Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer

In a wind turbine (WT), the maximum power can be achieved using a suitable and smooth signal, which should be applied to the pitch angle of the blades (PABLE). On the contrary, the uncertainties of the WT models cause the fatigue due to the mechanical stresses. To overcome these two problems, dynami...

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Main Authors: Karami Mollaee, Ali, Shojaei, Ali Asghar, Othman, Mohd. Fauzi
Format: Article
Published: SAGE Publications Ltd 2022
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Online Access:http://eprints.utm.my/104659/
http://dx.doi.org/10.1177/01423312221099304
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Institution: Universiti Teknologi Malaysia
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spelling my.utm.1046592024-02-21T08:54:18Z http://eprints.utm.my/104659/ Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer Karami Mollaee, Ali Shojaei, Ali Asghar Othman, Mohd. Fauzi TK Electrical engineering. Electronics Nuclear engineering In a wind turbine (WT), the maximum power can be achieved using a suitable and smooth signal, which should be applied to the pitch angle of the blades (PABLE). On the contrary, the uncertainties of the WT models cause the fatigue due to the mechanical stresses. To overcome these two problems, dynamic sliding mode control (D-SMC) is used because it is robust against uncertainties and can suppress the chattering by providing smooth signals. In D-SMC, an integrator is located before the actuator, as a low-pass filter, to suppress the high-frequency chattering. Then, the states number of the overall augmented system is one more than the states number of the actual system. To control such an augmented system, the added state variable needs to be estimated and hence, a novel sliding mode observer (SMO) is proposed. A trusty comparison is also presented using the conventional sliding mode control (C-SMC) with the proposed SMO. To implement D-SMC and C-SMC, a new state feedback is applied to the turbine at first. Therefore, a linear model with uncertainty is obtained, where its input is the PABLE. Lyapunov theory is used to proof the stability of the proposed SMO, D-SMC, and also the C-SMC. The presented comparison demonstrates the advantages of the D-SMC with respect to the C-SMC in removing the chattering and simplicity in concept and in implementation. SAGE Publications Ltd 2022-11 Article PeerReviewed Karami Mollaee, Ali and Shojaei, Ali Asghar and Othman, Mohd. Fauzi (2022) Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer. Transactions of the Institute of Measurement and Control, 44 (15). pp. 3028-3038. ISSN 0142-3312 http://dx.doi.org/10.1177/01423312221099304 DOI:10.1177/01423312221099304
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic TK Electrical engineering. Electronics Nuclear engineering
spellingShingle TK Electrical engineering. Electronics Nuclear engineering
Karami Mollaee, Ali
Shojaei, Ali Asghar
Othman, Mohd. Fauzi
Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer
description In a wind turbine (WT), the maximum power can be achieved using a suitable and smooth signal, which should be applied to the pitch angle of the blades (PABLE). On the contrary, the uncertainties of the WT models cause the fatigue due to the mechanical stresses. To overcome these two problems, dynamic sliding mode control (D-SMC) is used because it is robust against uncertainties and can suppress the chattering by providing smooth signals. In D-SMC, an integrator is located before the actuator, as a low-pass filter, to suppress the high-frequency chattering. Then, the states number of the overall augmented system is one more than the states number of the actual system. To control such an augmented system, the added state variable needs to be estimated and hence, a novel sliding mode observer (SMO) is proposed. A trusty comparison is also presented using the conventional sliding mode control (C-SMC) with the proposed SMO. To implement D-SMC and C-SMC, a new state feedback is applied to the turbine at first. Therefore, a linear model with uncertainty is obtained, where its input is the PABLE. Lyapunov theory is used to proof the stability of the proposed SMO, D-SMC, and also the C-SMC. The presented comparison demonstrates the advantages of the D-SMC with respect to the C-SMC in removing the chattering and simplicity in concept and in implementation.
format Article
author Karami Mollaee, Ali
Shojaei, Ali Asghar
Othman, Mohd. Fauzi
author_facet Karami Mollaee, Ali
Shojaei, Ali Asghar
Othman, Mohd. Fauzi
author_sort Karami Mollaee, Ali
title Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer
title_short Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer
title_full Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer
title_fullStr Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer
title_full_unstemmed Dynamic sliding mode control of pitch blade wind turbine using sliding mode observer
title_sort dynamic sliding mode control of pitch blade wind turbine using sliding mode observer
publisher SAGE Publications Ltd
publishDate 2022
url http://eprints.utm.my/104659/
http://dx.doi.org/10.1177/01423312221099304
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