A fast approach coupling Boundary Element Method and plane wave approximation for wave interaction analysis in sparse arrays of wave energy converters

Hydrodynamic Interactions in Multiple Body Array: A Simple and Fast Approach Coupling Boundary Element Method and Plane Wave Approximation

Volume 5: Ocean Engineering ◽

10.1115/omae2013-10541 ◽

2013 ◽

Author(s):

Jitendra Singh ◽

Aurélien Babarit

Keyword(s):

Boundary Element Method ◽

Plane Wave ◽

Boundary Element ◽

Hydrodynamic Interaction ◽

Computational Time ◽

Linear Potential ◽

Wave Approximation ◽

Interaction Problem ◽

Plane Wave Approximation ◽

Element Method

The hydrodynamic forces acting on an isolated body could be considerably different than those when it is considered in an array of multiple bodies, due to wave interactions among them. In this context, we present in this paper a numerical approach based on the linear potential flow theory to solve full hydrodynamic interaction problem in a multiple body array. In contrast to the previous approaches that considered all bodies in an array as a single unit, the present approach relies on solving for an isolated body. The interactions among the bodies are then taken into account via plane wave approximation in an iterative manner. The boundary value problem corresponding to a isolated body is solved by the Boundary Element Method (BEM). The approach is useful when the bodies are sufficiently distant from each other, at-least greater than five times the characteristic dimensions of the body. This is a valid assumption for wave energy converter devices array of point absorber type, which is our target application at a later stage. The main advantage of the proposed approach is that the computational time requirement is significantly less than the commonly used direct BEM. The time savings can be realized for even small arrays consisting of four bodies. Another advantage is that the computer memory requirements are also significantly smaller compared to the direct BEM, allowing us to consider large arrays. The numerical results for hydrodynamic interaction problem in two arrays consisting of 25 cylinders and same number of rectangular flaps are presented to validate the proposed approach.

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Three-dimensional Analysis of Sloshing Problems Using a Boundary Element Method. 2nd Report, Fluid-Structure-Interaction Analysis Method.

TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series B ◽

10.1299/kikaib.57.2791 ◽

1991 ◽

Vol 57 (540) ◽

pp. 2791-2797

Author(s):

Ken AMANO ◽

Masanori YAMAKAWA

Keyword(s):

Boundary Element Method ◽

Boundary Element ◽

Dimensional Analysis ◽

Interaction Analysis ◽

Fluid Structure Interaction ◽

Three Dimensional ◽

Analysis Method ◽

Fluid Structure ◽

Structure Interaction ◽

Element Method

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Performance assessments of the fully submerged sphere and cylinder point absorber wave energy converters

Modern Physics Letters B ◽

10.1142/s0217984919501689 ◽

2019 ◽

Vol 33 (13) ◽

pp. 1950168 ◽

Cited By ~ 2

Author(s):

Qianlong Xu ◽

Ye Li ◽

Yingkai Xia ◽

Weixing Chen ◽

Feng Gao

Keyword(s):

Wave Height ◽

Wave Energy ◽

Interaction Analysis ◽

Wave Power ◽

Viscous Damping ◽

Power Performance ◽

Point Absorber ◽

Wave Energy Converters ◽

Submerged Sphere ◽

Energy Converters

Fully submerged sphere and cylinder point absorber (PA), wave energy converters (WECs) are analyzed numerically based on linearized potential flow theory. A boundary element method (BEM) (a radiation–diffraction panel program for wave-body interactions) is used for the basic wave-structure interaction analysis. In the present numerical model, the viscous damping is modeled by an equivalent linearized damping which extracts the same amount of wave energy over one cycle as the conventional quadratic damping term. The wave power capture width in each case is predicted. Comparisons are also made between the sphere and cylinder PAs which have identical geometrical scales and submerged depths. The results show that: (i) viscous damping has a greater influence on wave power performance of the cylinder PA than that of the sphere PA; (ii) the increasing wave height reduces wave power performance of PAs; (iii) the cylinder PA has a better wave power performance compared to the sphere PA in larger wave height scenarios, which indicates that fully submerged cylinder PA is a preferable prototype of WEC.

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Post-processing of the plane-wave approximation of Schrödinger equations. Part II: Kohn–Sham models

IMA Journal of Numerical Analysis ◽

10.1093/imanum/draa052 ◽

2020 ◽

Author(s):

Geneviève Dusson

Keyword(s):

Plane Wave ◽

Ground State ◽

A Priori ◽

Processing Method ◽

Linear Operators ◽

Schrodinger Equations ◽

Schrödinger Equations ◽

Post Processing ◽

Wave Approximation ◽

Plane Wave Approximation

Abstract In this article, we provide a priori estimates for a perturbation-based post-processing method of the plane-wave approximation of nonlinear Kohn–Sham local density approximation (LDA) models with pseudopotentials, relying on Cancès et al. (2020, Post-processing of the plane-wave approximation of Schrödinger equations. Part I: linear operators. IMA Journal of Numerical Analysis, draa044) for the proofs of such estimates in the case of linear Schrödinger equations. As in Cancès et al. (2016, A perturbation-method-based post-processing for the plane-wave discretization of Kohn–Sham models. J. Comput. Phys., 307, 446–459), where these a priori results were announced and tested numerically, we use a periodic setting and the problem is discretized with plane waves (Fourier series). This post-processing method consists of performing a full computation in a coarse plane-wave basis and then to compute corrections based on the first-order perturbation theory in a fine basis, which numerically only requires the computation of the residuals of the ground-state orbitals in the fine basis. We show that this procedure asymptotically improves the accuracy of two quantities of interest: the ground-state density matrix, i.e. the orthogonal projector on the lowest $N$ eigenvectors, and the ground-state energy.

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