ONZAWA Tadao | Tokyo Institute of Technology
スポンサーリンク
概要
関連著者
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ONZAWA Tadao
Tokyo Institute of Technology
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Tamura Hiroshi
Tokyo Institute Of Technology
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Tamura Hiroshi
Tokyo Institute Of Technolngy
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TAMURA Hiroshi
Tokyo Research Institute, Seikagaku Corporation
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ISHII Yugoro
Tokyo Institute of Technology
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Suzumura Akio
Tokyo Institute Of Technology
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YASUDA Ken
Hitachi Research Lovoratory, Hitachi Ltd.
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Yasuda K
Institute Of Vocational Training
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HINATA Teruhiko
Institute of Vocational Training
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YASUDA Katsuhiko
Institute of Vocational Training
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Onzawa T
Tokyo Institute Of Technology
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YAMASHITA Tadayoshi
Defense Academy
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Hinata T
Institute Of Vocational Training
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Taneda Youji
Defense Academy
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UEMATSU Susumu
Cradnate School, Tokyo, Inst. of Tech.
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MAEKAWA Kiyoaki
Tokyo Institute of Technology
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UEMATSU Susumu
Ship Research Institute
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IGAWA Makoto
Suganuma Ltd.
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KASUGA Yukio
Takushoku University
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HATAKEYAMA Kotaro
Tokyo Institute of Technology
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Ishii Yugoro
Nihon University
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Takahashi Kunio
Tokyo Institute Of Technology
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YIN Yingchen
Tokyo Institute of Technology
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YUAN Xiaoying
Advance Soft Corporation
著作論文
- Notch Toughness and Retained Austenite in 9% Ni Steel Welds Using Ferritic Filler Metals
- Influence of Gas-Tungsten-Arc Electrode Material on AC TIG Arc Welding
- Study on Penetration Form Using Stationary TIG Arc : Study on Low Speed DC-TIG Welding Method
- Solid State Diffusion Weldability of High Temperature Alloy A286 and Hastelloy X
- Diffusion Welding Copper-Nickel Alloys to Carbon Steel
- Effect of Heating on Mechanical Properties and Microstructures of Explosive Stainless Clad Steels
- Notch Toughness and Retained Austenite in Synthetic HAZ of 9% Ni Steel
- Microstructures of Explosively Bonded Metals as Observed by Transmission Electron Microscopy : Low carbon-steel clad and austenitic stainless clad steel
- Study on Wave Formation in Explosive Bonding
- Fundamental Studies on Explosive Welding : Observations of Metal jet and wavy pattern
- Dimer Reference Embedded Atom Method (DR-EAM) and Its Application to Vacancy Formation Energy of FCC Metals