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Combined force decomposition approach and CFD simulation methods for 2D water entry and exit problem

Combined force decomposition approach and CFD simulation methods for 2D water entry and exit problem
Combined force decomposition approach and CFD simulation methods for 2D water entry and exit problem
The force decomposition approach is extended to solve the two-dimensional (2D) water entry and exit problems. Two typical scenarios, direct water exit and continuous water entry and exit, are examined. It reveals that the total force is irrelevant to the body velocity but to the acceleration. More specifically, the force can be expressed as the multiplication of constant values, body acceleration and a non-dimensional coefficient, and the coefficient is related only to the displacement and immersion condition of the body while independent of its motion condition. Two typical body shapes, a widely used wedge model and a practical ship section model, are examined here. CFD simulation is employed here to directly extract the non-dimensional coefficients, which avoids complex calculations for the wetted length of body by analytical models. The force decomposition approach with the obtained coefficients provides a means to quickly and accurately predict the hydrodynamic force acting on body for water exit scenarios. The proposed method is verified by comparing its results with CFD simulations in the complicated motion cases with varying acceleration. Furthermore, this work provides a potential tool to calculate the total force acting on any entire 3D hull that is divided into several independent 2D slices
Computational fluid dynamics, Force decomposition, Water entry, Water exit
0029-8018
Sui, Xupeng
b4651a2c-d0f9-492f-b7fb-e8214a6f1168
Djidjeli, Kamal
94ac4002-4170-495b-a443-74fde3b92998
Sun, Zhe
80e5a9b0-493f-4b95-85ea-1813bb57f022
Xing, Jing Tang
d4fe7ae0-2668-422a-8d89-9e66527835ce
Sui, Xupeng
b4651a2c-d0f9-492f-b7fb-e8214a6f1168
Djidjeli, Kamal
94ac4002-4170-495b-a443-74fde3b92998
Sun, Zhe
80e5a9b0-493f-4b95-85ea-1813bb57f022
Xing, Jing Tang
d4fe7ae0-2668-422a-8d89-9e66527835ce

Sui, Xupeng, Djidjeli, Kamal, Sun, Zhe and Xing, Jing Tang (2024) Combined force decomposition approach and CFD simulation methods for 2D water entry and exit problem. Ocean Engineering, 300 (5), [117421]. (doi:10.1016/j.oceaneng.2024.117421).

Record type: Article

Abstract

The force decomposition approach is extended to solve the two-dimensional (2D) water entry and exit problems. Two typical scenarios, direct water exit and continuous water entry and exit, are examined. It reveals that the total force is irrelevant to the body velocity but to the acceleration. More specifically, the force can be expressed as the multiplication of constant values, body acceleration and a non-dimensional coefficient, and the coefficient is related only to the displacement and immersion condition of the body while independent of its motion condition. Two typical body shapes, a widely used wedge model and a practical ship section model, are examined here. CFD simulation is employed here to directly extract the non-dimensional coefficients, which avoids complex calculations for the wetted length of body by analytical models. The force decomposition approach with the obtained coefficients provides a means to quickly and accurately predict the hydrodynamic force acting on body for water exit scenarios. The proposed method is verified by comparing its results with CFD simulations in the complicated motion cases with varying acceleration. Furthermore, this work provides a potential tool to calculate the total force acting on any entire 3D hull that is divided into several independent 2D slices

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More information

Accepted/In Press date: 6 March 2024
e-pub ahead of print date: 14 March 2024
Published date: 15 May 2024
Additional Information: Publisher Copyright: © 2024 The Authors
Keywords: Computational fluid dynamics, Force decomposition, Water entry, Water exit

Identifiers

Local EPrints ID: 488212
URI: http://eprints.soton.ac.uk/id/eprint/488212
DOI: doi:10.1016/j.oceaneng.2024.117421
ISSN: 0029-8018
PURE UUID: fa2e9889-b47b-4749-810a-a4338c7dfecc

Catalogue record

Date deposited: 18 Mar 2024 17:54
Last modified: 01 May 2024 16:38

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Contributors

Author: Xupeng Sui
Author: Kamal Djidjeli
Author: Zhe Sun
Author: Jing Tang Xing

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