Your search keyword '"Guo, Jicai"' showing total 2 results

1. Review of Data-Driven Approaches for Wind Turbine Blade Icing Detection.

Author

Cai, Chang, Guo, Jicai, Song, Xiaowen, Zhang, Yanfeng, Wu, Jianxin, Tang, Shufeng, Jia, Yan, Xing, Zhitai, and Li, Qing'an

Abstract

Onshore wind turbines are primarily installed in high-altitude areas with good wind energy resources. However, in winter, the blades are easy to ice, which will seriously impact their aerodynamic performance, as well as the power and service life of the wind turbine. Therefore, it is of great practical significance to predict wind turbine blade icing in advance and take measures to eliminate the adverse effects of icing. Along these lines, three approaches to supervisory control and data acquisition (SCADA) data feature selection were summarized in this work. The problems of imbalance between positive and negative sample datasets, the underutilization of SCADA data time series information, the scarcity of high-quality labeled data, and weak model generalization capabilities faced by data-driven approaches in wind turbine blade icing detection, were reviewed. Finally, some future trends in data-driven approaches were discussed. Our work provides guidance for the use of technical means in the actual detection of wind turbine blades. In addition, it also gives some insights to the further research of fault diagnosis technology. [ABSTRACT FROM AUTHOR]

Published

2023

2. Fault diagnosis of wind turbine blade icing based on feature engineering and the PSO-ConvLSTM-transformer.

Author

Guo, Jicai, Song, Xiaowen, Tang, Shufeng, Zhang, Yanfeng, Wu, Jianxin, Li, Yuan, Jia, Yan, Cai, Chang, and Li, Qing'an

Subjects

*WIND turbine blades, *ARTIFICIAL neural networks, *FAULT diagnosis, *COLD weather conditions, *OPTIMIZATION algorithms, *PARTICLE swarm optimization, *WIND turbines

Abstract

In winter, wind turbines often face the risk of blade icing, and traditional methods – which mostly rely on manual observation and sensors – are limited by the experience of testers and costs; therefore, they are not widely used in practice. With the development of artificial intelligence, data-driven methods have garnered increased attention. However, it is challenging to mine the effective hidden information within data. In this regard, this paper proposes a wind turbine blade icing detection method based on feature engineering and the PSO-ConvLSTM-Transformer. Firstly, feature engineering is carried out with the help of expert experience to construct the mechanism variables related to icing; secondly, the ConvLSTM-Transformer prediction model is constructed to mine the timing information between supervisory control and data acquisition (SCADA) data, and finally, the model hyper-parameters are optimized by using the particle swarm optimization (PSO) algorithm to improve the diagnostic performance and generalizability of the model. The proposed model is evaluated using two wind turbine blade icing datasets. The proposed PSO-ConvLSTM-Transformer has significant advantages over multiple baseline models. This study can inform wind farm operations in terms of optimizing maintenance strategies, ensuring the safe and efficient operation of wind turbines in cold weather conditions. • Constructing ConvLSTM-Transformers deep learning model for wind turbine icing detection. • Explored the impact of domain knowledge-based icing mechanism features on deep neural networks. • Tested the effect of different optimization algorithms on the performance of deep learning models. [ABSTRACT FROM AUTHOR]

Published

2024