Performance of a two-phase flow solver for the simulation of breaking waves

Wave breaking is one of the most violent phenomena observed in air-water interface interactions. This phenomenon commonly occurs in real ship flows and is one of the main sources of underwater noise and white-water wakes. The investigation of this phenomenon is thus important in ship and ocean engin...

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Main Authors: Jin, Qiu, Hudson, Dominic, Temarel, Pandeli, Price, W. Geraint
Format: Conference Object
Language:English
Published: ASME 2019
Subjects:
Arctic
Online Access:https://eprints.soton.ac.uk/432876/
https://eprints.soton.ac.uk/432876/1/OMAE2019_96326_jin.pdf
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spelling ftsouthampton:oai:eprints.soton.ac.uk:432876 2023-07-30T03:59:51+02:00 Performance of a two-phase flow solver for the simulation of breaking waves Jin, Qiu Hudson, Dominic Temarel, Pandeli Price, W. Geraint 2019-06-09 text https://eprints.soton.ac.uk/432876/ https://eprints.soton.ac.uk/432876/1/OMAE2019_96326_jin.pdf en English eng ASME https://eprints.soton.ac.uk/432876/1/OMAE2019_96326_jin.pdf Jin, Qiu, Hudson, Dominic, Temarel, Pandeli and Price, W. Geraint (2019) Performance of a two-phase flow solver for the simulation of breaking waves. In Proceedings of the ASME 2019 38th International Conference on Ocean, Offshore and Arctic Engineering: OMAE2019. ASME. Conference or Workshop Item PeerReviewed 2019 ftsouthampton 2023-07-09T22:31:02Z Wave breaking is one of the most violent phenomena observed in air-water interface interactions. This phenomenon commonly occurs in real ship flows and is one of the main sources of underwater noise and white-water wakes. The investigation of this phenomenon is thus important in ship and ocean engineering. The performance of a two-phase flow solver is investigated for a simulation of spilling breaking waves generated by a shallowly submerged hydrofoil (NACA0024) in a uniform flow. An algebraic Volume of Fluid (AVOF) method is applied to capture the dynamic behaviour of the free surface and a standard k - ε turbulence model is selected to capture the turbulent flow around and downstream of the hydrofoil. The wave profiles, pressure and velocity contours are computed to investigate the overall flow conditions and a detailed analysis of the flow field downstream of the hydrofoil is conducted in terms of velocity components and turbulence intensities at six measurement sections. A comparison of the numerical and experimental results shows that an accurate representation of the free surface and the turbulent flow beneath it is obtained with the present numerical scheme. It is expected that the systematic documentation of the performance of the AVOF two-phase solver will enable its more accurate and optimal use for simulating ship-related flows, as well as increase awareness of its potential shortcomings for those interested in general CFD simulation of breaking waves. Conference Object Arctic University of Southampton: e-Prints Soton
institution Open Polar
collection University of Southampton: e-Prints Soton
op_collection_id ftsouthampton
language English
description Wave breaking is one of the most violent phenomena observed in air-water interface interactions. This phenomenon commonly occurs in real ship flows and is one of the main sources of underwater noise and white-water wakes. The investigation of this phenomenon is thus important in ship and ocean engineering. The performance of a two-phase flow solver is investigated for a simulation of spilling breaking waves generated by a shallowly submerged hydrofoil (NACA0024) in a uniform flow. An algebraic Volume of Fluid (AVOF) method is applied to capture the dynamic behaviour of the free surface and a standard k - ε turbulence model is selected to capture the turbulent flow around and downstream of the hydrofoil. The wave profiles, pressure and velocity contours are computed to investigate the overall flow conditions and a detailed analysis of the flow field downstream of the hydrofoil is conducted in terms of velocity components and turbulence intensities at six measurement sections. A comparison of the numerical and experimental results shows that an accurate representation of the free surface and the turbulent flow beneath it is obtained with the present numerical scheme. It is expected that the systematic documentation of the performance of the AVOF two-phase solver will enable its more accurate and optimal use for simulating ship-related flows, as well as increase awareness of its potential shortcomings for those interested in general CFD simulation of breaking waves.
format Conference Object
author Jin, Qiu
Hudson, Dominic
Temarel, Pandeli
Price, W. Geraint
spellingShingle Jin, Qiu
Hudson, Dominic
Temarel, Pandeli
Price, W. Geraint
Performance of a two-phase flow solver for the simulation of breaking waves
author_facet Jin, Qiu
Hudson, Dominic
Temarel, Pandeli
Price, W. Geraint
author_sort Jin, Qiu
title Performance of a two-phase flow solver for the simulation of breaking waves
title_short Performance of a two-phase flow solver for the simulation of breaking waves
title_full Performance of a two-phase flow solver for the simulation of breaking waves
title_fullStr Performance of a two-phase flow solver for the simulation of breaking waves
title_full_unstemmed Performance of a two-phase flow solver for the simulation of breaking waves
title_sort performance of a two-phase flow solver for the simulation of breaking waves
publisher ASME
publishDate 2019
url https://eprints.soton.ac.uk/432876/
https://eprints.soton.ac.uk/432876/1/OMAE2019_96326_jin.pdf
genre Arctic
genre_facet Arctic
op_relation https://eprints.soton.ac.uk/432876/1/OMAE2019_96326_jin.pdf
Jin, Qiu, Hudson, Dominic, Temarel, Pandeli and Price, W. Geraint (2019) Performance of a two-phase flow solver for the simulation of breaking waves. In Proceedings of the ASME 2019 38th International Conference on Ocean, Offshore and Arctic Engineering: OMAE2019. ASME.
_version_ 1772810593412055040

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