Ion-Beam Driven Shock Loading Device for Compaction

M. Tsuchida; T. Aizawa; K. Horioka

doi:10.4131/jshpreview.7.948

Ion-Beam Driven Shock Loading Device for Compaction

M. Tsuchida, T. Aizawa, K. Horioka

Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Ion-beam driven shock loading device is proposed to make efficient dynamic compaction of nanocrystal and non-equilibrium powders. Different form the conventional gas-guns and powder fire-guns, the repetitive application of shock pressure pulse to targeting materials and the fine control of pressure pulse are intrinsic features to the present approach. Since the generated plasmoid is electro-magnetically accelerated to launch the flyer, no limitation to flyer velocity is present. The laser doppler velocimetry is used to make real time measurement of copper flyer velocity. The efficiency is estimated to be about 6 % for conversion from the accumulated energy in the condenser bank to the kinetic energy of a flyer.

Original language	English
Pages (from-to)	948-950
Number of pages	3
Journal	Review of High Pressure Science and Technology/Koatsuryoku No Kagaku To Gijutsu
Volume	7
DOIs	https://doi.org/10.4131/jshpreview.7.948
Publication status	Published - 1998 Jan 1

Keywords

Ion beam
Non-equilibrium phase
Powder compaction
Recovery
Shock wave

ASJC Scopus subject areas

Chemistry(all)
Materials Science(all)
Condensed Matter Physics

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abstract = "Ion-beam driven shock loading device is proposed to make efficient dynamic compaction of nanocrystal and non-equilibrium powders. Different form the conventional gas-guns and powder fire-guns, the repetitive application of shock pressure pulse to targeting materials and the fine control of pressure pulse are intrinsic features to the present approach. Since the generated plasmoid is electro-magnetically accelerated to launch the flyer, no limitation to flyer velocity is present. The laser doppler velocimetry is used to make real time measurement of copper flyer velocity. The efficiency is estimated to be about 6 % for conversion from the accumulated energy in the condenser bank to the kinetic energy of a flyer.",

keywords = "Ion beam, Non-equilibrium phase, Powder compaction, Recovery, Shock wave",

author = "M. Tsuchida and T. Aizawa and K. Horioka",

year = "1998",

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doi = "10.4131/jshpreview.7.948",

language = "English",

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T1 - Ion-Beam Driven Shock Loading Device for Compaction

AU - Tsuchida, M.

AU - Aizawa, T.

AU - Horioka, K.

PY - 1998/1/1

Y1 - 1998/1/1

N2 - Ion-beam driven shock loading device is proposed to make efficient dynamic compaction of nanocrystal and non-equilibrium powders. Different form the conventional gas-guns and powder fire-guns, the repetitive application of shock pressure pulse to targeting materials and the fine control of pressure pulse are intrinsic features to the present approach. Since the generated plasmoid is electro-magnetically accelerated to launch the flyer, no limitation to flyer velocity is present. The laser doppler velocimetry is used to make real time measurement of copper flyer velocity. The efficiency is estimated to be about 6 % for conversion from the accumulated energy in the condenser bank to the kinetic energy of a flyer.

AB - Ion-beam driven shock loading device is proposed to make efficient dynamic compaction of nanocrystal and non-equilibrium powders. Different form the conventional gas-guns and powder fire-guns, the repetitive application of shock pressure pulse to targeting materials and the fine control of pressure pulse are intrinsic features to the present approach. Since the generated plasmoid is electro-magnetically accelerated to launch the flyer, no limitation to flyer velocity is present. The laser doppler velocimetry is used to make real time measurement of copper flyer velocity. The efficiency is estimated to be about 6 % for conversion from the accumulated energy in the condenser bank to the kinetic energy of a flyer.

KW - Ion beam

KW - Non-equilibrium phase

KW - Powder compaction

KW - Recovery

KW - Shock wave

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ER -

Ion-Beam Driven Shock Loading Device for Compaction

Abstract

Keywords

ASJC Scopus subject areas

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