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Online Health Monitoring and Incipient Fault Detection for Large Wind Turbine Based on a Data-Driven Method

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Abstract:

Faults can cause a reduction or complete interruption in the wind power generation of wind turbines, making it crucial to detect faults at its early stage to allow for ti...Show More

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Abstract:

Faults can cause a reduction or complete interruption in the wind power generation of wind turbines, making it crucial to detect faults at its early stage to allow for timely maintenance and replacement decisions, and to prevent significant economic losses. However, many fault detection methods that rely on analyzing Supervisory Control and Data Acquisition (SCADA) data are not sensitive enough to detect incipient faults. In this paper, a data-driven fault detection method is proposed to address the detection of incipient faults in wind turbines. The collected multivariable data from the wind turbine SCADA system is effectively reduced in dimensionality using the Principal Component Analysis (PCA) method. In addition, secondary dimensionality reduction and feature enhancement can be performed on the feature variables in the principal subspace and residual subspace using Hotelling T2 and Squared Prediction Error (SPE) algorithms, respectively. Based on the feature-enhanced feature vector, small deviations caused by incipient faults are accumulated and amplified using the cumulative sum (CUSUM) algorithm so that the incipient faults can be detected. Experimental verification is conducted using multitemperature data can successfully detect the incipient fault, providing a warning 43 days earlier than the SCADA system. Our proposed method can effectively extract and enhance incipient fault features, with great prospects in online health monitoring of wind turbine systems and incipient fault detection in wind turbines.

Published in: 2024 Prognostics and System Health Management Conference (PHM)

Date of Conference: 28-31 May 2024

Date Added to IEEE Xplore: 17 September 2024

ISBN Information:

ISSN Information:

DOI: 10.1109/PHM61473.2024.00015

Conference Location: Stockholm, Sweden

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References is not available for this document.

Contents

I. Introduction

Wind energy, as a renewable and clean source of energy, is a growing contributor to the world's energy markets [1]. Wind turbine is a device converting wind energy into electricity efficiently. However, due to the complexity of its structure and the diversity of control methods, it has a high failure rate leading to the increase of capital investment in wind farm equipment operation and maintenance year by year. Monitoring the operating status and incipient fault detection, and providing appropriate repair and replacement strategies in time can effectively reduce the operation and maintenance costs of wind turbines and prolong their service life [2].

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Z. W. Gao and X. X. Liu, "An Overview on Fault Diagnosis Prognosis and Resilient Control for Wind Turbine Systems", Processes, vol. 9, no. 2, Feb. 2021.

CrossRef Google Scholar

F. Zhang, Z. Wen, D. Liu, J. Jiao, H. Wan and B. Zeng, "Calculation and Analysis of Wind Turbine Health Monitoring Indicators Based on the Relationships with SCADA Data", Applied Sciences-Basel, vol. 10, no. 1, Jan. 2020.

CrossRef Google Scholar

J. Y. Ma and Y. P. Yuan, "Application of SCADA data in wind turbine fault detection - a review", Sensor Rev, vol. 43, no. 1, pp. 1-11, Jan. 2023.

CrossRef Google Scholar

R. Pandit, D. Astolfi, J. R. Hong, D. Infield and M. Santos, "SCADA data for wind turbine data-driven condition/performance monitoring: A review on state-of-art challenges and future trends", Wind Eng, vol. 47, no. 2, pp. 422-441, Apr. 2023.

CrossRef Google Scholar

J. Tautz-Weinert and S. J. Watson, "Using SCADA data for wind turbine condition monitoring - a review", let Renew Power Gen, vol. 11, no. 4, pp. 382-394, Mar. 2017.

CrossRef Google Scholar

X. H. Jin, Z. W. Xu and W. Qiao, "Condition Monitoring of Wind Turbine Generators Using SCADA Data Analysis", Ieee T SustainEnerg, vol. 12, no. 1, pp. 202210, Jan. 2021.

View Article

Google Scholar

X. Y. Liu, S. X. Lu, Y. Ren and Z. N. Wu, "Wind Turbine Anomaly Detection Based on SCADA Data Mining", Electronics-Switz, vol. 9, no. 5, May 2020.

CrossRef Google Scholar

M. Arshad and B. C. O'Kelly, "Offshore wind-turbine structures: a review", P I Civil Eng-Energy, vol. 166, no. 4, pp. 139-152, 2013.

CrossRef Google Scholar

X. Wang, Q. C. Zhao, X. B. Yang and B. Zeng, "Condition monitoring of wind turbines based on analysis of temperature-related parameters n supervisory control and data acquisition data", Meas Control-Uk, vol. 53, no. 1–2, pp. 164-180, Jan. 2020.

CrossRef Google Scholar

10.

L. Gui, Q. C. Zhao, Q. H. Ling, A. F. Zhu, X. Wang and B. Zeng, "Analysis of temperature anomaly of pitch motor based on SCADA data", Proc Spie, vol. 11343, 2019.

CrossRef Google Scholar

11.

N. Taki, W. Ben Hassen, N. Ravot, C. Delpha and D. Diallo, "Frequency Selection for Reflectometry-based Soft Fault Detection using Principal Component Analysis", Prognost Syst Healt, pp. 273-278, 2019.

View Article

Google Scholar

12.

M. A. Bin Shams, H. M. Budman and T. A. Duever, "Fault detection identification and diagnosis using CUSUM based PCA", Chem Eng Sci, vol. 66, no. 20, pp. 4488-4498, Oct. 2011.

CrossRef Google Scholar

References is not available for this document.

Online Health Monitoring and Incipient Fault Detection for Large Wind Turbine Based on a Data-Driven Method

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Online Health Monitoring and Incipient Fault Detection for Large Wind Turbine Based on a Data-Driven Method

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Metadata

Abstract:

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I. Introduction

References

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