Theoretical analysis of annular laminar flows with MHD interaction driven by rotating co-axial cylinder

Ryo Sasaki; Takayasu Fujino; Hidemasa Takana; Hiromichi Kobayashi

doi:10.1002/ecj.12311

Theoretical analysis of annular laminar flows with MHD interaction driven by rotating co-axial cylinder

Ryo Sasaki, Takayasu Fujino, Hidemasa Takana, Hiromichi Kobayashi

法学部

研究成果: Article › 査読

2 被引用数 (Scopus)

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Theoretical solution is derived for annular laminar flows with MHD interaction driven by a rotating co-axial cylinder. The effects on the flow field and rotational torque are clarified by changing the radius ratio and the strength of MHD interaction. As the radius ratio increases, azimuthal flow velocity increases and approaches the plane Couette flow profile for weak MHD interaction. The azimuthal flow velocity, however, decreases as the MHD interaction increases, and the reverse flow emerges in large radial locations. As the MHD interaction increases, the rotational torque increases. A larger radius ratio leads to the larger sensitivity of the change in rotational torque.

本文言語	English
論文番号	12311
ジャーナル	Electronics and Communications in Japan
巻	104
号	2
DOI	https://doi.org/10.1002/ecj.12311
出版ステータス	Published - 2021 6月

ASJC Scopus subject areas

信号処理
物理学および天文学（全般）
コンピュータネットワークおよび通信
電子工学および電気工学
応用数学

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10.1002/ecj.12311

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abstract = "Theoretical solution is derived for annular laminar flows with MHD interaction driven by a rotating co-axial cylinder. The effects on the flow field and rotational torque are clarified by changing the radius ratio and the strength of MHD interaction. As the radius ratio increases, azimuthal flow velocity increases and approaches the plane Couette flow profile for weak MHD interaction. The azimuthal flow velocity, however, decreases as the MHD interaction increases, and the reverse flow emerges in large radial locations. As the MHD interaction increases, the rotational torque increases. A larger radius ratio leads to the larger sensitivity of the change in rotational torque.",

keywords = "annular rotating flow, MHD interaction, theoretical analysis, torque control",

author = "Ryo Sasaki and Takayasu Fujino and Hidemasa Takana and Hiromichi Kobayashi",

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doi = "10.1002/ecj.12311",

language = "English",

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AU - Sasaki, Ryo

AU - Fujino, Takayasu

AU - Takana, Hidemasa

AU - Kobayashi, Hiromichi

N1 - Funding Information: This study was conducted with a grant under the Collaborative Research Project from the Institute of Fluid Science at Tohoku University. Publisher Copyright: © 2021 Wiley Periodicals LLC

PY - 2021/6

Y1 - 2021/6

N2 - Theoretical solution is derived for annular laminar flows with MHD interaction driven by a rotating co-axial cylinder. The effects on the flow field and rotational torque are clarified by changing the radius ratio and the strength of MHD interaction. As the radius ratio increases, azimuthal flow velocity increases and approaches the plane Couette flow profile for weak MHD interaction. The azimuthal flow velocity, however, decreases as the MHD interaction increases, and the reverse flow emerges in large radial locations. As the MHD interaction increases, the rotational torque increases. A larger radius ratio leads to the larger sensitivity of the change in rotational torque.

AB - Theoretical solution is derived for annular laminar flows with MHD interaction driven by a rotating co-axial cylinder. The effects on the flow field and rotational torque are clarified by changing the radius ratio and the strength of MHD interaction. As the radius ratio increases, azimuthal flow velocity increases and approaches the plane Couette flow profile for weak MHD interaction. The azimuthal flow velocity, however, decreases as the MHD interaction increases, and the reverse flow emerges in large radial locations. As the MHD interaction increases, the rotational torque increases. A larger radius ratio leads to the larger sensitivity of the change in rotational torque.

KW - annular rotating flow

KW - MHD interaction

KW - theoretical analysis

KW - torque control

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Theoretical analysis of annular laminar flows with MHD interaction driven by rotating co-axial cylinder

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