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针对粉末冶金行业最新发展的几种短流程成形固结新技术,结合华南理工大学近十多年来在粉末材料-工艺-装备-零件一体化方面开展的研究,重点阐述了粉末冶金温压成形、高速压制成形、喷射成形、多场作用下粉末成形与烧结一体化技术的研究进展及应用情况。指出在粉末冶金成形固结研究领域,合理拓展现有粉末冶金技术规范的空间,有望给传统粉末冶金成形固结技术注入新的活力。粉末冶金成形固结新技术的不断出现,必将促进先进制造业和高技术产业的快速发展,也必将给材料工程和制造业带来更加光明的前景。

Based on the resuhs gained from the integrating researches on powder materials-processing techniques-equipments carried out in South China University of Technology in the past two decades, the novel powder metallurgy short process forming and consolidation techniques, with elaboration stressed on the research progress and application status of warm compaction forming, high-velocity compaction forming, spray forming, integrated multi-field powder metallurgy form- ing and consolidation techniques, are mainly introduced. Expanding the content of existing powder metallurgy technical specifications with insight may inject new vigor into the traditional powder metallurgy forming and consolidation. The continuous emergence of novel techniques will not only accelerate the rapid development of the advanced manufacturing and high-tech industries, but will also bring a bright future for materials engineering and manufacturing industries.

参考文献

[1] Capus J;Picketing S;Weaver A .Hoeganaes Offers Higher Density at Lower Cost[J].Metal Powder Report,1994,49(7/8):22-24.
[2] Howard G. Rutz;Francis G. Hanejko .HIGH DENSITY PROCESSING OF HIGH PERFORMANCE FERROUS MATERIALS[J].International Journal of Powder Metallurgy,1995(1):9,11-17-0.
[3] Capus J .Warm Compacted Turbine Hub Leads New PM Thrust[J].Metal Powder Report,1997,61(09):19.
[4] 李元元.金属粉末温压成形原理与技术[M].广州:华南理工大学出版社,2008:12.
[5] Pickering S .Warm Compacted Turbine Hub Earns Top Ferrous Prize from MPIF[J].Metal Powder Report,1997,7/8:12.
[6] Lothar Albano-Müller.新千年初的欧洲粉末冶金[J].粉末冶金工业,2001(02):7-13.
[7] Skoglund P;Bengtsson S;Bergstroem M.Material for Warm Compacted Heavy Truck Transmission Part[J].Advances in Powder Metallurgy and Particulate Materials,2000(06):6-10.
[8] 藤木章,前川幸広,马渕豊,渡部贵也,菅谷好美,岩切诚,芝野隆.直喷汽油(DIG)汽车发动机无声链条系统用温压-高温烧结粉末冶金链轮的开发[J].粉末冶金技术,2003(02):86-91.
[9] 朔风 .1998-2009年美国MPIF获奖粉末冶金零件介绍[J].粉末冶金技术,2010,28(05):395-397.
[10] 姜娟,李瑛,朱明原,杨秋平,田野.温压成型工艺制备钕铁硼粘结磁体[J].有色金属,2008(01):44-47.
[11] 果世驹.粉末冶金温压技术的进展[J].粉末冶金工业,2003(02):3-8.
[12] Hanejko F .用一次压制、一次烧结达到高密度[J].粉末冶金技术,2010,28(02):73-76.
[13] Michael L. Marucci .AncorMax D: a unique binder-lubricant for high-density applications[J].Metal Powder Report,2003(10 Suppl.):16-17.
[14] Warm flow compaction fosters more complex PM parts[J].Metal Powder Report,2001(2):26-28.
[15] Capus J .PM Progress Towards Wrought Steel Gear Performance[J].Powder Metallurgy,2003,46(04):301-302.
[16] St-Laurent S;Changnon F .为温压工艺设计的混合粉[J].粉末冶金技术,1998,16(01):40-51.
[17] P. Lemieux,Y. Thomas,P.E.Mongeon,S.Pelletier,S. St-Laurent,郭瑞金,韩凤麟.用静电模壁润滑-温压复合工艺增高粉末冶金零件生坯与烧结件性能[J].粉末冶金技术,2006(04):310-312.
[18] Toyota hits on smooth formula for compaction[J].Metal Powder Report,2002(9):30-31.
[19] 肖志瑜,李元元,倪东惠.粉末冶金温压的致密化机理[J].粉末冶金材料科学与工程,2006(02):85-90.
[20] 张菊红,肖志瑜,温利平,潘国如.不同方法制备的温压粉末形貌及工艺性能[J].粉末冶金材料科学与工程,2006(03):155-158.
[21] LI Yuan-yuan,ZHAO Wei-bin,ZHOU Zhao-yao,CHEN Pu-qing.Coupled mechanical and thermal simulation of warm compaction[J].中国有色金属学会会刊(英文版),2006(02):311-315.
[22] HVC punches PM to new mass production limits[J].Metal Powder Report,2002(9):26-30.
[23] Skoglund P .High Density P/M Components by High Velocity Compaction[J].Powder Metallurgy,2001,44(03):15-17.
[24] Hoganas promotes potential of high velocity compaction[J].Metal Powder Report,2001(9):6-0.
[25] 王建忠,曲选辉,尹海清,周晟宇,易明军.电解铜粉高速压制成形[J].中国有色金属学报,2008(08):1498-1503.
[26] 闫志巧,陈峰,蔡一湘,崔亮.Ti粉的高速压制成形及表征[J].金属学报,2010(02):227-232.
[27] 邓三才,肖志瑜,陈进,许阳,关航健.粉末冶金高速压制技术的研究现状及展望[J].粉末冶金材料科学与工程,2009(04):213-217.
[28] 邓三才,肖志瑜,陈进,张富兵,许阳.模壁润滑高速压制成形Fe-2Cu-1C粉末的研究[J].粉末冶金工业,2009(06):28-32.
[29] Tang Cuiyong;Xiao Zhiyu;Chen Jin .Compaction Experiment on the Newly Designed High Velocity Warm Compaction Equipment[J].Current Advances in Materials and Processes,2010,139 - 141:485-488.
[30] A.Leatbam .Spray forming: alloys, products and markets[J].Metal Powder Report,1999(4):28-37.
[31] Grant P S .Spray Forming[J].Progress in Materials Science,2005,39:497-545.
[32] 陈振华.多层喷射沉积技术及应用[M].长沙:湖南大学出版社,2003
[33] Yunzhong Liu;Yuanyuan Li .Numerical Simulation of Thermal History in A Novel Spray Forming Process[J].Materials Science Forum,2007(Pt.2):1171-1176.
[34] LIU Yun-zhong,K. Minagawa,H. Kakisawa,K. Halada.Melt film formation and disintegration during novel atomization process[J].中国有色金属学会会刊(英文版),2007(06):1276-1281.
[35] K.M. McHugh;J.-P. Delplanque;S.B. Johnson .Spray rolling aluminum alloy strip[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2004(1):96-106.
[36] McHugh K M;Lin Y;Zhou Y et al.Microstructure Evolution during Spray Roiling and Heat Treatment of 2124 Al[J].Materials Science and Engineering A:Structural Materials Properties Microstructure and Processing,2008,477:26-28.
[37] Yanagisawa O.;Kuramoto H.;Matsugi K.;Komatsu M. .Observation of particle behavior in copper powder compact during pulsed electric discharge[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2003(1/2):184-189.
[38] Xiaoyan Song;Xuemei Liu;Jiuxing Zhang .Neck Formation and Self-Adjusting Mechanism of Neck Growth of Conducting Powders in Spark Plasma Sintering[J].Journal of the American Ceramic Society,2006(2):494-500.
[39] Frei JM;Anselmi-Tamburini U;Munir ZA .Current effects on neck growth in the sintering of copper spheres to copper plates by the pulsed electric current method[J].Journal of Applied Physics,2007(11):14914-1-14914-8-0.
[40] Olevsky E;Froyen L .Constitutive modeling of spark-plasma sintering of conductive materials[J].Scripta materialia,2006(12):1175-1178.
[41] J.E. Garay;U. Anselmi-Tamburini;Z.A. Munir .Enhanced growth of intermetallic phases in the Ni-Ti system by current effects[J].Acta materialia,2003(15):4487-4495.
[42] Friedman J R;Garay J E;Anselmi-Tamburini U et al.Modified Interracial Reactions in Ag-Zn Multilayers under the Influence of High DC Currents[J].Intermetallics,2005,12(06):589-597.
[43] U. Anselmi-Tamburini;J. E. Garay;Z. A. Munir .Fundamental investigations on the spark plasma sintering/synthesis process -- III. Current effect on reactivity[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2005(1/2):24-30.
[44] N. Bertolino;J. Garay;U. Anselmi-Tamburini .ELECTROMIGRATION EFFECTS IN Al-Au MULTILAYERS[J].Scripta materialia,2001(5):737-742.
[45] Yanagisawa O.;Kuramoto H.;Matsugi K.;Komatsu M. .Observation of particle behavior in copper powder compact during pulsed electric discharge[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2003(1/2):184-189.
[46] Chen W;Anselmi-Tamburini U;Garay JE;Groza JR;Munir ZA .Fundamental investigations on the spark plasma sintering/synthesis process - I. Effect of dc pulsing on reactivity[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2005(1/2):132-138.
[47] Yuanyuan LI,Xiaoqiang LI,Yan LONG,Wei XIA,Min ZHU,Weiping CHEN.Fabrication of Iron-base Alloy by Spark Plasma Sintering[J].材料科学技术学报(英文版),2006(02):257-260.
[48] Takida T;Mabuchi M;Nakamura M et al.Mechanical Properties of a ZrC-Disperesed Mo Alloy Processed by Mechanical Alloying and Spark Plasma Sintering[J].Materials Science and Engineering A:Structural Materials Properties Microstructure and Processing,2000,275(1 - 2):269-272.
[49] Y.H. Wang;J.P. Lin;Y.H. He .Fabrication and SPS microstructures of Ti-45Al-8.5Nb-(W,B,Y) alloying powders[J].Intermetallics,2008(2):215-224.
[50] Zhao-Hui Zhang;Fu-Chi Wang;Jie Luo;Shu-Kui Lee;Lu Wang .Processing and characterization of fine-grained monolithic SiC ceramic synthesized by spark plasma sintering[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2010(7/8):2099-2103.
[51] Lin C G;Kny E;Yuan G S et al.Microstructure and Properties of Ultrafine WC-0.6VC-10Co Hardmetals Densified by Pressure- Assisted Critical Liquid Hhase Sintering[J].Journal of Alloys and Compounds,2004,383:98-102.
[52] Yuanyuan LI,Xiaoqiang LI,Yan LONG,Wei XIA,Min ZHU,Weiping CHEN.Fabrication of Iron-base Alloy by Spark Plasma Sintering[J].材料科学技术学报(英文版),2006(02):257-260.
[53] Li X Q;Xiao Z Y;Li Y Y et al.WC-8Co-2Al(w%)Cemented Carbides Prepared by Mechanical Milling and Spark Plasma Sintering[J].Materials Science Forum,2010,638-642:1817-1823.
[54] LI Xiao-qiang,XIN Hong-wei,HU Ke,LI Yuan-yuan.Microstructure and properties of ultra-fine tungsten heavy alloys prepared by mechanical alloying and electric current activated sintering[J].中国有色金属学报(英文版),2010(03):443-449.
[55] 张寅,李小强,叶永权,杨俊逸.电场活化烧结制备Cu-10Cr-0.5Al2O3复合材料[J].粉末冶金材料科学与工程,2010(03):212-218.
[56] Li, YY;Yang, C;Chen, WP;Li, XQ;Qu, SG .Ultrafine-grained Ti66Nb13Cu8Ni6.8Al6.2 composites fabricated by spark plasma sintering and crystallization of amorphous phase[J].Journal of Materials Research,2009(6):2118-2122.
[57] Li, Y.Y.;Yang, C.;Wei, T.;Li, X.Q.;Qu, S.G. .Ductile fine-grained Ti-O-based composites with ultrahigh compressive specific strength fabricated by spark plasma sintering[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2011(3):1897-1900.
[58] 杨俊逸,李元元,李小强,郭亮,陈维平.模具的热电属性对电流烧结温度场的影响[J].特种铸造及有色合金,2007(01):24-27.
[59] Guo L;Li Y Y;Li X Q et al.Numerical Analysis on Temperature Field of Axial Ahernating Magnetic Field-Assisted Electric Field-Activated Sintering[J].Materials Science Forum,2008,575 - 578:702-708.
[60] Xiaoqiang Li;Yongquan Ye;Yu Tang;Shengguan Qu .Effect of Pulsed Magnetic Field on Spark Plasma Sintering of Iron-Based Powders[J].Materials transactions,2010(7):1308-1312.
[61] Verzhakovskaya M A;Petrov S S;Pokoev A V .Effect of Pulsed Magnetic Field on the Diffusion of Aluminum in Iron and the Fine- Structure Parameters of Iron[J].Bulletin of the Russian Academy Sciences:Physics,2007,71(12):1674-1679.
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