Abstract
This study uses deep learning algorithms to predict the rotational speed of the turbine generator in an oscillating water column-type wave energy converter (OWC-WEC). The effective control and operation of OWC-WECs remain a challenge due to the variation in the input wave energy and the significantly high peak-to-average power ratio. Therefore, the rated power control of OWC-WECs is essential for increasing the operating time and power output. The existing rated power control method is based on the instantaneous rotational speed of the turbine generator. However, due to physical limitations, such as the valve operating time, a more refined rated power control method is required. Therefore, we propose a method that applies a deep learning algorithm. Our method predicts the instantaneous rotational speed of the turbine generator and the rated power control is performed based on the prediction. This enables precise control through the operation of the high-speed safety valve before the energy input exceeds the rated value. The prediction performances for various algorithms, such as a multi-layer perceptron (MLP), recurrent neural network (RNN), long short-term memory (LSTM), and convolutional neural network (CNN), are compared. In addition, the prediction performance of each algorithm as a function of the input datasets is investigated using various error evaluation methods. For the training datasets, the operation data from an OWC-WEC west of Jeju in South Korea is used. The analysis demonstrates that LSTM exhibits the most accurate prediction of the instantaneous rotational speed of a turbine generator and CNN has visible advantages when the data correlation is low.
Highlights
As the global energy demand increases with an increasing population, renewable energy systems are regarded as an indispensable alternative energy source in terms of technological maturation and carbon footprint reduction [1]
We presented the results of predicting the instantaneous rotational speed of a turbine generator based on a deep learning algorithm for the rated power control of an oscillating water column-type wave energy converter (OWC-WEC)
As the conventional rated control method is based on the instantaneous rotational speed of the turbine generator in its present state, the control can only be performed after the energy input surpasses the rated value of the system
Summary
As the global energy demand increases with an increasing population, renewable energy systems are regarded as an indispensable alternative energy source in terms of technological maturation and carbon footprint reduction [1]. A number of studies have reported the introduction of power grids that incorporate renewable energy sources [2,3,4,5]. In this context, wave energy will play a key role as an energy source, as it has the potential for an annual energy generation of 29,500 TWh [6,7,8]. The air turbine driving the generator is an essential component of the power plant, where the pneumatic energy from the waves is converted into useful electrical energy. OWC prototypes have been in operation in several countries
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