Analysis of Sloshing Suppressors in Liquefied Natural Gas Carriers Tanks

This study develops an accurate numerical tool for investigating optimal retrofit configurations in order to minimize wave overtopping from a vertical seawall due to extreme climatic events and under changing climate. A weakly compressible smoothed particle hydrodynamics (WCSPH) model is developed to simulate the wave-structure interactions for coastal retrofit structures in front of a vertical seawall. A range of possible physical configurations of coastal retrofits including re-curve wall and submerged breakwater are modelled with the numerical model to understand their performance under different wave and structural conditions. The numerical model is successfully validated against laboratory data collected in 2D wave flume at Warwick Water Laboratory. The findings of numerical modelling are in good agreement with the laboratory data. The results indicate that recurve wall is more effective in mitigating wave overtopping and provides more resilience to coastal flooding in comparison to base-case (plain vertical wall) and submerged breakwater retrofit.

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Application of Smoothed Particle Hydrodynamics to Structural Cable Analysis

Applied Sciences ◽

10.3390/app10248983 ◽

2020 ◽

Vol 10 (24) ◽

pp. 8983

Author(s):

A. Ersin Dinçer ◽

Abdullah Demir

Keyword(s):

Numerical Model ◽

Smoothed Particle Hydrodynamics ◽

Solid Mechanics ◽

Numerical Studies ◽

Mesh Free ◽

Longitudinal Stiffness ◽

Damping Parameter ◽

Particle Hydrodynamics ◽

Deformable Bodies ◽

Smoothed Particle

In this study, a numerical model is proposed for the analysis of a simply supported structural cable. Smoothed particle hydrodynamics (SPH)—a mesh-free, Lagrangian method with advantages for analysis of highly deformable bodies—is utilized to model a cable. In the proposed numerical model, it is assumed that a cable has only longitudinal stiffness in tension. Accordingly, SPH equations derived for solid mechanics are adapted for a structural cable, for the first time. Besides, a proper damping parameter is introduced to capture the behavior of the cable more realistically. In order to validate the proposed numerical model, different experimental and numerical studies available in the literature are used. In addition, novel experiments are carried out. In the experiments, different harmonic motions are applied to a uniformly loaded cable. Results show that the SPH method is an appropriate method to simulate the structural cable.

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APPLICATION OF SMOOTHED PARTICLE HYDRODYNAMICS IN EVALUATING THE PERFORMANCE OF COASTAL RETROFIT STRUCTURES

Coastal Engineering Proceedings ◽

10.9753/icce.v36.waves.44 ◽

2018 ◽

Vol 1 (36) ◽

pp. 109 ◽

Cited By ~ 1

Author(s):

Soroush Abolfathi ◽

Dong Shudi ◽

Sina Borzooei ◽

Abbas Yeganeh-Bakhtiari ◽

Jonathan Pearson

Keyword(s):

Numerical Model ◽

Smoothed Particle Hydrodynamics ◽

Vertical Wall ◽

Laboratory Data ◽

Wave Structure ◽

Base Case ◽

Submerged Breakwater ◽

Wave Overtopping ◽

Particle Hydrodynamics ◽

Smoothed Particle

This study develops an accurate numerical tool for investigating optimal retrofit configurations in order to minimize wave overtopping from a vertical seawall due to extreme climatic events and under changing climate. A weakly compressible smoothed particle hydrodynamics (WCSPH) model is developed to simulate the wave-structure interactions for coastal retrofit structures in front of a vertical seawall. A range of possible physical configurations of coastal retrofits including re-curve wall and submerged breakwater are modelled with the numerical model to understand their performance under different wave and structural conditions. The numerical model is successfully validated against laboratory data collected in 2D wave flume at Warwick Water Laboratory. The findings of numerical modelling are in good agreement with the laboratory data. The results indicate that recurve wall is more effective in mitigating wave overtopping and provides more resilience to coastal flooding in comparison to base-case (plain vertical wall) and submerged breakwater retrofit.

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Numerical Simulation of Multidirectional Waves With Full-Spectrum Using DualSPHysics

Volume 9: Rodney Eatock Taylor Honoring Symposium on Marine and Offshore Hydrodynamics; Takeshi Kinoshita Honoring Symposium on Offshore Technology ◽

10.1115/omae2019-96405 ◽

2019 ◽

Author(s):

Taiga Kanehira ◽

Hidemi Mutsuda ◽

Samuel Draycott ◽

David M. Ingram ◽

Yasuaki Doi

Keyword(s):

Numerical Simulation ◽

Numerical Model ◽

Smoothed Particle Hydrodynamics ◽

Full Spectrum ◽

Tank Model ◽

Type Wave ◽

Wave Basin ◽

Particle Hydrodynamics ◽

Spreading Function ◽

Smoothed Particle

Abstract The numerical model for circular wave basin were developed using DualSPHysics based on Smoothed Particle Hydrodynamics to generate short-crested wave. The recreation of short-crested wave was achieved using Pierson Moskowitz spectrum and cosin2s spreading function with spreading value s. It is found that this numerical tank model could successfully reproduced not only long-crested but short-crested waves using 168 hinged-flap type wave makers.

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Upon Bulk Cavitation Appearing in Underwater Explosions

International conference KNOWLEDGE-BASED ORGANIZATION ◽

10.1515/kbo-2017-0159 ◽

2017 ◽

Vol 23 (3) ◽

pp. 71-78

Author(s):

Vasile Năstăsescu ◽

Ghiță Bârsan

Keyword(s):

Numerical Model ◽

Numerical Modelling ◽

Smoothed Particle Hydrodynamics ◽

Underwater Explosion ◽

Characteristic Parameters ◽

Sph Method ◽

Underwater Explosions ◽

Particle Hydrodynamics ◽

Smoothed Particle ◽

Smoothed Particle Hydrodynamics Method

Abstract This paper presents some results of the author’s researching in connection with SPH (smoothed particle hydrodynamics) method and underwater explosion numerical modelling. All about cavitation fundamentals are considered known and about cavitation effects upon the structures. The authors, deeply preoccupied in using of SPH method, as well in modelling of the underwater explosion effects upon structures, had to take into consideration the bulk cavitation. A main issue in this study was the knowing of the bulk cavitation domain and its characteristic parameters. Such researching was possible to be successfully carried out, only by using of the SPH method. Finally, the paper presents the relations and the working way for knowing of the bulk cavitation domain and also a numerical model using SPH method is presented. The numerical example regarding shape and dimensions of the bulk cavitation is presented together putting in evidence of some parameters which can make damages upon a structure that is in the bulk cavitation area.

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