Modelling the hydrodynamic effect of abrupt water depth changes on a ship travelling in restricted waters using CFD
Modelling the hydrodynamic effect of abrupt water depth changes on a ship travelling in restricted waters using CFD
Shallow water studies of ship hydrodynamics typically examine a single, constant underwater canal cross-section at a time. In practice, the underwater cross-sectional area and shape of the waterway is rarely maintained constant over long distances. This study presents an attempt to quantify the effects of an abruptly varying water depth by numerically modelling such a condition using CFD. The results show that waves propagate and refract in the numerical towing tank in a physically consistent manner showing less than 0.1% error in the dissipation of a solitary wave when compared to analytical relations. A strong boundary layer is formed on the canal bottom almost as soon as the ship enters the shallower region. The resistance increase, resulting from the depth change is up to approximately 226% of the initial value near critical speeds.
1087 - 1103
Terziev, Momchil
938f71d0-02b5-414c-8c2d-9cca8cc87397
Tezdogan, Tahsin
7e7328e2-4185-4052-8e9a-53fd81c98909
Incecik, Atilla
25a12ee2-7ba6-47cf-af5d-a79de4c6a2c4
7 September 2021
Terziev, Momchil
938f71d0-02b5-414c-8c2d-9cca8cc87397
Tezdogan, Tahsin
7e7328e2-4185-4052-8e9a-53fd81c98909
Incecik, Atilla
25a12ee2-7ba6-47cf-af5d-a79de4c6a2c4
Terziev, Momchil, Tezdogan, Tahsin and Incecik, Atilla
(2021)
Modelling the hydrodynamic effect of abrupt water depth changes on a ship travelling in restricted waters using CFD.
Ships and Offshore Structures, 16, .
(doi:10.1080/17445302.2020.1816731).
Abstract
Shallow water studies of ship hydrodynamics typically examine a single, constant underwater canal cross-section at a time. In practice, the underwater cross-sectional area and shape of the waterway is rarely maintained constant over long distances. This study presents an attempt to quantify the effects of an abruptly varying water depth by numerically modelling such a condition using CFD. The results show that waves propagate and refract in the numerical towing tank in a physically consistent manner showing less than 0.1% error in the dissipation of a solitary wave when compared to analytical relations. A strong boundary layer is formed on the canal bottom almost as soon as the ship enters the shallower region. The resistance increase, resulting from the depth change is up to approximately 226% of the initial value near critical speeds.
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Modelling the hydrodynamic effect of abrupt water depth changes on a ship travelling in restricted waters using CFD
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Accepted/In Press date: 26 August 2020
Published date: 7 September 2021
Identifiers
Local EPrints ID: 473883
URI: http://eprints.soton.ac.uk/id/eprint/473883
ISSN: 1744-5302
PURE UUID: 014231cb-5ccb-411b-a404-65024f8eaa18
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Date deposited: 02 Feb 2023 17:37
Last modified: 17 Mar 2024 04:18
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Author:
Momchil Terziev
Author:
Tahsin Tezdogan
Author:
Atilla Incecik
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