Abstract
Nowadays, the energy sector is experiencing a profound transition. Among all renewable energy sources, wind energy is the most developed technology across the world. To ensure the profitability of wind turbines, it is essential to develop predictive maintenance strategies that will optimize energy production while preventing unexpected downtimes. With the huge amount of data collected every day, machine learning is seen as a key enabling approach for predictive maintenance of wind turbines. However, most of the effort is put into the optimization of the model architectures and its parameters, whereas data-related aspects are often neglected. The goal of this paper is to contribute to a better understanding of wind turbines through a data-centric machine learning methodology. In particular, we focus on the optimization of data preprocessing and feature selection steps of the machine learning pipeline. The proposed methodology is used to detect failures affecting five components on a wind farm composed of five turbines. Despite the simplicity of the used machine learning model (a decision tree), the methodology outperformed model-centric approach by improving the prediction of the remaining useful life of the wind farm, making it more reliable and contributing to the global efforts towards tackling climate change.
Highlights
This paper has proved the benefit of a data-centric Machine Learning (ML) methodology for making wind turbines more reliable, by predicting the Remaining Useful Life (RUL) more accurately and contributing to the global efforts of tackling climate change
The RUL information is used to make decisions about the maintenance scheduling of wind turbines, through several actions associated to different costs: inspection, replacement or repair
Among the perspective directions for further research, we can highlight the implementation of more sophisticated ML models enriched with the proposed data-centric methodology
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The energy sector is undergoing a profound transition to meet climate objectives while ensuring global access. The Paris Climate Agreement, adopted by 196 countries in. 2015, strives to “keep the increase in global average temperature to well below 2 ◦ C, while trying to maintain it at 1.5 ◦ C above pre-industrial levels” [1]. On the consumer side, energy demand is projected to grow rapidly in all countries due to greater electrification, proliferation of cooling equipment, electric mobility and climate change
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