Optimization of heterogeneous arrays of wave energy converters

Optimizing the layout of devices in an array of wave energy converters (WECs) is one of the core aspects of WEC array design. More often than not, WEC arrays are designed to contain identical devices. However, to further improve power generation, this paper investigates how devices of varying dimens...

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Published inOcean engineering Vol. 272; p. 113818
Main Authors Abdulkadir, Habeebullah, Abdelkhalik, Ossama
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 15.03.2023
Subjects
Heterogeneous array
Homogeneous array
Layout optimization
Optimal control
Semi-analytic hydrodynamics
Size optimization
Wave energy converter
Heterogeneous array
Layout optimization
Optimal control
Wave energy converter
Homogeneous array
Size optimization
Semi-analytic hydrodynamics
Online AccessGet full text
ISSN0029-8018
DOI10.1016/j.oceaneng.2023.113818

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Abstract Optimizing the layout of devices in an array of wave energy converters (WECs) is one of the core aspects of WEC array design. More often than not, WEC arrays are designed to contain identical devices. However, to further improve power generation, this paper investigates how devices of varying dimensions can affect the overall performance of the array; the array containing devices of different sizes is referred to as a heterogeneous array in this work. The heterogeneity is achieved by varying the radius and draught of cylindrical buoys. We measured the performance of the heterogeneous array against the homogeneous array containing the same number of devices in an identical layout, assuming the summation of volumes of all devices is the same for both the heterogeneous and the homogeneous arrays. The power from the array is computed using a time-domain array dynamic model and an optimal constrained control. The hydrodynamic coefficients used as input in the dynamic model are computed using a semi-analytical method to enable computationally efficient optimization. The optimization was performed using a genetic algorithm. Arrays of 3, 5, and 7 devices are presented in this paper. For the tested wave conditions, it was found that in some wave conditions a heterogeneous array can achieve a performance improvement of up to 40% over the corresponding homogeneous array. •This paper investigates how heterogeneity can lead to improved overall performance.•Heterogeneity is achieved by varying the dimensions of individual cylindrical buoys.•Performance of heterogeneous arrays are compared with equivalent homogeneous arrays.•Hydrodynamic coefficients are computed using a semi-analytical method.•Heterogenous arrays achieved significant improvement with less volume of materials.
AbstractList Optimizing the layout of devices in an array of wave energy converters (WECs) is one of the core aspects of WEC array design. More often than not, WEC arrays are designed to contain identical devices. However, to further improve power generation, this paper investigates how devices of varying dimensions can affect the overall performance of the array; the array containing devices of different sizes is referred to as a heterogeneous array in this work. The heterogeneity is achieved by varying the radius and draught of cylindrical buoys. We measured the performance of the heterogeneous array against the homogeneous array containing the same number of devices in an identical layout, assuming the summation of volumes of all devices is the same for both the heterogeneous and the homogeneous arrays. The power from the array is computed using a time-domain array dynamic model and an optimal constrained control. The hydrodynamic coefficients used as input in the dynamic model are computed using a semi-analytical method to enable computationally efficient optimization. The optimization was performed using a genetic algorithm. Arrays of 3, 5, and 7 devices are presented in this paper. For the tested wave conditions, it was found that in some wave conditions a heterogeneous array can achieve a performance improvement of up to 40% over the corresponding homogeneous array. •This paper investigates how heterogeneity can lead to improved overall performance.•Heterogeneity is achieved by varying the dimensions of individual cylindrical buoys.•Performance of heterogeneous arrays are compared with equivalent homogeneous arrays.•Hydrodynamic coefficients are computed using a semi-analytical method.•Heterogenous arrays achieved significant improvement with less volume of materials.
ArticleNumber 113818
Author Abdulkadir, Habeebullah
Abdelkhalik, Ossama
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Keywords Heterogeneous array
Layout optimization
Optimal control
Wave energy converter
Homogeneous array
Size optimization
Semi-analytic hydrodynamics
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Snippet Optimizing the layout of devices in an array of wave energy converters (WECs) is one of the core aspects of WEC array design. More often than not, WEC arrays...
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StartPage 113818
SubjectTerms Heterogeneous array
Homogeneous array
Layout optimization
Optimal control
Semi-analytic hydrodynamics
Size optimization
Wave energy converter
Title Optimization of heterogeneous arrays of wave energy converters
URI https://dx.doi.org/10.1016/j.oceaneng.2023.113818
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