Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
6.2
3.0
Journals
Energies
Special Issues
Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing
energies-logo
Submit to Energies Review for Energies Propose a Special Issue

Journal Menu

Journal Menu

Journal Browser

Journal Browser
share announcement

Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing

A special issue of Energies (ISSN 1996-1073). This special issue belongs to the section "A3: Wind, Wave and Tidal Energy".

Deadline for manuscript submissions: closed (30 June 2022) | Viewed by 21855
Please submit your paper and select the Journal "Energies" and the Special Issue "Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing" via: https://susy.mdpi.com/user/manuscripts/upload?journal=energies. Please contact the journal editor Adele Min ([email protected]) before submitting.

Special Issue Editor

Dr. Yi-Hsiang Yu

E-Mail Website
Guest Editor
Department of Civil Engineering, National Yang Ming Chiao Tung University, Hsinchu 30010, Taiwan
Interests: wave energy; high-performance computing; wave resources characterization; numerical wave tank; fluid structure interaction; design optimization; grid integration
Special Issues, Collections and Topics in MDPI journals

Special Issue Information

Dear Colleagues,

The simulation of wave energy converter systems and arrays is a complex multiphysics modeling challenge, and tools must be capable of capturing the interactions between wave energy converter systems, the complex ocean environment, and the electric grid. Specifically, tools must model the coupled interactions between relevant fluid, structural, control, and electrical system dynamics. Further, models must resolve both dynamics of relevant device subsystems, including mooring and power take-off systems. The availability of high-performance computing resources and the capability of modeling tools has significantly increased in recent years. This has, for the first time, made simulations of wave energy converters that resolve all relevant physical phenomena possible and enabled the R&D community to study the wave energy resource, along with the design, performance, and optimization of wave energy converters at a level of detail not previously possible.

We would like to invite papers dealing with the application of high-performance computing for wave energy converter modeling. Specific topics include but are not limited to:

  • Development and implementation of numerical wave tanks, including high-fidelity computational fluid dynamics (CFD) simulations and fully nonlinear time-domain potential flow methods;
  • Wave resource characterization studies;
  • Device array interaction and layout optimization;
  • Fluid structure interaction, such as coupling between CFD for the fluid domain and finite element analysis (FEA) for the structure domain, particularly for advanced and flexible material applications;
  • System design and innovation, including co-design, system optimization methods, and the application of machine learning;
  • Grid integration analysis, including system cost modeling for utility-scale markets, microgrids and coastal resiliency applications.

Dr. Yi-Hsiang Yu
Guest Editor

Manuscript Submission Information

Manuscripts should be submitted online at www.mdpi.com by registering and logging in to this website. Once you are registered, click here to go to the submission form. Manuscripts can be submitted until the deadline. All submissions that pass pre-check are peer-reviewed. Accepted papers will be published continuously in the journal (as soon as accepted) and will be listed together on the special issue website. Research articles, review articles as well as short communications are invited. For planned papers, a title and short abstract (about 100 words) can be sent to the Editorial Office for announcement on this website.

Submitted manuscripts should not have been published previously, nor be under consideration for publication elsewhere (except conference proceedings papers). All manuscripts are thoroughly refereed through a single-blind peer-review process. A guide for authors and other relevant information for submission of manuscripts is available on the Instructions for Authors page. Energies is an international peer-reviewed open access semimonthly journal published by MDPI.

Please visit the Instructions for Authors page before submitting a manuscript. The Article Processing Charge (APC) for publication in this open access journal is 2600 CHF (Swiss Francs). Submitted papers should be well formatted and use good English. Authors may use MDPI's English editing service prior to publication or during author revisions.

Keywords

  • wave energy
  • wave resources characterization
  • numerical wave tank
  • fluid structure interaction
  • design optimization
  • grid integration

Benefits of Publishing in a Special Issue

  • Ease of navigation: Grouping papers by topic helps scholars navigate broad scope journals more efficiently.
  • Greater discoverability: Special Issues support the reach and impact of scientific research. Articles in Special Issues are more discoverable and cited more frequently.
  • Expansion of research network: Special Issues facilitate connections among authors, fostering scientific collaborations.
  • External promotion: Articles in Special Issues are often promoted through the journal's social media, increasing their visibility.
  • e-Book format: Special Issues with more than 10 articles can be published as dedicated e-books, ensuring wide and rapid dissemination.

Further information on MDPI's Special Issue polices can be found here.

Published Papers (6 papers)

Download All Papers
Order results
Result details
Show export options expand_more Show export options expand_less
Select all
Export citation of selected articles as:

Research

18 pages, 2692 KiB  
Article
Comparison and Validation of Hydrodynamic Theories for Wave Energy Converter Modelling
by Matthew Leary, Curtis Rusch, Zhe Zhang and Bryson Robertson
Energies 2021, 14(13), 3959; https://doi.org/10.3390/en14133959 - 1 Jul 2021
Cited by 5 | Viewed by 2537
Abstract
Dynamic Wave Energy Converter (WEC) models utilize a wide variety of fundamental hydrodynamic theories. When incorporating novel hydrodynamic theories into numerical models, there are distinct impacts on WEC rigid body motions, cable dynamics, and final power production. This paper focuses on developing an [...] Read more.
Dynamic Wave Energy Converter (WEC) models utilize a wide variety of fundamental hydrodynamic theories. When incorporating novel hydrodynamic theories into numerical models, there are distinct impacts on WEC rigid body motions, cable dynamics, and final power production. This paper focuses on developing an understanding of the influence several refined hydrodynamic theories have on WEC dynamics, including weakly nonlinear Froude-Krylov and hydrostatic forces, body-to-body interactions, and dynamic cable modelling. All theories have evolved from simpler approaches and are of importance to a wide array of WEC archetypes. This study quantifies the impact these theories have on modelling accuracy through a WEC case study. Theoretical differences are first explored in a regular sea state. Subsequently, numerical validation efforts are performed against field data following wave reconstruction techniques. Comparisons of significance are WEC motion and cable tension. It is shown that weakly nonlinear Froude-Krylov and hydrostatic force calculations and dynamic cable modelling both significantly improve simulated WEC dynamics. However, body-to-body interactions are not found to impact simulated WEC dynamics. Full article
(This article belongs to the Special Issue Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing)
Show Figures

Figure 1

35 pages, 6985 KiB  
Article
Ocean Energy Systems Wave Energy Modeling Task 10.4: Numerical Modeling of a Fixed Oscillating Water Column
by Harry B. Bingham, Yi-Hsiang Yu, Kim Nielsen, Thanh Toan Tran, Kyong-Hwan Kim, Sewan Park, Keyyong Hong, Hafiz Ahsan Said, Thomas Kelly, John V. Ringwood, Robert W. Read, Edward Ransley, Scott Brown and Deborah Greaves
Energies 2021, 14(6), 1718; https://doi.org/10.3390/en14061718 - 19 Mar 2021
Cited by 16 | Viewed by 3759
Abstract
This paper reports on an ongoing international effort to establish guidelines for numerical modeling of wave energy converters, initiated by the International Energy Agency Technology Collaboration Program for Ocean Energy Systems. Initial results for point absorbers were presented in previous work, and here [...] Read more.
This paper reports on an ongoing international effort to establish guidelines for numerical modeling of wave energy converters, initiated by the International Energy Agency Technology Collaboration Program for Ocean Energy Systems. Initial results for point absorbers were presented in previous work, and here we present results for a breakwater-mounted Oscillating Water Column (OWC) device. The experimental model is at scale 1:4 relative to a full-scale installation in a water depth of 12.8 m. The power-extracting air turbine is modeled by an orifice plate of 1–2% of the internal chamber surface area. Measurements of chamber surface elevation, air flow through the orifice, and pressure difference across the orifice are compared with numerical calculations using both weakly-nonlinear potential flow theory and computational fluid dynamics. Both compressible- and incompressible-flow models are considered, and the effects of air compressibility are found to have a significant influence on the motion of the internal chamber surface. Recommendations are made for reducing uncertainties in future experimental campaigns, which are critical to enable firm conclusions to be drawn about the relative accuracy of the numerical models. It is well-known that boundary element method solutions of the linear potential flow problem (e.g., WAMIT) are singular at infinite frequency when panels are placed directly on the free surface. This is problematic for time-domain solutions where the value of the added mass matrix at infinite frequency is critical, especially for OWC chambers, which are modeled by zero-mass elements on the free surface. A straightforward rational procedure is described to replace ad-hoc solutions to this problem that have been proposed in the literature. Full article
(This article belongs to the Special Issue Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing)
Show Figures

Figure 1

20 pages, 8216 KiB  
Article
Modelling a Heaving Point-Absorber with a Closed-Loop Control System Using the DualSPHysics Code
by Pablo Ropero-Giralda, Alejandro J. C. Crespo, Ryan G. Coe, Bonaventura Tagliafierro, José M. Domínguez, Giorgio Bacelli and Moncho Gómez-Gesteira
Energies 2021, 14(3), 760; https://doi.org/10.3390/en14030760 - 1 Feb 2021
Cited by 29 | Viewed by 4481
Abstract
The present work addresses the need for an efficient, versatile, accurate and open-source numerical tool to be used during the design stage of wave energy converters (WECs). The device considered here is the heaving point-absorber developed and tested by Sandia National Laboratories. The [...] Read more.
The present work addresses the need for an efficient, versatile, accurate and open-source numerical tool to be used during the design stage of wave energy converters (WECs). The device considered here is the heaving point-absorber developed and tested by Sandia National Laboratories. The smoothed particle hydrodynamics (SPH) method, as implemented in DualSPHysics, is proposed since its meshless approach presents some important advantages when simulating floating devices. The dynamics of the power take-off system are also modelled by coupling DualSPHysics with the multi-physics library Project Chrono. A satisfactory matching between experimental and numerical results is obtained for: (i) the heave response of the device when forced via its actuator; (ii) the vertical forces acting on the fixed device under regular waves and; (iii) the heave response of the WEC under the action of both regular waves and the actuator force. This proves the ability of the numerical approach proposed to simulate accurately the fluid–structure interaction along with the WEC’s closed-loop control system. In addition, radiation models built from the experimental and WAMIT results are compared with DualSPHysics by plotting the intrinsic impedance in the frequency domain, showing that the SPH method can be also employed for system identification. Full article
(This article belongs to the Special Issue Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing)
Show Figures

Figure 1

36 pages, 31714 KiB  
Article
Highly Accurate Experimental Heave Decay Tests with a Floating Sphere: A Public Benchmark Dataset for Model Validation of Fluid–Structure Interaction
by Morten Bech Kramer, Jacob Andersen, Sarah Thomas, Flemming Buus Bendixen, Harry Bingham, Robert Read, Nikolaj Holk, Edward Ransley, Scott Brown, Yi-Hsiang Yu, Thanh Toan Tran, Josh Davidson, Csaba Horvath, Carl-Erik Janson, Kim Nielsen and Claes Eskilsson
Energies 2021, 14(2), 269; https://doi.org/10.3390/en14020269 - 6 Jan 2021
Cited by 18 | Viewed by 4995
Abstract
Highly accurate and precise heave decay tests on a sphere with a diameter of 300 mm were completed in a meticulously designed test setup in the wave basin in the Ocean and Coastal Engineering Laboratory at Aalborg University, Denmark. The tests were dedicated [...] Read more.
Highly accurate and precise heave decay tests on a sphere with a diameter of 300 mm were completed in a meticulously designed test setup in the wave basin in the Ocean and Coastal Engineering Laboratory at Aalborg University, Denmark. The tests were dedicated to providing a rigorous benchmark dataset for numerical model validation. The sphere was ballasted to half submergence, thereby floating with the waterline at the equator when at rest in calm water. Heave decay tests were conducted, wherein the sphere was held stationary and dropped from three drop heights: a small drop height, which can be considered a linear case, a moderately nonlinear case, and a highly nonlinear case with a drop height from a position where the whole sphere was initially above the water. The precision of the heave decay time series was calculated from random and systematic standard uncertainties. At a 95% confidence level, uncertainties were found to be very low—on average only about 0.3% of the respective drop heights. Physical parameters of the test setup and associated uncertainties were quantified. A test case was formulated that closely represents the physical tests, enabling the reader to do his/her own numerical tests. The paper includes a comparison of the physical test results to the results from several independent numerical models based on linear potential flow, fully nonlinear potential flow, and the Reynolds-averaged Navier–Stokes (RANS) equations. A high correlation between physical and numerical test results is shown. The physical test results are very suitable for numerical model validation and are public as a benchmark dataset. Full article
(This article belongs to the Special Issue Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing)
Show Figures

Graphical abstract

18 pages, 2187 KiB  
Communication
Investigation of Turbulence Modeling for Point-Absorber-Type Wave Energy Converters
by Christian Windt, Josh Davidson and John V. Ringwood
Energies 2021, 14(1), 26; https://doi.org/10.3390/en14010026 - 23 Dec 2020
Cited by 6 | Viewed by 2557
Abstract
Reviewing the literature of CFD-based numerical wave tanks for wave energy applications, it can be observed that different flow conditions and different turbulence models are applied during numerical wave energy converter (WEC) experiments. No single turbulence model can be identified as an `industry [...] Read more.
Reviewing the literature of CFD-based numerical wave tanks for wave energy applications, it can be observed that different flow conditions and different turbulence models are applied during numerical wave energy converter (WEC) experiments. No single turbulence model can be identified as an `industry standard’ for WEC modeling. The complexity of the flow field around a WEC, together with the strong dependency of turbulence effects on the shape, operational conditions, and external forces, hampers the formulation of such an `industry standard’. Furthermore, the conceptually different flow characteristics (i.e., oscillating, free surface flows), compared to the design cases of most turbulence models (i.e., continuous single-phase flow), can be identified as a source for the potential lack of accuracy of turbulence models for WEC applications. This communication performs a first step towards analyzing the accuracy and necessity of modeling turbulence effects, by means of turbulence models, within CFD-based NWTs for WEC applications. To that end, the influence of turbulence models and, in addition, the influence of the initial turbulence intensity is investigated based on different wave–structure interaction cases considering two separately validated WEC models. The results highlight the complexity of such a `turbulence analysis’ and the study suggests specific future work to get a better understanding of the model requirements for the flow field around WECs. Full article
(This article belongs to the Special Issue Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing)
Show Figures

Figure 1

21 pages, 3170 KiB  
Article
Hydrodynamic Performance of a Hybrid System Combining a Fixed Breakwater and a Wave Energy Converter: An Experimental Study
by Wei Peng, Yingnan Zhang, Xueer Yang, Jisheng Zhang, Rui He, Yanjun Liu and Renwen Chen
Energies 2020, 13(21), 5740; https://doi.org/10.3390/en13215740 - 2 Nov 2020
Cited by 6 | Viewed by 2242
Abstract
In this paper, a hybrid system integrating a fixed breakwater and an oscillating buoy type wave energy converter (WEC) is introduced. The energy converter is designed to extract the wave power by making use of the wave-induced heave motions of the three floating [...] Read more.
In this paper, a hybrid system integrating a fixed breakwater and an oscillating buoy type wave energy converter (WEC) is introduced. The energy converter is designed to extract the wave power by making use of the wave-induced heave motions of the three floating pontoons in front of the fixed breakwater. A preliminary experimental study is carried out to discuss the hydrodynamic performance of the hybrid system under the action of regular waves. A scale model was built in the laboratory at Hohai University, and the dissipative force from racks and gearboxes and the Ampere force from dynamos were employed as the power take-off (PTO) damping source. During the experiments, variations in numbers of key parameters, including the wave elevation, free response or damped motion of the floating pontoons, and the voltage output of the dynamos were simultaneously measured. Results indicate that the wave overtopping and breaking occurring on the upper surfaces of floating pontoons have a significant influence on the hydrodynamic performance of the system. For moderate and longer waves, the developed system proves to be effective in attenuating the incident energy, with less than 30% of the energy reflected back to the paddle. More importantly, the hydrodynamic efficiency of energy conversion for the present device can achieve approximately 19.6% at the lowest wave steepness in the model tests, implying that although the WEC model harnesses more energy in more energetic seas, the device may be more efficient for wave power extraction in a less energetic sea-state. Full article
(This article belongs to the Special Issue Wave Energy System Hydrodynamics Modeling and Application of High-Performance Computing)
Show Figures

Figure 1

Show export options expand_more Show export options expand_less
Select all
Export citation of selected articles as:
 
Displaying articles 1-6
Back to TopTop