Layout optimization of heaving Wave Energy Converters linear arrays in front of a vertical wall

The present paper focuses on the determination of optimum layouts for linear arrays of heaving Wave Energy Converters (WECs) in front of a vertical wall. Optimum layouts maximize the annual averaged absorbed energy at a given marine site and satisfy spatial constraints. For achieving this goal, we developed an efficient optimization numerical framework, where a genetic algorithm solver is appropriately coupled with a frequency-domain hydrodynamic model, while, furthermore, a numerical wave model is utilized to determine the local wave climate conditions at the site of interest. The context is applied for an array of five semi-immersed, oblate spheroidal heaving WECs deployed at five near-shore sites of mild wave environments in the Aegean Sea, Greece. For each site, different optimization cases are solved, facilitating the investigation of different aspects of the examined problem. The largest annual energy absorption ability is observed for optimum layouts, characterized by the placement of the array close to the wall and the formation of clusters of closely-positioned WECs near the wall edges. Compared to arrays employed at sites in south-eastern Aegean, optimally-arranged arrays at central Aegean locations showed reduced energy absorption ability due to milder local wave conditions and/or the existence of quite limited water depths. (c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This study focuses on determining the optimal linear arrangement of oscillating wave energy converters to maximize energy absorption annually and meet spatial constraints. Through an efficient optimization framework, it is possible to identify the layout of WECs that achieve the highest energy absorption at specific marine sites, with observations showing that placing the array close to the wall and forming clusters of densely-positioned WECs can lead to maximum energy absorption ability.