Computational Modeling of a Regular Wave Tank

Gomes, Mateus das Neves; Olinto, Cláudio Rodrigues; Rocha, Luíz Alberto Oliveira; Souza, Jeferson Ávila; Isoldi, Liércio André

doi:10.5380/reterm.v8i1.61881

Cited by 20 publications

(26 citation statements)

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“…The computational modeling presented was already verified and validated in Gomes et al (2009) and Seibt et al (2013), respectively, showing its effectiveness and accuracy for generating regular waves. Thus, for the sake of brevity, these procedures will not be reproduced here.…”

Section: Computational Modelingmentioning

confidence: 70%

“…the turbine motion is independent of the fluid direction (Twidell and Weir, 2006). Several publications employing numerical techniques have been used to study the fluid dynamic behavior of the OWC device (Horko, 2007;Conde and Gato, 2008;Liu et al, 2008;Gomes et al, 2009;Grimmler et al 2012;Dos Santos et al, 2013). However there are few publications analyzing the influence of the OWC shape in its performance: Horko (2007) presents a numeric-experimental investigation about the front lip format, comparing five geometric possibilities and concluding that a rounded lip improves the efficiency of the OWC converter; Grimmler et al (2012), adopting a 3D numerical approach and by means of the Constructal Design method, studied an OWC having a hydropneumatic chamber with an hexahedral shape, aiming to maximize the mass flow rate of air passing through the chimney, obtaining a geometry with a performance 30% superior; Gomes et al (2012) also using the Constructal Design method but employing a 2D computational model studied the influence of the ratio between the height and length of a rectangular OWC chamber in its power, showing that the optimal shape can be ten times better if compared with the worst case; Isoldi et al (2013) used a 3D numerical model to compare the influence in the OWC performance of hydro-pneumatic chambers with different cross-sectional area format (rectangle, ellipse and diamond).…”

Section: Introductionmentioning

confidence: 99%

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3d Numerical Analysis About the Shape Influence of the Hydro-Pneumatic Chamber in an Oscillating Water Column (Owc)

Isoldi

Grimmler

Letzow

et al. 2015

RETERM

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The oceans represent one of the major energy natural resources, which potentially can be used to supply the World energy demand. In the last decades some devices to convert the wave ocean energy into electrical energy have been studied. In this work the operating principle of an Oscillating Water Column (OWC) converter was analyzed with a transient 3D numerical methodology, using the Finite Volume Method (FVM) and the Volume of Fluid (VOF) model. The incident waves on the OWC hydro- pneumatic chamber cause an oscillation of the water column inside the chamber producing an alternate air flow through the chimney. The air drives a turbine that is coupled to an electric generator. The aim of this work was to investigate the shape influence of the hydro-pneumatic chamber geometry in the air flow. For this, six cases were studied in laboratory scale and the results showed that the variation of the OWC chamber shape can improve 12.4% the amount of mass air flow.

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Section: Computational Modelingmentioning

confidence: 70%

Section: Introductionmentioning

confidence: 99%

3d Numerical Analysis About the Shape Influence of the Hydro-Pneumatic Chamber in an Oscillating Water Column (Owc)

Isoldi

Grimmler

Letzow

et al. 2015

RETERM

Self Cite

View full text Add to dashboard Cite

show abstract

“…It is important to highlight that this numerical model, for the wave generation into a wave tank, was already verified and validated in Gomes et al (2009) and in Seibt et al (2014).…”

Section: T   mentioning

confidence: 83%

Computational modeling applied to the study of wave energy converters (WEC)

Seibt

Letzow

Gomes

et al. 2014

Mar. Syst. Ocean Technol.

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The employment of numerical methods to solve engineering problems is a reality, as well as, the worldwide concern about the need of renewable and alternative energy sources. Thus, this work presents a computational model capable of simulating the operating principle of some Wave Energy Converters (WEC). To do so, the device is coupled in a wave tank, where the sea waves are reproduced. The Finite Volume Method (FVM) and the Volume of Fluid (VOF) model are adopted. The results showed that the converter's operating principle can be numerically reproduced, demonstrating the potential of computational modeling to study this subject.

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“…It was introduced in 1976 at Queen's University in Belfast some research into different aerodynamic blade profiles of the Wells turbine and modifications related to the airflow velocities [7][8][9]. A series of useful studies on OWC have been carried out by some authors from the application of the theory and boundary conditions to improve the properties and performance of OWC, the numerical model the flow was assumed to be inviscid, unsteady and incompressible were modeled in a NWT two-dimensional and k-ε turbulent model, where the Volume of Fluid (VOF) model were used [10][11][12][13][14][15][16][17]. ANSYS Fluent is a commercial software which solves the continuity and momentum Navier-Stokes equations based on the finite volume method.…”

Section: Introductionmentioning

confidence: 99%

The Analysis of Fluid Dynamics of Wave Power Station With Wells Turbin by CFD

Truong¹,

Nguyen²,

Tran³

2020

JST

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Natural energy such as wind, wave and other natural vibrations is one of the high potential renewable energy sources. The Wells turbine is based on the use of bidirectional turbines, which act as axial-flow self-rectifying turbines that employs a symmetrical blade profile and rotating unidirectionally in reciprocating airflows generated by the air chamber to extract energy from vibrations. These topics have been extensively studied both numerically and experimentally such as research on the parameters of the effects of structure, angle of attack, blade shape, etc. In this paper, numerical simulation is carried out using commercially available tool Fluent for fluid dynamics analysis and focus on oscillating predictions, with particular attention to the behavior of the flow. Based on the Numerical Wave Tank (NWT) model is simulated in a two dimensional used in this model, which is constructed mainly based on the spatially averaged Navier Stokes equation with the k-ε model for simulating the turbulence and modeled with Volume of Fluid (VOF). Axial-flow turbines system and future development as well as the proposed limitations will be discussed in detail.

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Computational Modeling of a Regular Wave Tank

Cited by 20 publications

References 0 publications

3d Numerical Analysis About the Shape Influence of the Hydro-Pneumatic Chamber in an Oscillating Water Column (Owc)

3d Numerical Analysis About the Shape Influence of the Hydro-Pneumatic Chamber in an Oscillating Water Column (Owc)

Computational modeling applied to the study of wave energy converters (WEC)

The Analysis of Fluid Dynamics of Wave Power Station With Wells Turbin by CFD

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