Microstructure and microhardness of Ti_3Al matrix composites produced by XD^(TM) synthesis 被引量：2

Microstructure and microhardness of Ti_3Al matrix composites produced by XD^(TM) synthesis

下载PDF

导出

摘要 XD TM method was used to prepare titanium aluminide(Ti 3Al) matrix composites. The phase constitution and the as cast microstructure of Ti 25Al alloy with different carbon contents have been investigated using XRD and SEM. Microhardness and elastic modulus of the matrix and reinforcements were tested by mechanical property microprobe. In Ti 25Al 0.5C alloy, blocky Ti 3AlC and lath Ti 3AlC were in situ formed as reinforcement, and homogeneously distributed in the matrix. The microhardness and elastic modulus of blocky Ti 3AlC are 14.2 GPa and 281.3 GPa respectively, higher than those of the lath Ti 3AlC about 3 GPa and 60 GPa respectively. When C content is more than 0.5%, dendritic TiC and Ti 3AlC were formed as reinforcement in a core structure, where the TiC core is coated with Ti 3AlC phase. The microhardness and elastic modulus of the reinforcement decrease with increasing distance from the center of the reinforcement and matrix. The maximum microhardness and modulus of TiC and Ti 3AlC are 22.8 GPa, 302.7 GPa and 20.2 GPa, 313.5 GPa, respectively. XD TM method was used to prepare titanium aluminide(Ti 3Al) matrix composites. The phase constitution and the as cast microstructure of Ti 25Al alloy with different carbon contents have been investigated using XRD and SEM. Microhardness and elastic modulus of the matrix and reinforcements were tested by mechanical property microprobe. In Ti 25Al 0.5C alloy, blocky Ti 3AlC and lath Ti 3AlC were in situ formed as reinforcement, and homogeneously distributed in the matrix. The microhardness and elastic modulus of blocky Ti 3AlC are 14.2 GPa and 281.3 GPa respectively, higher than those of the lath Ti 3AlC about 3 GPa and 60 GPa respectively. When C content is more than 0.5%, dendritic TiC and Ti 3AlC were formed as reinforcement in a core structure, where the TiC core is coated with Ti 3AlC phase. The microhardness and elastic modulus of the reinforcement decrease with increasing distance from the center of the reinforcement and matrix. The maximum microhardness and modulus of TiC and Ti 3AlC are 22.8 GPa, 302.7 GPa and 20.2 GPa, 313.5 GPa, respectively.

作者魏尊杰房文斌王宏伟曾松岩

机构地区 School of Materials Science and Engineering

出处《中国有色金属学会会刊：英文版》 CSCD 2002年第6期1138-1141,共4页 Transactions of Nonferrous Metals Society of China

基金 Project(0 13 0 413 1)supportedbytheAstronauticScienceandTechnologyInnovationFoundationofChina

关键词 TI3AL Ti3AlC TIC 微硬度弹性模数 Ti 3Al Ti 3AlC TiC microhardness elastic modulus

分类号 TB331 [一般工业技术—材料科学与工程]

引文网络
相关文献

参考文献1

1Young- Won (Y-W.) Kim(UES, Inc., Materials Research Division, 4401 Dayton-Xenia Rd., Dayton, OH 45432, USA)(Paper presented at the International Workshop on OrderedIntermetallics 1992, Hangzhou, China).Effects of Microstructure on the Tensile, Fracture Toughness and Fatigue Behaviour of Gamma Titanium Aluminides[J].Journal of Materials Science & Technology,1994,10(2):79-91. 被引量：19

共引文献18

1CHEN Jian-xun(陈建勋) HUANG Bai-yun(黄伯云).Effect of HIPing time on the properties of TiAl alloys[J].Journal of Central South University of Technology,2002,9(3):145-149. 被引量：2
2宫子琪,周峰,柴丽华,陈子勇,相志磊,聂祚仁.TiAl合金断裂韧性的影响因素及其韧化机制[J].材料科学与工程学报,2014,32(3):465-468. 被引量：8
3李达人,徐顺有,蔡一湘,车晓舟.烧结温度对SPS制备γ-TiAl合金组织性能的影响[J].稀有金属材料与工程,2013,42(S2):277-279. 被引量：2
4艾桃桃,王芬,冯小明,郭从盛.原位合成Al_(2)O_(3)颗粒增强双相TiAl基复合材料的组织与性能[J].中国有色金属学报,2007,17(11):1849-1854. 被引量：14
5Y.G.Zhang,Y.H.Lu,G.K.Hu,C.Q.Chen.FRACTURE MECHANISM AND MICROMECHANICAL ANALYSIS OF POLYSYNTHETICALLY TWINNED CRYSTALS OF γTiAl ALLOYS[J].中国有色金属学会会刊:英文版,1999,9(S1):130-137. 被引量：3
6雷晓武.含混合阳离子的Sn基极性金属间化合物的研究进展[J].济宁学院学报,2011,32(6):22-25.
7秦云翔,谢泉,高廷红,闫万珺,郭笑天,范梦慧.冷速对液态Ti_3Al合金快速凝固过程中微观结构变化的影响[J].现代机械,2013(1):80-82.
8周浩.精密铸造TiAl基合金薄壁铸件用型壳退让性的研究[J].铸造,2013,62(8):781-783. 被引量：6
9万文娟,韩伟,张继.TiAl合金高周疲劳行为的基本特征[J].材料导报,2014,28(23):8-11. 被引量：3
10王慧,程芳.Ti-40Al-3.5Nb-0.8Mo-0.3Y高温合金组织和力学性能研究[J].稀有金属与硬质合金,2018,46(3):19-22. 被引量：2

同被引文献25

1储双杰,何贵玉.颗粒增强Ti－Al化合物基复合材料[J].材料科学与工程,1994,12(1):23-29. 被引量：6
2陶春虎,王守凯,张少卿,颜鸣皋.采用XD工艺合成TiAl合金及TiC／TiAl复合材料的研究[J].航空学报,1994,15(12):1445-1449. 被引量：10
3王为民,梅炳初,傅正义,袁润章.热压自蔓延高温合成制备TiB_2／NiAl金属间化合物基复合材料[J].复合材料学报,1996,13(1):30-34. 被引量：10
4Muzir Z A.Self-propagating High-temperature Synthesis[J].Journal of Materials Science,1992,(27):6249～6273.
5Khatri S H,Koczak M J.Formation of TiC in-situ Processed Composites Via Solid-gas.Solid-liquid and Liquid-gas Reaction in Molten Al-Ti [J].Materials Science & Engineering, 1993,A162(1/2):153～162.
6Tang W,Bergman B.On the Formation of Al2O3-Al Composites by Directed Oxidation of Molten Metals [J].Materials Science & Engineering, 1994, A117(4):135～142.
7Marthy V R S,Rao B S.Microstructural Development in the Directed Melt-oxidized (DIMOX) Al-Mg-Si Alloys [J].Journal of Materials Science,1995,30(12):3091～3097.
8Antolin S.Formation of Al2O3/Metal Composites by the Directed Oxidation of Molten Al-Mg-Si Alloys: Part Ⅱ Growth Kinetics [J].Journal of American Ceramic Society, 1992,(2):259～267.
9Johnsson M,Bacherud L,Sigworth G K.Study of the Mechanism of Hrain Refinement of Aluminum After Additions of Ti and B Containing Master Alloys [J].Metallurgical Transactions,1993,l24A(2):481～491.
10陈子勇,陈玉勇,舒群,安阁英.盐类反应制备TiB_2/Al-4.5Cu复合材料的研究[J].特种铸造及有色合金,1997,17(6):1-4. 被引量：25

引证文献2

1朱晓光,王为民.原位反应合成金属基复合材料[J].国外建材科技,2005,26(4):1-4. 被引量：6
2Zhi-qiang BU,Xiu-ping MA,Jia-yun WU,Zhen LÜ,Hu CHEN,Jin-fu LI.Microstructure and mechanical properties of continuous drive friction welded Ti_(2)AlNb alloy under different rotational rates[J].Transactions of Nonferrous Metals Society of China,2024,34(10):3221-3232. 被引量：1

二级引证文献7

1任文坛,张勇,张隐西.原位反应合成技术在橡胶加工和改性方面的应用[J].特种橡胶制品,2007,28(4):1-6. 被引量：6
2胡付立,陈敬超,于杰,冯晶.原位合成制备Cu/FeS复合材料研究[J].电工材料,2007(4):3-6. 被引量：1
3胡勇,闫洪,陈国香.原位镁基复合材料的研究进展[J].铸造,2008,57(8):757-762. 被引量：8
4胡付立,陈敬超,张志伟,刘满门,耿永红,张昆华,管伟明.热挤压变形改善Cu/FeS复合材料的性能[J].稀有金属材料与工程,2009,38(A01):217-220. 被引量：3
5王亚娟,史楷歧,邵双喜,单志华.原位协同聚合反应在制革中的应用[J].皮革科学与工程,2009,19(4):28-32. 被引量：1
6杨铭湘,陈永泰,谢明,宁德魁,陈松,杨有才.AgCu系电接触材料研究进展[J].贵金属,2024,45(S01):1-6. 被引量：1
7薛甜甜,王世清,温国栋,亓钧雷,高旺,骆晓炜,路永新.无磁钻杆摩擦焊焊缝塑性环演变规律[J].焊接学报,2025,46(7):91-99.

1田文怀,杨海春,根本■.TiAl金属间化合物中(Al,Ag)_3Ti,Ti_3AlC的析出形态[J].金属学报,1997,33(7):677-682. 被引量：2
2李书江,王艳丽,林均品,林志,陈国良.微量C,B对高铌TiAl合金显微组织与力学性能的影响[J].稀有金属材料与工程,2004,33(2):144-148. 被引量：26
3郭俊明,陈克新,王宝森,张虹,李兴权,周和平.TiAl_3对燃烧合成Ti_3AlC的影响[J].稀有金属材料与工程,2006,35(11):1708-1711. 被引量：1
4廉继范.磨轮弹性模数模拟的进一步评述[J].磨床与磨削,1997(1):55-56.
5王立慧,蔡冬萍,贾秋生.冷冲压钢球组合模具过盈组装挤压力的计算[J].哈尔滨轴承,2006,27(1):41-41.
6冯庆玲,王昶明.Al－Ti－C中间合金中TiC粒子的失效问题[J].清华大学学报（自然科学版）,1994,34(5):106-111. 被引量：10
7卫静,刘安斌.铜合金薄零件的加工工艺及变形控制[J].郑州工业大学学报,1999,20(1):109-109. 被引量：2
8周欢,张铁邦,吴泽恩,胡锐,寇宏超,李金山.间隙原子C作用下TiAl合金中析出相的形成及演变规律[J].金属学报,2014,50(7):832-838. 被引量：1
9Weiguo Jiang Jiasheng Dong Li Wang Langhong Lou.Effect of Casting Modulus on Microstructure and Segregation in K441 Superalloy Casting[J].Journal of Materials Science & Technology,2011,27(9):831-840. 被引量：4
10Yong Zhang,Junpin Lin,Guoliang Chen,Gengchen Sun,Guanxing Li (State Key Laboratory for Advanced Metals and Materials, UST Beijing, Beijing 100083, China)(Institute of Mechanics Research, Sinica Academy of Science, Beijing, China)(202 Plane Baotou, C.Mechanical Properties of Interface between U-0.75Ti Alloy and TiC[J].International Journal of Minerals,Metallurgy and Materials,1998,12(1):41-43.

中国有色金属学会会刊：英文版

2002年第6期

浏览历史

内容加载中请稍等...