Abstract
Kites can be used to harvest wind energy at higher altitudes while using only a fraction of the material required for conventional wind turbines. In this work, we present the kite system of Kyushu University and demonstrate how experimental data can be used to train machine learning regression models. The system is designed for 7 kW traction power and comprises an inflatable wing with suspended kite control unit that is either tethered to a fixed ground anchor or to a towing vehicle to produce a controlled relative flow environment. A measurement unit was attached to the kite for data acquisition. To predict the generated tether force, we collected input–output samples from a set of well-designed experimental runs to act as our labeled training data in a supervised machine learning setting. We then identified a set of key input parameters which were found to be consistent with our sensitivity analysis using Pearson input–output correlation metrics. Finally, we designed and tested the accuracy of a neural network, among other multivariate regression models. The quality metrics of our models show great promise in accurately predicting the tether force for new input/feature combinations and potentially guide new designs for optimal power generation.
Highlights
In this paper we describe an Airborne Wind EnergyAirborne wind energy (AWE) research platform developed at Kyushu University, covering system set-up, ground station and kite control unit (KCU)
In a multi-layered perceptron (MLP), perceptrons are arranged in interconnected layers
We demonstrated a novel approach to employ machine learning regression methods, based on experimental measurements, for the prediction of the power generated by AWE systems
Summary
Airborne wind energy (AWE) is an emerging renewable energy technology, which utilizes flying devices for harnessing wind energy at higher altitudes than conventional wind turbines [1–5]. The fundamental working principles of the technology were already formulated in the 1980s by Miles L. Loyd [6], it was not until the turn of the century that a more systematic and networked exploration of the technology started to emerge. AWE has evolved into a rapidly growing field of activity encompassing a global community of researchers, investors and developers. The investment in this topic is motivated by the desire to find a cost-effective renewable energy technology that can Energies 2020, 13, 2367; doi:10.3390/en13092367 www.mdpi.com/journal/energies
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