Orbital-abrasion-assisted Electroforming of Non-rotating Parts 被引量：4

Orbital-abrasion-assisted Electroforming of Non-rotating Parts

下载PDF

导出

摘要 A novel technique of electroforming with orbital moving cathode was carried out for the fabrication of non-rotating thin-walled parts.This technique features a large number of insulating and insoluble hard particles as a real-time polishing to the cathode.When cathode moves,hard particles polish its surface and provide the nickel non-rotating parts with near-mirror finishing.Morphology,microstructure,surface roughness and micro hardness of deposits fabricated by novel method were studied in contrast with the sample produced by traditional electroforming methods.Theoretical analysis and experimental results showed that the novel technique could effectively remove the hydrogen bubbles and nodules,disturb the crystal nucleation,and refine the grains of layer.The mechanical properties were significantly improved over traditional method.The micro-hardness of the layer was in a uniform distribution ranging from 345 HV to 360 HV.It was confirmed that this technique had practical significance to non-rotating thin-walled parts. A novel technique of electroforming with orbital moving cathode was carried out for the fabrication of non-rotating thin-walled parts.This technique features a large number of insulating and insoluble hard particles as a real-time polishing to the cathode.When cathode moves,hard particles polish its surface and provide the nickel non-rotating parts with near-mirror finishing.Morphology,microstructure,surface roughness and micro hardness of deposits fabricated by novel method were studied in contrast with the sample produced by traditional electroforming methods.Theoretical analysis and experimental results showed that the novel technique could effectively remove the hydrogen bubbles and nodules,disturb the crystal nucleation,and refine the grains of layer.The mechanical properties were significantly improved over traditional method.The micro-hardness of the layer was in a uniform distribution ranging from 345 HV to 360 HV.It was confirmed that this technique had practical significance to non-rotating thin-walled parts.

作者李学磊

机构地区 Nanjing University of Aeronautics & Astronautics School of Mechanical & Electronic Engineering

出处《Journal of Wuhan University of Technology(Materials Science)》 SCIE EI CAS 2011年第5期827-831,共5页 武汉理工大学学报（材料科学英文版）

基金 Funded partly by the National Natural Science Foundation of China(No.50975143) the Aviation Science Funds,China (No.2009ZE52048)

关键词 ELECTROFORMING orbital cathode ABRASION non-rotating parts electroforming orbital cathode abrasion non-rotating parts

分类号 TH117.1 [机械工程—机械设计及理论]

引文网络
相关文献

参考文献2

1朱增伟,朱荻.硬质粒子摩擦法电铸新技术的研究[J].中国机械工程,2006,17(1):60-63. 被引量：22
2张爱兵.复杂薄壁类零件的工艺分析[J].科技情报开发与经济,2008,18(4):215-217. 被引量：2

二级参考文献8

1Zhu D, Qu N S, Chan K C. Development of Joint-Electroforming. Technology Journal of Materials Processing Technology, 1997, 63: 844-847.
2McGeough J A, Leu M C, Rajurkar K P, et al.Electroforming Process and Application to Micro/Macro Manufacturing. Annals of the CIRP, 2001,50(2) : 499-514.
3Sole, Michael J, Szendrei, et al. Electroformed Copper Shaped Charge Liners. Proc. AESF Annu. Tech. Conf. ,1991, 78:423-47.
4Thangavelu Pr, Veeramani P, Srinivasan K N,et al(India). Copper Electroforming of Cryogenic Upper Stage Main Engine. Bulletin of Electrochemistry,2000, 16:493-496.
5Budevski E, Staikov G, Lorenz W J. Electr-ocrystallization Nucleation and Growth Phen omena. Electrochimica Acta,2000, 45 : 2559-2574.
6Ye Xingpu, Bonte M De, Celis J P,et al. Role of Overpotential on Texture, Morphology and Ductility of Electrodeposited Copper Foils for Printed Circuit Board Applications. J. Electrochem. Soc.,1992, 139(6):1592-1600.
7Kalantary M R, Wilcox G D, Gabe D R. The Production of Compositionally Modulated Alloys by Simulated High Speed Electrod-eposition from a Single Solution. Electrochimica Acta, 1995, 40:1609-1616.
8Bonhote Ch, Landolt D. Microstructure of Ni-Cu Multilayers Electrodeposited from a Citrate Electrolyte. Electrochimica Acta, 1997, 42:2407-2417.

共引文献22

1胡美些,王宁.我国电铸技术的研究进展[J].电镀与涂饰,2006,25(11):38-41. 被引量：5
2余胜东,朱荻,李学磊,曲宁松,朱增伟.阴极平动式摩擦辅助精密电铸的研究[J].电加工与模具,2009(1):29-32. 被引量：9
3庞梅,李洪友,李哲煜,江开勇,黄超.双向脉冲电铸镍的研究[J].电镀与环保,2010,30(1):11-14. 被引量：4
4李学磊,朱荻,朱增伟.游离粒子对摩擦辅助电铸技术的影响[J].电加工与模具,2010(4):35-39. 被引量：7
5郑志敏,朱荻,朱增伟,曲宁松,李学磊.无裂纹硬铬电镀的试验研究[J].电加工与模具,2011(2):33-36. 被引量：5
6马胜军,沈理达,田宗军,刘志东,黄因慧,王桂峰.电流密度对摩擦喷射电沉积制备镍沉积层微观形貌及性能的影响[J].机械工程材料,2012,36(4):17-20. 被引量：4
7戴乃昌,马金玉,余胜东,豆照峰.粒子流冲刷精密电铸技术的研究[J].煤矿机械,2012,33(10):134-136. 被引量：1
8蒋中江,朱增伟,彭永森.铁-镍合金摩擦辅助电沉积试验[J].中国科技论文,2013,8(3):207-210. 被引量：3
9张磊,沈理达,刘志东,朱军,马云.摩擦喷射电沉积钴的微观形貌和硬度[J].材料科学与工程学报,2013,31(2):243-247. 被引量：1
10徐营,朱增伟,彭永森,任建华.摩擦辅助电铸铜的研究[J].电镀与环保,2014,34(1):16-19. 被引量：6

同被引文献48

1鹿安理,任家烈,吕保才,于淑兰,邓景云.航天器件电铸镍焊接裂纹的研究[J].导弹与航天运载技术,1993(3):65-74. 被引量：2
2雷卫宁,朱荻,曲宁松.纳米晶粒精密电铸层力学性能的试验研究[J].机械工程学报,2004,40(12):124-127. 被引量：12
3朱保国,王振龙.电铸技术的发展及应用[J].电加工与模具,2006(5):1-6. 被引量：28
4彭宝香,吴俊伟.硫酸盐镀铜的故障修复技术[J].涂料涂装与电镀,2007,5(4):29-32. 被引量：2
5Montgomery DC.Design and analysis of experiments. . 2008
6N.S. Qu,W.H. Qian,X.Y. Hu,Z.W. Zhu.??Preparation of a Microprism Ni-Ceo2 Nanocomposite Mold by Electroforming(J)Materials and Manufacturing Processes . 2013 (1)
7E. B. Brousseau,S. S. Dimov,D. T. Pham.??Some recent advances in multi-material micro- and nano-manufacturing(J)The International Journal of Advanced Manufacturing Technology . 2010 (1)
8Z. W. Zhong.??Recent Advances in Polishing of Advanced Materials(J)Materials and Manufacturing Processes . 2008 (5)
9Zeng-Wei Zhu,Di Zhu,Ning-Song Qu,Kun Wang,Jian-Ming Yang.??Electroforming of revolving parts with near-polished surface and uniform thickness(J)The International Journal of Advanced Manufacturing Technology . 2008 (11)
10Zengwei Zhu,Di Zhu,Ningsong Qu,Weining Lei.??Electrodeposition of bright nickel coating under perturbation of hard particles(J)Materials and Design . 2006 (6)

引证文献4

1Jianhua REN,Zengwei ZHU,Chunqiu XIA,Ningsong QU,Di ZHU.Abrasive-assisted Nickel Electroforming Process with Moving Cathode[J].Chinese Journal of Mechanical Engineering,2017,30(2):294-300. 被引量：4
2王兆新,任建华,姚传慧,尹冠华.硫酸铜浓度及电流密度的变化对游离微珠辅助磨电铸铜的影响[J].表面技术,2023,52(1):401-409. 被引量：1
3王兆新,任建华,尹冠华,姚传慧,朱增伟.阴极复合运动游离微珠辅助磨擦电铸装置的设计[J].电镀与精饰,2023,45(4):64-69.
4Ren Jianhua,Zhu Zengwei,Zhu Di.Effects of process parameters on mechanical properties of abrasive-assisted electroformed nickel[J].Chinese Journal of Aeronautics,2016,29(4):1096-1102. 被引量：2

二级引证文献6

1赵勇飞,钱双庆,章勇,张华,陈文龙.电铸铜制备小直径薄壁回转体零件[J].电镀与涂饰,2020,39(8):456-460.
2闫广亮,张凤鹏,郝红泽,高继开.电爆炸破碎岩石类脆性材料实验方法与应用[J].煤炭学报,2021,46(10):3203-3211. 被引量：4
3尹冠华,任建华,姚传慧,王兆新.基于游离微珠摩擦辅助的阴极复合运动电铸装置的设计及试验研究[J].电镀与涂饰,2022,41(5):325-331.
4王兆新,任建华,姚传慧,尹冠华.硫酸铜浓度及电流密度的变化对游离微珠辅助磨电铸铜的影响[J].表面技术,2023,52(1):401-409. 被引量：1
5姚传慧,任建华,尹冠华,董迎港,周超.微珠柔性受压辅助磨电铸镍工艺[J].电镀与涂饰,2023,42(9):24-30.
6王晓峰.风力发电机组受共模电流的影响分析[J].南方能源建设,2023,10(4):158-165.

1朱增伟,朱荻,曲宁松,雷卫宁.Pulse electroforming of nickel under perturbation of hard particles[J].中国有色金属学会会刊：英文版,2005,15(S3):251-254.
2张绍维.低膨胀高温合金的发展与应用[J].航空制造工程,1994(9):5-8. 被引量：11
3吕镖,胡振峰,汪笑鹤,徐滨士.电流密度对镍镀层结构和性能的影响[J].中国表面工程,2013,26(4):66-71. 被引量：23
4班无用,刘伦贤,庄兴民,晏雄.丙纶基熔喷非织造材料吸声性能研究[J].上海纺织科技,2013,41(7):14-16. 被引量：4
5王文星,严志伟,麻鲁田,吴旭九.纯棉织物免烫整理工艺探讨[J].河南纺织科技,1999,20(2):9-12.
6吕镖,汪笑鹤,胡振峰,徐滨士.不同电流密度下阴极移动对电镀镍层性能的影响[J].电镀与涂饰,2013,32(10):5-9. 被引量：8
7潘应君,宫娜,张恒.纯铝表面TiO_2涂层的光阴极保护行为[J].武汉科技大学学报,2007,30(1):17-19. 被引量：1
8李劼科,马正.高速主轴的轴承技术[J].轴承工业,2004(5):23-27. 被引量：1
9Gang WU Ning LI Derui ZHOU Kurachi Mitsuo.Microstructure of Co-Ni-Al2O3 Composite Coatings by Electroforming[J].Journal of Materials Science & Technology,2003,19(z1):133-134.
10孟庆森,薛锦.Study on comprehensive properties of duplex austenitic surfacing alloys for impacting abrasion[J].China Welding,2000,9(1):11-16.

Journal of Wuhan University of Technology(Materials Science)

2011年第5期

浏览历史

内容加载中请稍等...