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Ti40合金热稳定性的研究 被引量:4

Thermal Stability of Ti40 Alloy
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摘要 研究了Ti40阻燃β钛合金的热稳定性。结果表明 ,仅固溶处理的Ti40合金具有良好的强度和塑性配合 ,其热稳定性相对较好 ;固溶并时效处理合金的热稳定性较差 ,且时效温度越高 ,合金的热稳定性也越差。热暴露温度越高 ,合金的热稳定性能越差。 The thermal stability of Ti40 burn resistant titanium alloy was studied. The results show that Ti40 alloy after only solution treatment has a good strength/ductility combination, and its thermal stability is better than that of the alloy after aging treatment following solution treatment. The higher the aging temperature, the worse the thermal stability of the alloy. In addition, it was also found that the higher the thermal exposure temperature is, the worse the thermal stability of the alloy is.
出处 《稀有金属》 EI CAS CSCD 北大核心 2004年第1期44-46,共3页 Chinese Journal of Rare Metals
基金 国防"十五"重点预研项目 ( 4 13 12 0 2 0 3 0 2 )资助
关键词 金属材料 阻燃钛合金 TI40 热处理 微观组织 热稳定性 burn resistant titanium alloy Ti40 heat treatment microstructure thermal stability
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  • 1赵永庆,赵香苗,朱康英,罗国珍,周廉.阻燃钛合金[J].稀有金属材料与工程,1996,25(5):1-6. 被引量:43
  • 2赵永庆.-[J].稀有金属材料与工程,2000,29(6):403-403.
  • 3[1]Hansen J O, Sound H , Novotnak D, et al. Heat treatment to reduce embrittlement of titanium alloys[P]. US Patent: 5397404, 1995-03-14.
  • 4[2]Giary K. High-strength titanium resistant ignition[J]. Advanced Materials and Processes, 1993, 9: 7-10.
  • 5[3]Seagle S R. The state of the USA titanium industry in 1995[J]. Materials Science and Engineering A, 1996, 213: 1-7.
  • 6[4]Boyer R R. An overview on the use of titanium in the aerospace industry[J]. Materials Science and Engineering A, 1996, 213: 103-114.
  • 7[5]Li Y G, Zhang X D, Blenkinsop P A, et al. The development and evaluation of β titanium alloys for aerospace applications[A]. Blenkinsop P A, Evens W J. Proceedings of the 8th World Conference on Titanium[C]. London: The Institute of Materials, 1996. 2317-2324.
  • 8[6]Li Y G, Blenkinsop P A, Loretto M H, et al. Effect of aluminium on ordering of highly stabilized β-Ti-V-Cr alloys[J]. Materials Science and Technology, 1998, 14(8): 732-737.
  • 9[7]Li Y G, Blenkinsop P A, Loretto M H, et al. Effect of aluminium on deformation structure of highly stabilized β-Ti-V-Cr alloys[J]. Materials Science and Technology, 1999, 15(2): 151-155.
  • 10[8]Li Y G, Blenkinsop P A, Loretto M H, et al. Structure and stability of precipitates in 500℃ exposed Ti-25V-15Cr-xAl alloys[J]. Acta Mater, 1999, 46(16): 5777-5794.

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  • 1赵永庆,周廉,邓炬.阻燃钛合金的阻燃模型[J].材料科学与工程学报,2000,20(z2):888-891. 被引量:2
  • 2黄旭,曹春晓,王宝,高扬,马济民,周尧和.阻燃钛合金Alloy C[J].航空制造工程,1997(6):24-26. 被引量:10
  • 3Zhu Yanchun, Zeng Weidong, Zhao Yongqing, et al. Effect of processing parameters on hot deformation behavior and mierostructural evolution during hot compression of Ti40 titanium alloy [J]. Mater Sci Eng,2012,552(8):384.
  • 4Zhao Y Q, et al. The role of interface in the burning of titanium alloys [J]. Mater Sci Eng A, 1999,267(1) :167.
  • 5Zhao Y Q, Qu H L, Zhu K Y, et al. Oxidation behavior of a burn resistant highly stabilized 13 titanium alloy [J]. Mater Sci Eng A,2001,316(1) :214.
  • 6Lei Liming, Huang Xu, Sun Fusheng, et al. The effect of thermal exposure on the microstructure of Ti-2. 5V-1.5Cr- 2Al-0. 2C Alloy [J]. Rare Metal Mater Eng, 2003,27 (1) : 208.
  • 7Peng W W, Zeng W D, Zhang Y W,et al. Oxidation beha- vior and effect of oxidation on microstructure and tensile properties of Ti-SAl-5Mo-SV-1Cr-IFe alloy [J]. J Alloys Compd, 2013 , 577 : 635.
  • 8Akahori T, Niinomi M, Fukunaga K, et al. Effects of mi erostructure on the short fatigue crack initiation and propa gation characteristics of biomedical α/β titanium alloys [J]. Metall Mater Trans A,2000,31 : 1949.
  • 9赵永庆,辛社伟,吴欢,杨海瑛,李倩.热处理对Ti40阻燃钛合金热稳定性能的影响[J].稀有金属材料与工程,2008,37(4):660-664. 被引量:10
  • 10辛社伟,赵永庆,曾卫东.Ti40阻燃钛合金热处理的研究[J].金属热处理,2008,33(5):68-71. 被引量:7

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