Numerical Investigation of Cavitating Flow Around a Hydrofoil Considering Advection–Diffusion and Precipitation of Dissolved Gas in Liquid

Yoshihito Higa; Ryo Iida; Shin Ichi Tsuda; Satoshi Watanabe

doi:10.1007/978-981-99-9470-0_9

Numerical Investigation of Cavitating Flow Around a Hydrofoil Considering Advection–Diffusion and Precipitation of Dissolved Gas in Liquid

Yoshihito Higa, Ryo Iida, Shin Ichi Tsuda, Satoshi Watanabe

流体工学

研究成果: 書籍/レポートタイプへの寄稿 › 会議への寄与

抄録

Hydraulic cavitation is mainly affected by the pressure or velocity field, but the detailed flow structure also depends on other factors such as surface wall roughness or working fluid quality. Among those, the present study has focused on the influence of air content as a non-condensable gas in water, which is one of the factors in water quality. The novel point in this study is that we have applied a simple but physics-based model taking account of the mass transfer of the non-condensable gas based on mass conservation law in the CFD simulations. On the basis of the assumption of a homogeneous bubbly flow, the simulations were conducted by solving five governing equations for cavitation around a hydrofoil of Clark Y-11.7% (angle of attack is 8°) modifying interPhaseChageFoam of OpenFOAM v1706. As a result, the lift coefficient containing air showed higher values than the case without the gas in a certain developed cavitation state showing a periodic change of the hydrofoil lift force, and it may improve the current prediction accuracy of the lift in many CFD simulations. In the case with much air content, an attached cavity around the leading edge due to the influence of the precipitation of air was confirmed even at the time of the minimum lift force, different from the case with little content of air.

本文言語	英語
ホスト出版物のタイトル	Proceedings of the 9th Asian Joint Workshop on Thermophysics and Fluid Science, 2022 - Asian Research in Thermal and Fluid Sciences
編集者	Abhilash Suryan, Minoru Yaga, Han Seo Ko, Zhang Guang
出版社	Springer Science and Business Media Deutschland GmbH
ページ	73-81
ページ数	9
ISBN（印刷版）	9789819994694
DOI	https://doi.org/10.1007/978-981-99-9470-0_9
出版ステータス	出版済み - 2024
イベント	9th Asian Joint Workshop on Thermophysics and Fluid Science, AJWTF 2022 - Utsunomiya, 日本継続期間: 11月 27 2022 → 11月 30 2022

出版物シリーズ

名前	Springer Proceedings in Physics
巻	396
ISSN（印刷版）	0930-8989
ISSN（電子版）	1867-4941

会議

会議	9th Asian Joint Workshop on Thermophysics and Fluid Science, AJWTF 2022
国/地域	日本
City	Utsunomiya
Period	11/27/22 → 11/30/22

!!!All Science Journal Classification (ASJC) codes

物理学および天文学一般

文献へのアクセス

10.1007/978-981-99-9470-0_9

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引用スタイル

Higa, Y., Iida, R., Tsuda, S. I., & Watanabe, S. (2024). Numerical Investigation of Cavitating Flow Around a Hydrofoil Considering Advection–Diffusion and Precipitation of Dissolved Gas in Liquid. In A. Suryan, M. Yaga, H. S. Ko, & Z. Guang (Eds.), Proceedings of the 9th Asian Joint Workshop on Thermophysics and Fluid Science, 2022 - Asian Research in Thermal and Fluid Sciences (pp. 73-81). (Springer Proceedings in Physics; Vol. 396). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-981-99-9470-0_9

Numerical Investigation of Cavitating Flow Around a Hydrofoil Considering Advection–Diffusion and Precipitation of Dissolved Gas in Liquid. / Higa, Yoshihito; Iida, Ryo; Tsuda, Shin Ichi その他.
Proceedings of the 9th Asian Joint Workshop on Thermophysics and Fluid Science, 2022 - Asian Research in Thermal and Fluid Sciences. ed. / Abhilash Suryan; Minoru Yaga; Han Seo Ko; Zhang Guang. Springer Science and Business Media Deutschland GmbH, 2024. p. 73-81 (Springer Proceedings in Physics; Vol. 396).

研究成果: 書籍/レポートタイプへの寄稿 › 会議への寄与

Higa, Y, Iida, R, Tsuda, SI & Watanabe, S 2024, Numerical Investigation of Cavitating Flow Around a Hydrofoil Considering Advection–Diffusion and Precipitation of Dissolved Gas in Liquid. in A Suryan, M Yaga, HS Ko & Z Guang (eds), Proceedings of the 9th Asian Joint Workshop on Thermophysics and Fluid Science, 2022 - Asian Research in Thermal and Fluid Sciences. Springer Proceedings in Physics, vol. 396, Springer Science and Business Media Deutschland GmbH, pp. 73-81, 9th Asian Joint Workshop on Thermophysics and Fluid Science, AJWTF 2022, Utsunomiya, 日本, 11/27/22. https://doi.org/10.1007/978-981-99-9470-0_9

Higa Y, Iida R, Tsuda SI , Watanabe S. Numerical Investigation of Cavitating Flow Around a Hydrofoil Considering Advection–Diffusion and Precipitation of Dissolved Gas in Liquid. In Suryan A, Yaga M, Ko HS, Guang Z, editors, Proceedings of the 9th Asian Joint Workshop on Thermophysics and Fluid Science, 2022 - Asian Research in Thermal and Fluid Sciences. Springer Science and Business Media Deutschland GmbH. 2024. p. 73-81. (Springer Proceedings in Physics). doi: 10.1007/978-981-99-9470-0_9

Higa, Yoshihito ; Iida, Ryo ; Tsuda, Shin Ichi その他. / Numerical Investigation of Cavitating Flow Around a Hydrofoil Considering Advection–Diffusion and Precipitation of Dissolved Gas in Liquid. Proceedings of the 9th Asian Joint Workshop on Thermophysics and Fluid Science, 2022 - Asian Research in Thermal and Fluid Sciences. editor / Abhilash Suryan ; Minoru Yaga ; Han Seo Ko ; Zhang Guang. Springer Science and Business Media Deutschland GmbH, 2024. pp. 73-81 (Springer Proceedings in Physics).

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abstract = "Hydraulic cavitation is mainly affected by the pressure or velocity field, but the detailed flow structure also depends on other factors such as surface wall roughness or working fluid quality. Among those, the present study has focused on the influence of air content as a non-condensable gas in water, which is one of the factors in water quality. The novel point in this study is that we have applied a simple but physics-based model taking account of the mass transfer of the non-condensable gas based on mass conservation law in the CFD simulations. On the basis of the assumption of a homogeneous bubbly flow, the simulations were conducted by solving five governing equations for cavitation around a hydrofoil of Clark Y-11.7% (angle of attack is 8°) modifying interPhaseChageFoam of OpenFOAM v1706. As a result, the lift coefficient containing air showed higher values than the case without the gas in a certain developed cavitation state showing a periodic change of the hydrofoil lift force, and it may improve the current prediction accuracy of the lift in many CFD simulations. In the case with much air content, an attached cavity around the leading edge due to the influence of the precipitation of air was confirmed even at the time of the minimum lift force, different from the case with little content of air.",

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