, NASA/TM-1998-207928.
[7] Doorbar H J, Sudds I D A. Method of making fiber reinforced metal component: America, US5305520. 1994-04-26.
[8] Woods H L, Merrimack R C L, Nagy P, et al. Method of manufacturing composites:America, US5427304, 1995-07-27.
[9] Linsey G D, Chen G O X, Blackburn M J. Ductile titanium alloy matrix fiber reinforced composites:America, US5508115.1996-04-16.
[10] 周义刚,杨延清.碳化硅连续纤维增强钛基复合材料的研究进展.金属学报, 2002, 38(S): 461-466.
[11] Dudek H J, Borath R, Leucht R, et al. Transmission electron microscopy of the fibre-matrix interface in SiC-SCS-6 fibre-reinforced IMI834 alloys. Journal of Materials Science,1997, 32(3): 5355-5365.
[12] Peng H X. Manufacturing titanium metal matrix composites by consolidation matrix coated fibers. J Mater Sci Technol , 2005, 21(5):647-656.
[13] Ma Z J , Yang Y Q , Du J , et al. The effect of magnetron sputter parameter on fiber coating character. Materials Letters, 2004, 58(15): 2118-2125.
[14] Olevky E, Dudek H J, Kaysser W A. Hiping conditions for processing of metal matrix composites using continuum theory for sintering-II. Application to Fiber Reinforced Titanium Alloys. Acta Materialia, 1996, 44(2): 715-723.
[15] Djanarthany S, Viala J C, Bouix J. Development of SiC/TiAl composites: processing and interfacial phenomena. Materials Science and Engineering, 2001, 300(6 ): 211-217.
[16] 杨延清, 朱艳, 马志军. SiC长纤维增强Ti基复合材料的制备.稀有金属材料与工程, 2002, 21(3): 424-426.
[17] Gorsse S, Petitcorps Y L. A new approach in the understanding of the SiC/Ti reaction zone composition and morphology. Composites Part A, 1998, 29(9-10):1221-1226.
[18] Yang Y Q, Zhu Y, Ma Z J. Formation of interfacial reaction products in SCS-6 SiC/Ti2AlNb composites. Scripta Materialia, 2004: 51(11): 385-396.
[19] Baik K H , Grant P S. Chemical interaction between Sigma 1140 SiC fiber and Ti-6Al-4V. Scripta materialia, 2001, 44(7): 607-611.
[20] 曾立英,邓炬,白保良,等.连续纤维增强钛基复合材料研究概况.稀有金属材料与工程, 2000, 29(3): 211-215.
[21] Chou T W, Kell A, Okura A, Fiber-reinforced metal matrix composites. Composites, 1985,16(3): 187-192.
[22] Mall S, Titanium matrix composites-mechanical behavior. Lancaster: Technomic Publishing Co,1997: 41-53.
[23] Bednarcyk B A, Arnold S M. A new local debonding model with application to the transverse tensile and creep behavior of continuously reinforced titanium composites, NASA/TM-2000-210029.
[24] 莱茵斯 C, 皮特尔斯 M.钛与钛合金. 北京:化学工业出版社, 2005:268-302.
[25] Barney C, Beevers C J, Bowen.Fatigue crack propagation in SiC continuous fiber-reinforced Ti-6Al-4V alloy metal-matrix composites. Composites,1993, 24(3): 229-236.