System Design for High Energy Rate Electromagnetic Powder Compaction Devices

Jun Liu; Gang Yi Zhou; Xin Long Dong; Guo Fu Li

doi:10.4028/www.scientific.net/AMR.97-101.1146

Paper Titles

Carbon Foams with High Compressive Strength Derived from Mixtures of Mesophase Pitch and Si Particles
p.1130

Study on Friction Properties of Cu-Based Friction Materials with Ni Coated Nano-SiO₂ Particles
p.1134

Synthesis of α-Al₂O₃ Platelets in Molten Salt for High Performance Ceramics
p.1138

Synthesis of High Nitrogen Stainless Steel Powders by High Energy Ball Milling and their SPS Compaction
p.1142

System Design for High Energy Rate Electromagnetic Powder Compaction Devices
p.1146

An Experimental Study of Fine Powder Comminution in a Dual Cone Impact Mill
p.1150

Research of Constitutive Relation of Metal Powder in High Velocity Compaction
p.1154

Research on Manufacturing Technology and Heat Transfer Characteristics of Sintered Porous Surface Tubes
p.1161

Thermoelectric Properties of Iron Disilicide Prepared by Field-Activated Synthesis Process
p.1166

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 97-101System Design for High Energy Rate Electromagnetic...

System Design for High Energy Rate Electromagnetic Powder Compaction Devices

Abstract:

In this paper, the main element is constructed high energy electromagnetic compaction system on the high-energy flat coil. Physical model for analyzing dynamic response of high pulse current was reviewed. Design loading device using high energy electromagnetic technology to suppress powder, consider the exhaust, stripping, loading, positioning and other issues,propose a more reasonable program.The device includes various components of the installation. such as coil, the coil plate, driver, amplifiers, punching first, die, upper and lower fixing plate. The model of device based on Pro/E to facilitate manufacturing.Pressure embryo along the suppression direction has more uniform density distribution.The technology possesses advantagesof the single side forming and directional loading.

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Periodical:

Advanced Materials Research (Volumes 97-101)

Pages:

1146-1149

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.97-101.1146

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Online since:

March 2010

Authors:

Jun Liu, Gang Yi Zhou, Xin Long Dong, Guo Fu Li

Keywords:

Flat Coil, High Energy Electromagnetic, Loading Device, Powder Compacting

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References

[1] M.H. Es-Saheb. Journal of Materials Processing Technology. Vol. 178(2006), pp.143-147.

Google Scholar

[2] M. Rosinski, E. Fortuna, A. Michalski,Z. Pakiela, K.J. Kurzydlowski. Fusion Engineering and Design. Vol. 82 (2007), pp.2621-2626.

DOI: 10.1016/j.fusengdes.2007.06.017

Google Scholar

[3] M. Anhalt. Journal of Magnetism and Magnetic Materials. Vol. 320 (2008), p. c266-c369.

Google Scholar

[4] S.J. Hong, G.H. Lee , C.K. Rhee, W.W. Kim, K.S. Lee. Materials Science and Engineering. Vol. 449 (2007), pp.401-406.

Google Scholar

[5] H.P. Yu, C.F. Li. Acta Metallurgica Sinica (English Letters). Vol. 20 (2007), pp.277-283.

Google Scholar

[6] Xiyong Wu, Jingdong Guo. International Journal of Refractory Metals & Hard Materials. Vol. 26 (2008), pp.28-32.

Google Scholar

[7] E.G. Grigoriev. Journal of Materials Processing Technology. Vol. 191 (2007), pp.182-184.

Google Scholar

[8] S. Yang, J.R.G. Evans. Powder Technology. Vol. 178 (2007), pp.56-72.

Google Scholar

[9] Liu Jun, Zhou Gang-yi , Dong Xin-long. Light Industry Machinery. Vol. 25 (2007), pp.71-73.

Google Scholar

[10] M. Alitavoli, A. Darvizeh. Journal of materials processing technology. Vol. 209 (2009), pp.3542-3549.

Google Scholar

[11] Shoufeng Yang, Julian R.G. Evans. Powder Technology. Vol. 154 (2005), pp.94-98.

Google Scholar