TiAl合金与GH3039摩擦焊接界面组织被引量：2

Intermediate Phases of TiAl/GH3039 Friction Welding Joint

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摘要使用GH3039合金作为γ-TiAl与碳钢摩擦焊接的过渡第三体,采用扫描电子显微镜(SEM)和透射电子显微镜(TEM)分析了TiAl/GH3039摩擦焊接接头的界面结构。结果表明,γ-TiAl和GH3039摩擦焊接接头的最大抗拉伸强度能达到400 MPa以上。GH3039一侧热力影响区的塑性变形大于TiAl一侧,并且在两侧均发生动态再结晶。接近GH3039母材相层中的Ni含量几乎不变,接近TiAl母材相层中的Ti含量也几乎不变。在GH3039侧面附近的焊接区中,富Ni和富Cr晶粒的分布是互补的。Ti和Al容易溶于富Ni的晶粒中,而Mn容易溶于富Cr的晶粒中。在结合区中形成的大量富Cr晶粒是体心立方结构的α-Cr。γ-TiAl和GH3039摩擦焊接的典型界面结构为:γ-TiAl+α_(2)-Ti_(3)Al/α_(2)+τ_(3)/τ_(3)-Al_(1+x−y)Ti_(1+y)Ni_(1−x)/τ_(3)+α-Cr/(Ni,Cr)_(ss)/GH3039。 GH3039 superalloy was used as the third body metal to weldγ-TiAl with carbon steel,and the interface structure of the TiAl/GH3039 friction welding joint was analyzed by scanning electron microscope(SEM)and transmission electron microscope(TEM).The results show that the maximum tensile strength of the weld joint is more than 400 MPa after friction welding ofγ-TiAl and GH3039 alloys.The plastic deformation of thermo-mechanically affected zone(TMAZ)on GH3039 side is larger than that on TiAl side,and dynamic recrystallization occurs on both sides.The Ni and Ti contents in the phase layer close to GH3039 and TiAl alloys hardly change,respectively.In the welding zone near GH3039 side,the distribution of Ni-rich and Cr-rich grains are complementary.Ti and Al are easily soluble in the Ni-rich crystal grains,and Mn is easily soluble in the Cr-rich crystal grains.A large number of Cr-rich grains formed in the bonding zone have body-centered cubic structure ofα-Cr.The interface microstructure of the friction welding zone betweenγ-TiAl and GH3039 alloys isγ-TiAl+α_(2)-Ti_(3)Al/α_(2)+τ_(3)/τ_(3)-Al_(1+x−y)Ti_(1+y)Ni_(1−x)/τ_(3)+α-Cr/(Ni,Cr)_(ss)/GH3039.

作者杜随更李娜王松林 Du Suigeng;Li Na;Wang Songlin(Key Laboratory of High Performance Manufacturing for Aero Engine,Ministry of Industry and Information Technology,Northwestern Polytechnical University,Xi'an 710072,China;Department of Mechanical and Electrical Engineering,Pingliang Vocational and Technical College,Pingliang 744000,China)

机构地区西北工业大学航空发动机高性能制造工业和信息化部重点实验室平凉职业技术学院机电工程系

出处《稀有金属材料与工程》 SCIE EI CAS CSCD 北大核心 2021年第9期3102-3109,共8页 Rare Metal Materials and Engineering

基金 National Natural Science Foundation of China (51675434)

关键词摩擦焊接 TIAL金属间化合物 GH3039高温合金连接机理界面结构 friction welding TiAl intermetallic GH3039 superalloy joint mechanism interface microstructure

分类号 TG453.9 [金属学及工艺—焊接]

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参考文献3

1苏彦庆,刘桐,李新中,陈瑞润,郭景杰,傅恒志.籽晶法定向凝固TiAl基合金片层取向控制[J].金属学报,2018,54(5):647-656. 被引量：4
2Honggang Dong,Zhonglin Yang,Zengrui Wang,Dewei Deng,Chuang Dong.CuTiNiZrV Amorphous Alloy Foils for Vacuum Brazing of TiAl Alloy to 40Cr Steel[J].Journal of Materials Science & Technology,2015,31(2):217-222. 被引量：7
3R.KUMAR,M.BALASUBRAMANIAN.Experimental investigation of Tie6Ale4V titanium alloy and 304L stainless steel friction welded with copper interlayer[J].Defence Technology（防务技术）,2015,11(1):65-75. 被引量：9

二级参考文献30

1罗文忠,沈军,李庆林,满伟伟,郑循强,刘林,傅恒志.抽拉速率对Ti-43Al-3Si合金籽晶法定向凝固组织的影响[J].金属学报,2006,42(12):1238-1242. 被引量：15
2罗文忠,沈军,李庆林,满伟伟,傅恒志.Ti-47Al合金籽晶法定向凝固过程中的组织演化[J].金属学报,2007,43(9):897-902. 被引量：14
3Ambroziak A, Korzeniowski M, Kustron P. Friction welding of dissimilarmetal joints with intermediate layers. J Achiev Mater Manuf Eng2007;21(2):37-40. 被引量：1
4Montgomery Jonathan S, Wells Martin GH, Roopchand Brij,Ogilvy James W. Low-cost titanium armors for combat vehicles. MineralsMetals Mater Soc 1997;49(5):45-7. 被引量：1
5Cola MJ, Dickerson RM, Gentzlinger RC, Teter DF. Dissimilar welds forthe apt superconducting cavity's cryogenic plumbing system. In: Proceedingsof the 1999 Workshop on RF Superconductivity, Santa Fe, NewMexico, USA; 1999. 被引量：1
6Lee Won-Bae, Jung Seung-Boo. Effect of microstructure on mechanicalproperties of friction-welded joints between Ti and AISI 321 stainlesssteel. Jpn Inst Metals Mater Trans 2004;45(9):2805-11. 被引量：1
7Astarita, Curioni M, Squillace A, Zhou X, Bellucci F, Thompson GE,et al. Corrosion behavior of stainless steeletitanium alloy linear frictionwelded joints: galvanic coupling. Mater Corros 2014. http://dx.doi.org/10.1002/maco.201307476. 被引量：1
8Madhusudhan Reddy G, Mohandas T, Sambasivarao A,Satyanarayana VV. Influence of welding processes on microstructure andmechanical properties of dissimilar austenitic- ferrite stainless steelwelds. Mater Manuf Process 2005;20(2):147-73. 被引量：1
9Balasubramanian M, Jayabalan V, Balasubramanian V. Optimizing thepulsed current GTAW parameters to attain maximum impact toughness.Mater Manuf Process 2008;23:69-73. 被引量：1
10Cosmin Groza A, Ion Mite lea A, Dimian Marcela Elena. Mechanicaland structural characteristics of friction weldedTIe6ALe4V t X5CRNI18-10 dissimilar joints. Metal 2011;5:18-20.Brno, Czech Republic, EU. 被引量：1

共引文献17

1周丽,王唱舟,张星星,肖伯律,马宗义.SiCp/Al复合材料热轧过程的有限元模拟[J].金属学报,2015,51(7):889-896. 被引量：9
2袁江,魏红伟,欧学卫,韦肖飞.RE(RE=Y,La,Ce,Lu)对TiAl性能影响的计算研究[J].热加工工艺,2017,46(2):42-46.
3吕攀,王克鸿,朱和国.钛合金与不锈钢异种金属焊接的研究现状[J].热加工工艺,2017,46(13):26-32. 被引量：12
4Gopinath THIRUNAVUKARASU,Subrata CHATTERJEE,Sukumar KUNDU.Scope for improved properties of dissimilar joints of ferrous and non-ferrous metals[J].Transactions of Nonferrous Metals Society of China,2017,27(7):1517-1529. 被引量：1
5李聪,王金凤,胡爽,张旺.Cu-P钎料真空钎焊紫铜的钎焊后扩散及组织分析[J].焊接学报,2019,40(3):91-96. 被引量：2
6陈光,陈奉锐,祁志祥,冯辰铭,曹月德,许昊,郑功.聚片孪生TiAl单晶及其应用展望[J].振动．测试与诊断,2019,39(5):915-926. 被引量：4
7Huihong Liu,Yo Aoki,Yasuhiro Aoki,Kohsaku Ushioda,Hidetoshi Fujii.Principle for obtaining high joint quality in dissimilar friction welding of Ti-6Al-4V alloy and SUS316L stainless steel[J].Journal of Materials Science & Technology,2020,42(11):211-224. 被引量：3
8张鹏贤,乔永丰.一种钛/钢电阻钎焊接头专用复合过渡金属片[J].热加工工艺,2020,49(13):136-141.
9李娜,杜随更,王松林,王晋伟.TiAl合金与GH3039高温合金的摩擦焊接[J].焊接学报,2020,41(6):6-11. 被引量：1
10王松林,杜随更,李娜.TiAl与GH3039异种材料摩擦焊接工艺及接头组织[J].机械科学与技术,2020,39(12):1957-1962. 被引量：1

同被引文献15

1陈国庆,张秉刚,何景山,冯吉才.TiAl基合金电子束焊接头组织及转变规律[J].焊接学报,2007,28(5):81-84. 被引量：6
2谭永恒,徐洪辉,杜勇.Isothermal section at 927℃ of Cr-Ni-Ti system[J].中国有色金属学会会刊：英文版,2007,17(4):711-714. 被引量：1
3何鹏,冯吉才,钱乙余,张九海.扩散连接接头金属间化合物新相的形成机理[J].焊接学报,2001,22(1):53-55. 被引量：35
4董红刚,于连震,高洪明,邓德伟,周文龙,董闯.Microstructure and mechanical properties of friction welds between TiA l alloy and 40Cr steel rods[J].Transactions of Nonferrous Metals Society of China,2014,24(10):3126-3133. 被引量：5
5杨锐.钛铝金属间化合物的进展与挑战[J].金属学报,2015,51(2):129-147. 被引量：150
6宋晓国,司晓庆,曹健,王志权,赵洪运,冯吉才.高铌TiAl合金钎焊接头组织和性能研究（英文）[J].稀有金属材料与工程,2018,47(1):52-58. 被引量：7
7包潘飞,宋晓国,王新波,胡胜鹏,彭赫力,李中权.连接温度对高铌TiAl合金扩散接头组织和强度的影响[J].稀有金属材料与工程,2018,47(7):2132-2136. 被引量：2
8Changfeng YAO,Jiannan LIN,Daoxia WU,Junxue REN.Surface integrity and fatigue behavior when turning γ-TiAl alloy with optimized PVD-coated carbide inserts[J].Chinese Journal of Aeronautics,2018,31(4):826-836. 被引量：11
9陈国庆,张戈,尹乾兴,张秉刚,冯吉才.TiAl合金焊接裂纹控制研究进展[J].材料导报,2020,34(5):115-119. 被引量：5
10Peng Li,Shuai Wang,Yueqing Xia,Xiaohu Hao,Honggang Dong.Diffusion bonding of AlCoCrFeNi2.1 eutectic high entropy alloy to TiAl alloy[J].Journal of Materials Science & Technology,2020,42(10):59-69. 被引量：10

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1杜随更,胡弘毅,丁珂.γ⁃TiAl与Ti_(2)AlNb线性摩擦焊接头微观组织[J].航空学报,2024,45(13):258-265.
2杜随更,王松林,胡弘毅.TiAl基合金与GH3039合金摩擦-扩散双重焊焊合区过渡相的形成、结构与原位开裂[J].金属学报,2024,60(12):1637-1646.

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2王亚,周文,陈浩,葛茂忠.激光冲击处理对GH3039高温合金磨损性能的影响[J].机械工程与自动化,2021(5):31-34. 被引量：1
3杨爽,王静,杨帅,李金虹,刘金.电阻焊接技术在复合材料领域应用进展[J].冶金与材料,2021,41(5):127-128. 被引量：1
4路尧文,赵亚东,崔红保,罗亚龙,何洋洋.铝/镁异种材料搅拌摩擦焊接头的组织演化与断裂行为研究[J].热加工工艺,2021,50(17):27-31. 被引量：4
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6龚思恒,董显娟,徐勇,鲁世强.真空烧结温度对Ti-44Al-2Cr-4Nb-0.2W-0.2B合金显微组织及力学性能的影响[J].稀有金属材料与工程,2021,50(8):2950-2956.
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TiAl合金与GH3039摩擦焊接界面组织被引量：2