Progress in smart industrial control applied to renewable energy system

被引：2

作者：

Salhi M.S. ^{[1
]}

Kashoob S. ^{[2
]}

Lachiri Z. ^{[1
]}

机构：

[1] National Engineering School of Tunis-Tunisia, Research Laboratory of Signal Image and Information Technology LR-SITI, University of Tunis El Manor, Tunis

[2] Ministry of Higher Education, Director of SVC, Salalah

来源：

Energy Harvesting and Systems | 2022年 / 9卷 / 02期

关键词：

failure diagnosis; neural evolutionary algorithm; renewable energy; smart control;

D O I：

10.1515/ehs-2021-0004

中图分类号：

学科分类号：

摘要：

The industrial Supervising Control and Data Acquisition, referred by SCADA system, tends to improve its accuracy in detecting faults. In that, it uses fault diagnosis models based mostly on probabilistic methods with close uncertainties. These models are based on a subjective evaluation by comparing the obtained signal to its reference. Therefore, SCADA precision fault detection varies depending on the operation environment, system design and analysis approach among other factors. The contribution of this research work is to propose a smart strategy that will enrich and enhance failure recognition in SCADA systems by integrating two additional models into the classic technique. The first model is a SOM map reduce simple classifier and the second model is an evolutionary recurrent self-organizing neural filter for final decision-making. This integrated paradigm improves results accuracy and robustness against signal interference. The proposed idea involves best details around any remotely listed defect. This study has been conducted on Simulink-Matlab, through the analysis of multi signals emitted by sensors and received by corresponding antennas. © 2022 Walter de Gruyter GmbH, Berlin/Boston.

引用

页码：123 / 132

页数：9

共 18 条

[1]

Blickey G.J., SCADA Systems Affected by Distributed Control, Control Engineering, 32, 3, pp. 79-81, (1985)

[2]

Boualem I., Contribution À l'Étude de la Superviion Industrielle Automatique dans un Environnement SCADA, pp. 1-103, (2009)

[3]

Boyer S.A., SCADA: Supervisory Control and Data Acquisition, (1993)

[4]

Chartre J.-M., Supervision: Outil de Mesure de la Production", Techniques de l'Ingénieur, National Conservatory of Arts and Crafts-France, R 7630, pp. 1-14, (2013)

[5]

Farana R., L.landryova, Data Visualization of the SCADA lHMI System on the Internet/Intranet, 13th International Conference on Automation in Mining ICAMC'98/ASRTP'98, High Tatras, pp. 386-389, (1998)

[6]

Gaushell D.J., Darlington H.T., Supervisory Control and Data Acquisition, Proceedings of the IEEE, 75, pp. 1645-1658, (1987)

[7]

Ibrahim H., Etude et Conception d'Un Générateur Hybride d'Électricité de Type Éolien-diesel Avec Élément de Stockage d'Air Comprimé, pp. 1-345, (2010)

[8]

Ibrahim H., Adrian I., Younes R., Perron J., T.basbous, Study of a Hybrid Wind-Diesel System with Compressed Air Energy Storage." in Electrical Power Conference, 2007, EPC, pp. 1-7, (2007)

[9]

Ibrahim H., Ilinca A., Rousse D., Dutil Y., J.perron, Analyse des Systèmes de Génération d'Électricité Pour les Sites Isolés Basés sur l'Utilisation du Stockage d'Air Comprimé en Hybridation Avec un Jumelage Éolien-diesel, pp. 28-30, (2012)

[10]

Landryova L., Zolotova I., Integrated Environment of SCADAlHMI for Process Simulation, INES'99, 3rd IEEE International Conference on Intelligent Engineering Systems 1999 Hight Tatras, pp. 99-105, (1999)

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