Energy-storage welding connection characteristics of rapidly solidified Cu-Co alloy foils 被引量：4

Energy-storage welding connection characteristics of rapidly solidified Cu-Co alloy foils

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摘要 The connection characteristics of rapidly solidified Cu-40%Co alloy foils were studied using a self-developed micro-type energy-storage welding machine. The results show that the microstructure of the alloy foils is characterized by uni form and fine equiaxed grains,whose maximum grain size is 1.8 μm. Under the o ptimum energy,the regular flat nugget is formed,low voltage and high capacitan ce are favorable for obtaining the perfect connection joints,whereas high volta ge and low capacitance are likely to result in the surface burn of the alloy foi ls. With the increase of welding energy,the spot welding joint will be transfor med from regular flat nugget to nugget-free one,and the microstructure tends t o coarsen. The welding parameters recommended are: welding voltage 80100 V,(electric) capacitance 1 8002 500 μF,and welding force 48 N. The connection characteristics of rapidly solidified Cu-40%Co alloy foils were studied using a self-developed micro-type energy-storage welding machine. The results show that the microstructure of the alloy foils is characterized by uni form and fine equiaxed grains,whose maximum grain size is 1.8 μm. Under the o ptimum energy,the regular flat nugget is formed,low voltage and high capacitan ce are favorable for obtaining the perfect connection joints,whereas high volta ge and low capacitance are likely to result in the surface burn of the alloy foi ls. With the increase of welding energy,the spot welding joint will be transfor med from regular flat nugget to nugget-free one,and the microstructure tends t o coarsen. The welding parameters recommended are: welding voltage 80100 V,(electric) capacitance 1 8002 500 μF,and welding force 48 N.

作者徐锦锋翟秋亚蒋永

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 2004年第4期785-789,共5页 Transactions of Nonferrous Metals Society of China

关键词储能焊铜合金快速凝固 CU-CO合金焊接接头点焊 rapidly solidified alloy foils energy-storage welding nugget joint microstructure

分类号 TG457.13 [金属学及工艺—焊接] TG453.9 [金属学及工艺—焊接]

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参考文献3

1赵九洲.Model for calculation of microstructural development in rapidly directionally solidified immiscible alloys[J].中国有色金属学会会刊：英文版,2002,12(3):366-369. 被引量：2
2孙占波,宋晓平,胡柱东,王献辉,杨森,曹崇德,魏炳波.深过冷条件下Cu-Co合金的二次液相分解与合金的凝固[J].中国有色金属学报,2001,11(2):172-175. 被引量：4
3孙占波,宋晓平,胡柱东,杨森,曹崇德,魏炳波.深过冷条件下Cu-Co合金的液相分解[J].中国有色金属学报,2001,11(1):68-73. 被引量：13

二级参考文献18

1Robinson M B，J Mater Sci，1999年，34卷，3747页
2Song X，Mater Lett，1997年，31卷，261页
3Andrews J B. Solidification of immiscible alloys [A]. Ratke L. Immiscible Liquid Metals and Organics [C]. Germany: DGM-Informationsgesellschaft, 1993, 199-222.
4Grugel R N, Angus H. Alloy solidification in systems containing a liquid miscibility gap [J]. Metall Trans A, 1981, 12A: 669-681.
5Grugel R N, Lograsso T A, Hellawell A. Directional solidification of alloys in systems containing a liquid miscibility gap [A]. Rindone G E. Materials Processing in the Reduced Gravity Environment of Space [C]. Elsevier Science Publishing Company Inc, 1982. 553-561.
6LIU Y, GUO J J, SU Y Q, et al. Microstructure of rapidly solidified Al-In immiscible alloy [J]. Trans Nonferrous Met Soc China, 2001, 11(1): 84-89.
7Zhao J Z, Ratke L. Microstructure evolution of immiscible alloys during cooling through the miscibility gap [J]. Modelling Simul Sci Eng, 1998, 6: 123-139.
8Zhao J Z, Ratke L. Kinetics of phase separation in immiscible alloy [J]. Z Metallkd, 1998, 89: 241-246.
9Granasy L, Ratke L. Homogeneous nucleation within the liquid miscibility gap of Zn-Pb alloys [J]. Scripta Metall Mater, 1993, 28: 1329-1334.
10Patankar S V. Numerical Heat Transfer and Fluid Flow [M]. New York: McGraw-Hill, 1980.

共引文献16

1郑红星,陈倬麟,郭学锋.过偏晶合金Ni-40%Pb深过冷凝固组织[J].中国有色金属学报,2001,11(z2):148-151. 被引量：9
2郑红星,马伟增,郭学锋,李建国.偏晶合金凝固研究进展[J].稀有金属材料与工程,2004,33(8):893-896. 被引量：3
3孙万里,张忠明,徐春杰,郭学锋.深过冷快速凝固技术的研究进展[J].兵器材料科学与工程,2005,28(1):66-71. 被引量：9
4郑红星,谢辉,周永欣,郭学锋.过冷Ni-31.44%Pb偏晶合金凝固行为[J].铸造技术,2001,26(4):57-59.
5张忠明,孙万里,徐春杰,郭学锋.深过冷Cu-20wt%Pb亚偏晶合金的凝固行为[J].西安理工大学学报,2005,21(2):118-121. 被引量：2
6刘源,郭景杰,贾均,李言祥.Simulation of nucleation and coalescence of second phase droplets during earth-based solidification process of immiscible alloys[J].中国有色金属学会会刊：英文版,2005,15(3):479-484. 被引量：2
7孙万里,张忠明,徐春杰,郭学锋.过冷条件下Cu-34.15%Pb偏晶合金凝固规律[J].材料热处理学报,2005,26(4):44-47.
8孙万里,张忠明,徐春杰,郭学锋.过冷Cu-Pb偏晶合金的凝固热力学分析[J].材料热处理学报,2005,26(6):53-56. 被引量：4
9李雷鸣,徐锦锋.大体积非晶合金的制备技术[J].铸造技术,2007,28(10):1332-1337. 被引量：5
10李圣,刘峰,杨根仓,杨伟.溶质含量对快速凝固Co-Cu不混溶合金晶粒细化组织的影响[J].中国有色金属学报,2013,23(4):1012-1018. 被引量：3

同被引文献22

1李小平,汪凯,张春恒,雒敏,马沁,王世民.钽及钽合金在废酸回收设备中的应用[J].材料开发与应用,2012,27(6):19-21. 被引量：5
2翟秋亚,徐锦锋.Cu-Sn合金急冷箔储能焊接头的形貌特征与形成机制[J].金属学报,2005,41(7):755-758. 被引量：8
3邢丽,李磊,柯黎明.低碳钢与紫铜搅拌摩擦焊接头显微组织分析[J].焊接学报,2007,28(2):17-20. 被引量：18
4Paul B K, Wilson D D, McDowell E, et al. Study of weld strength variability for capacitor discharge welding process automation [ J ]. Science and Technology of Welding and Joining, 2001,6(2): 109-115.
5翟秋亚,徐锦锋,蔡再生.细直径YG5FA硬质合金/45Cr钢储能焊工艺分析[J].焊接学报,2007,28(8):13-16. 被引量：9
6何康生曹雄天.异种金属焊接[M].北京：机械工业出版社,1986.28-42.
7翟秋亚,杨扬,徐锦锋,郭学锋.快速凝固Cu-Sn亚包晶合金的电阻率及力学性能[J].物理学报,2007,56(10):6118-6123. 被引量：10
8赵麦群,铃木实平,川上博士,松山文彦,康晶.Capacitor discharge percussion welding of pure aluminum wire to pure copper sheet[J].China Welding,2008,17(3):66-71. 被引量：2
9翟秋亚,杨金山,徐峰,徐锦锋.急冷Cu-Sn合金的快速凝固焊接接头组织特征[J].焊接学报,2009,30(4):49-52. 被引量：3
10冯吉才,王廷,张秉刚,陈国庆.异种材料真空电子束焊接研究现状分析[J].焊接学报,2009,30(10):108-112. 被引量：74

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1翟秋亚,杨金山,徐锦锋,郭学锋.急冷Cu-Sn合金箔快速凝固连接工艺[J].焊接学报,2009,30(7):53-56.
2康晶,赵麦群,吕娟,赵雪琴,铃木实平.异种金属铁丝-铜板的电容储能冲击焊接[J].焊接学报,2010,31(4):93-96. 被引量：2
3翟秋亚,刘帅宾,杨全虎,叶建林,徐锦锋.Ta1/0Cr18Ni9薄板储能焊熔核高熵化机理[J].焊接学报,2020,41(8):79-84. 被引量：3
4翟秋亚,刘帅宾,杨全虎,叶建林,徐锦锋.Ta1/Ta8Ni30Cr20Cu42/0Cr18Ni9储能焊接头组织与性能[J].焊接学报,2020,41(10):60-64. 被引量：3

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1杨文杰,吴立鹏,李慕勤,王军,曹永胜,李秀玲.异种金属丝电容储能对接焊设备的研究[J].佳木斯大学学报（自然科学版）,2010,28(6):897-899.
2翟秋亚,刘帅宾,杨全虎,叶建林,徐锦锋.Ta1/Ta8Ni30Cr20Cu42/0Cr18Ni9储能焊接头组织与性能[J].焊接学报,2020,41(10):60-64. 被引量：3
3翟秋亚,刘帅宾,田甜,徐锦锋,叶建林.基于焊缝高熵化的TA2与0Cr18Ni9板材TIG焊分析[J].焊接学报,2021,42(4):79-83. 被引量：2
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5逯胜磊,黄增好,庞世炫,李茂盛,曹彪.铝/钢线对接逆变电源冲击焊电弧形态及焊点成形[J].热加工工艺,2022,51(11):121-126.
6刘喆,王伟雄,贺琼瑶,郭瑞,赵运强,刘德佳.TC4钛合金/N4纯镍激光高熵化填粉焊接组织性能研究[J].精密成形工程,2022,14(8):118-126.
7周永强,冯杉杉,朱政强.钽与不锈钢异种材料焊接的研究进展[J].电焊机,2023,53(1):63-70. 被引量：1
8蒋淑英,蔡畅,赵明,黄万群.基于高熵合金中间层的Q235钢/6061铝合金电阻点焊接头的组织与性能[J].焊接学报,2023,44(7):71-78. 被引量：2

1JinfengXU,QiuyaZHAI,SenYUAN.Energy-storage Welding Connection Characteristics of Rapid Solidification AZ91D Mg Alloy Ribbons[J].Journal of Materials Science & Technology,2004,20(4):431-434. 被引量：14
2朱福良,余细波,黄秀扬,张霞.脉冲电沉积Cu-Co合金镀层及其性能[J].兰州理工大学学报,2011,37(1):9-13. 被引量：1
3Pyachin S.A.,Verkhoturov A.D.,Zavodinsky V.G.,Pugachevsky M.A..The influence of low voltage discharges on structure and phase transformations of metallic foils[J].广东有色金属学报,2005,15(2):495-495.
4M. J Li,G.S. Song,G.C. Yang and YH Zhou (State Key Laboratory of Solidification Processing, Northwestern Polytechnical University, Xi’an 710072,China).GRAIN REFINEMENT INDUCED BY REMELTING INUNDERCOOLED Fe-30at.%Co ALLOYS[J].Acta Metallurgica Sinica(English Letters),1999,12(6):0-0.
5王培,刘峰,李争显,杜继红.深过冷Cu_(98)Co_2合金的凝固组织演化[J].稀有金属材料与工程,2010,39(A01):482-486.
6陈国庆,张秉刚,叶鸿森,冯吉才.Effects of electron beam welding parameters on the microstructure of titanium to aluminum alloy joints[J].China Welding,2012,21(4):32-37. 被引量：2
7S.Gholami Shiri,A.Sarani,S.R.Elmi Hosseini,G.Roudini.Diffusion in FSW Joints by Inserting the Metallic Foils[J].Journal of Materials Science & Technology,2013,29(11):1091-1095.
8赵永庆,周廉,邓炬.High Tem perature Defor mation Mechanism of Ti-40 Burn Resistant Titaniu m Alloy As-annealing[J].Rare Metals,1999,18(3):203-207. 被引量：3
9宋尽霞,曾潮流,付广艳,牛焱.双相Cu-Co合金在600～800℃空气中的氧化[J].腐蚀科学与防护技术,2000,12(2):77-81. 被引量：4
10李培友,孟凡莹,王永善,董敏敏,史俊婷,宋佩维.Glass forming ability and thermodynamic properties in novel La-Al-Cu-Co bulk metallic glasses[J].Journal of Rare Earths,2015,33(9):972-976. 被引量：10

中国有色金属学会会刊：英文版

2004年第4期

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