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Gradient-augmented level set two-phase flow method with pretreated reinitialization for three-dimensional violent sloshing

Gradient-augmented level set two-phase flow method with pretreated reinitialization for three-dimensional violent sloshing
Gradient-augmented level set two-phase flow method with pretreated reinitialization for three-dimensional violent sloshing
A three-dimensional (3D) gradient-augmented level set (GALS) two-phase flow model with a pretreated reinitialization procedure is developed to simulate violent sloshing in a cuboid tank. Based on a two-dimensional (2D) GALS method, 3D Hermite, and 3D Lagrange polynomial schemes are derived to interpolate the level set function and the velocity field at arbitrary positions over a cell, respectively. A reinitialization procedure is performed on a 3D narrow band to treat the strongly distorted interface and improve computational efficiency. In addition, an identification-correction technique is proposed and incorporated into the reinitialization procedure to treat the tiny droplet which can distort the free surface shape, even lead to computation failure. To validate the accuracy of the present GALS method and the effectiveness of the proposed identification correction technique, a 3D velocity advection case is first simulated. The present method is validated to have better mass conservation property than the classical level set and original GALS methods. Also, distorted and thin interfaces are well captured on all grid resolutions by the present GALS method. Then, sloshing under coupled surge and sway excitation, sloshing under rotational excitation are simulated. Good agreements are obtained when the present wave and pressure results are compared with the experimental and numerical results. In addition, the highly nonlinear free surface is observed, and the relationship between the excitation frequency and the impulsive pressure is investigated.
gradient-augmented level set, identification-correction, Cartesian grid, mass conservation, violent sloshing
0098-2202
Xin, Jianjian
a99a1d46-ad71-4efc-a190-c93e7fee0a38
Shi, Fulong
938aceea-880e-499f-8486-3c39892952c1
Jin, Qiu
27d56f4b-3b1f-4bd9-aab7-ebd3331912d1
Ma, Lin
a9766ffe-2172-4953-8db6-2c67ab3fdd14
Xin, Jianjian
a99a1d46-ad71-4efc-a190-c93e7fee0a38
Shi, Fulong
938aceea-880e-499f-8486-3c39892952c1
Jin, Qiu
27d56f4b-3b1f-4bd9-aab7-ebd3331912d1
Ma, Lin
a9766ffe-2172-4953-8db6-2c67ab3fdd14

Xin, Jianjian, Shi, Fulong, Jin, Qiu and Ma, Lin (2020) Gradient-augmented level set two-phase flow method with pretreated reinitialization for three-dimensional violent sloshing. Journal of Fluids Engineering, 142 (1), [1]. (doi:10.1115/1.4044823).

Record type: Article

Abstract

A three-dimensional (3D) gradient-augmented level set (GALS) two-phase flow model with a pretreated reinitialization procedure is developed to simulate violent sloshing in a cuboid tank. Based on a two-dimensional (2D) GALS method, 3D Hermite, and 3D Lagrange polynomial schemes are derived to interpolate the level set function and the velocity field at arbitrary positions over a cell, respectively. A reinitialization procedure is performed on a 3D narrow band to treat the strongly distorted interface and improve computational efficiency. In addition, an identification-correction technique is proposed and incorporated into the reinitialization procedure to treat the tiny droplet which can distort the free surface shape, even lead to computation failure. To validate the accuracy of the present GALS method and the effectiveness of the proposed identification correction technique, a 3D velocity advection case is first simulated. The present method is validated to have better mass conservation property than the classical level set and original GALS methods. Also, distorted and thin interfaces are well captured on all grid resolutions by the present GALS method. Then, sloshing under coupled surge and sway excitation, sloshing under rotational excitation are simulated. Good agreements are obtained when the present wave and pressure results are compared with the experimental and numerical results. In addition, the highly nonlinear free surface is observed, and the relationship between the excitation frequency and the impulsive pressure is investigated.

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Gradient-Augmented Level Set Two-Phase Flow Method With Pretreated Reinitialization for Three-Dimensional Violent Sloshing - Version of Record
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e-pub ahead of print date: 4 October 2019
Published date: 1 January 2020
Keywords: gradient-augmented level set, identification-correction, Cartesian grid, mass conservation, violent sloshing

Identifiers

Local EPrints ID: 438286
URI: http://eprints.soton.ac.uk/id/eprint/438286
ISSN: 0098-2202
PURE UUID: d7b0d328-521a-4579-bc91-2927b1a72f39

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Date deposited: 04 Mar 2020 17:33
Last modified: 16 Mar 2024 06:46

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Contributors

Author: Jianjian Xin
Author: Fulong Shi
Author: Qiu Jin
Author: Lin Ma

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