Abstract
An effective condition monitoring system of wind turbines generally requires installation of a high number of sensors and use of a high sampling frequency in particular for monitoring of the electrical components within a turbine, resulting in a large amount of data. This can become a burden for condition monitoring and fault detection systems. This paper aims to develop algorithms that will allow a reduced dataset to be used in wind turbine fault detection. This paper first proposes a variable selection algorithm based on principal component analysis with multiple selection criteria in order to select a set of variables to target fault signals while still preserving the variation of data in the original dataset. With the selected variables, this paper then describes fault detection and identification algorithms, which can identify faults, determine the corresponding time and location where the fault occurs, and estimate its severity. The proposed algorithms are evaluated with simulation data from PSCAD/EMTDC, Supervisory control and data acquisition data from an operational wind farm, and experimental data from a wind turbine test rig. Results show that the proposed methods can select a reduced set of variables with minimal information lost whilst detecting faults efficiently and effectively.
Highlights
T HE importance of continuous and autonomous condition monitoring (CM) and fault detection systems for engineering applications has increased dramatically in the past decades
According to IRENA, the operation and maintenance cost of a wind turbines (WTs) is between 10%–25% of the total cost of electricity [2], [3]
Based on the information collected from sensors, a CM system monitors and identifies potential anomalies and predicts
Summary
T HE importance of continuous and autonomous condition monitoring (CM) and fault detection systems for engineering applications has increased dramatically in the past decades. This is the case for wind power, as turbines are often deployed in remote and harsh environments. CM techniques can help improve the performance and reliability of the wind turbines (WTs) [1]. According to IRENA, the operation and maintenance cost of a WT is between 10%–25% of the total cost of electricity [2], [3]. With increasing size and complexity of turbines, and the move to building more offshore wind farms, maintaining the performance and reliability of WTs technically and financially has become a challenge.
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