Zobrazeno 1 - 10
of 41
pro vyhledávání: '"T. Komagome"'
Autor:
T. Onji, R. Inomata, T. Yagai, T. Takao, Y. Makida, T. Shintomi, N. Hirano, T. Komagome, T. Hamajima
Publikováno v:
IEEE Transactions on Applied Superconductivity. 33:1-5
Autor:
T. Yagai, M. Takahashi, R. Inomata, T. Takao, T. Onji, T. Komagome, Y. Makida, T. Shintomi, N. Hirano, T. Hamajima, A. Kikuchi, G. Nishijima, A. Matsumoto
Publikováno v:
IEEE Transactions on Applied Superconductivity. 32:1-5
Publikováno v:
IEEE Transactions on Applied Superconductivity. 32:1-5
Autor:
Makoto Tsuda, Toru Okubo, Taiki Onji, Yasuhiro Makida, Masahiro Kamibayashi, T. Komagome, Takataro Hamajima, Tsuyoshi Yagai, Tomoaki Takao, A. Ishihara, Daisuke Miyagi, Masaru Tomita, Moeto Hira, Yusuke Kuwabara, Kenichi Tsukada, Arai Yuki, Naoki Hirano, Takakazu Shintomi, Mana Jimbo
Publikováno v:
IEEE Transactions on Applied Superconductivity. 29:1-5
MgB 2 wires have been provided by several manufacturers, showing enough critical current (Ic) for practical applications in relatively low-field. Because the MgB 2 has critical temperature above boiling temperature of hydrogen, dc power distribution
Autor:
Tsuyoshi Yagai, Mana Jimbo, T. Komagome, Yusuke Kuwabara, Takataro Hamajima, Akihiro Kikuchi, Tomoaki Takao, Masaru Tomita, Naoki Hirano, Kenichi Tsukada, Takakazu Shintomi, Taiki Onji, Masahiro Kamibayashi, Yasuhiro Makida
Publikováno v:
IEEE Transactions on Applied Superconductivity. 29:1-5
MgB2 superconductors are promising candidates for application to devices such as Superconducting Magnetic Energy Storage, and generators. To apply MgB2 conductors to such devices, the current capacity of a conductor must be in the kilo-ampere range.
Autor:
H. Ayakawa, Kenichi Tsukada, Daisuke Miyagi, Makoto Tsuda, Y. Ishii, Z. Zhang, T. Komagome, Takataro Hamajima, Yoh Nagasaki, D. Yonekura
Publikováno v:
International Journal of Hydrogen Energy. 44:8403-8414
In order to realize a large-capacity stand-alone emergency power supply that enables highly reliable and high-quality power supply at the time of a large-scale natural disaster and enables effective use of solar power generation, we proposed an elect
Autor:
A. Ishihara, Naoki Hirano, Tomoaki Takao, Y. Makida, Yusuke Kobayashi, Takakazu Shintomi, Masaru Tomita, T. Komagome, Kenichi Tsukada, Takataro Hamajima, Yusuke Fukumoto, Shinya Mizuno, Tsuyoshi Yagai, Taiki Onji
Publikováno v:
IEEE Transactions on Applied Superconductivity. 28:1-4
A prototype pancake coil using a MgB2 Rutherford-type stranded conductor for superconducting magnetic energy storage (SMES) proposed in the Advanced Superconducting Power Conditioning System was fabricated and evaluated. The conductor consisted of a
Autor:
Yasuhiro Makida, Sora Mizuochi, Shinya Mizuno, Tsuyoshi Yagai, Tomoaki Takao, Takakazu Shintomi, Masahiro Kamibayashi, Makoto Tsuda, T. Komagome, Mana Jinbo, Takataro Hamajima, Masaru Tomita, Kenichi Tsukada, Daisuke Miyagi, Toru Okubo, Taiki Onji, Arai Yuki, Naoki Hirano
Publikováno v:
IEEE Transactions on Applied Superconductivity. 28:1-5
Superconducting magnetic energy storage (SMES) devices of several tens of kJ class are generally suitable for voltage compensation for microgrids, which produce and distribute electric power to restricted areas. MgB2 material has been developed with
Autor:
T. Shintomi, Shizuichi Fujikawa, K. Hanada, R. Miyajima, Naoki Hirano, Daisuke Miyagi, Tsuyoshi Yagai, Yutaka S. Sato, Katsuya Iwaki, Z. Zhang, H. Tsujigami, T. Komagome, Makoto Tsuda, Takataro Hamajima, Tomoaki Takao, Yasuhiro Makida
Publikováno v:
IEEE Transactions on Applied Superconductivity. 26:1-5
Due to global issue of energy shortage, alternative energy such as solar and wind energy has to be introduced to the commercial electricity grid. A hybrid energy storage system which is able to convert unstable alternative energy into constant electr
Autor:
Taiki Onji, Daisuke Miyagi, Masaru Tomita, Naoki Hirano, Makoto Tsuda, Yuuki Arai, Kenichi Tsukada, A. Ishihara, T. Komagome, M. Hira, Takakazu Shintomi, Takataro Hamajima, Yasuhiro Makida, Tomoaki Takao, Tsuyoshi Yagai
Publikováno v:
Journal of Physics: Conference Series. 1590:012058
We have developed the system called Advanced Superconducting Power Conditioning System (ASPCS) composed of a Superconducting Magnetic Energy Storage (SMES), a fuel cell and a water electrolyzer for effective use of renewable energy such as wind and s