Abstract
A U-shaped oscillating water column (U-OWC) device has been investigated to enhance power extraction by placing the bottom-mounted vertical barrier in front of a conventional OWC. Then, the optimal design of a U-OWC device has been attempted by using an artificial neural network (ANN) model. First, the analytical model is developed by a matched eigenfunction expansion method (MEEM) based on linear potential theory. Using the developed analytical model, the input and output features for training an ANN model are identified, and then the database containing input and output features is established by a Latin hypercube sampling (LHS) method. With 200 samples, an ANN model is trained with the training data (70%) and validated with the remaining test data (30%). The predictions on output features are made for 4000 random combinations of input features for given significant wave heights and energy periods in irregular waves. From these predictions, the optimal geometric values of a U-OWC are determined by considering both the conversion efficiency and wave force on the barrier. It is found that a well-trained ANN model shows good prediction accuracy and provides the optimal geometric values of a U-OWC suitable for wave conditions at the installation site.
Highlights
The idea of extracting electricity from wave energy is attracting the attention of developers and researchers once again due to its abundance as well as its low environmental impact
A U-shaped oscillating water column (U-oscillating water column (OWC)) device is composed of an air chamber of length (a) and height (H) and a chamber wall that is submerged at d2 below the water surface
The same methodology is followed for the remaining energy periods TE 4.6s and the optimal geometric values of the U-OWC are summarized in Table 3 following the same design procedure
Summary
The idea of extracting electricity from wave energy is attracting the attention of developers and researchers once again due to its abundance as well as its low environmental impact. Malara and Arena [12] developed a hybrid numerical model applying the eigenfunction expansion method based on linear potential theory to the outer region of the U-OWC and the unsteady Bernoulli equation to the inner region. Derived the boundary integral equation based on the linear potential theory and developed a three-dimensional numerical model of the U-OWC device. The hydrodynamic performance of a 2D U-OWC is investigated in irregular waves using an analytical model. An ANN model is designed and trained to predict output features like conversion efficiency and wave forces in irregular waves.
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