Kriging Empirical Mode Decomposition via support vector machine learning technique for autonomous operation diagnosing of CHP in microgrid

Kriging Empirical Mode Decomposition via support vector machine learning technique for autonomous operation diagnosing of CHP in microgrid

•Negligible none detection zone for CHP generator.•Avoiding of threshold selection.•Suitable for microgrid application.•Usable in noisy condition.•Best data selection method. Combined Heat and Power (CHP) is the one of new energy resources which has been added to power system in recent years. High e...

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Bibliographic Details
Published in:Applied thermal engineering Vol. 145; pp. 58 - 70
Main Authors: Shao, Zehui, Wakil, Karzan, Usak, Muhammet, Amin Heidari, Mohammad, Wang, Bo, Simoes, Rolando
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 25-12-2018
Elsevier BV
Subjects:
CHP
Cogeneration
Computer simulation
Decomposition
Distributed generation
Electric power distribution
Electric power systems
Empirical mode decomposition
Energy resources
Energy sources
Islanding detection
Islanding technique
Kriging interpolation
Learning curves
Machine learning
Optimal support vector machine
Pattern learning
Pattern recognition
Power efficiency
Power supply
Relay
Signal processing
Signal selection
Smart grid technology
Smell
Support vector machines
Signal selection
Empirical mode decomposition
CHP
Pattern learning
Optimal support vector machine
Islanding detection
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Summary:•Negligible none detection zone for CHP generator.•Avoiding of threshold selection.•Suitable for microgrid application.•Usable in noisy condition.•Best data selection method. Combined Heat and Power (CHP) is the one of new energy resources which has been added to power system in recent years. High efficiency, Loss reducing of power system and etc, are the main advantages of CHP as same as other distributed generations. But, unwanted islanding is one of the main problems for this generation. This article presents a novel technique for CHP unit islanding detection using Kriging Empirical Mode Decomposition (KEMD) and Support Vector Machine (SVM) pattern learning technique. In this technique the variation of Intrinsic Mode Functions (IMF) of local signals in two-dimensional mode is utilized as input data of relay. An optimal signal selection model is applied to the proposed relay in order to Non-Detection Zone (NDZ) and fails detection reducing. The best signal selection is introduces based on mean square value between islanding and non-islanding conditions. Also, by considering Optimal SVM model for the proposed relay as a pattern recognizing and weighing it using shark smell optimization, this technique has overcome the threshold selection problem. This relay is applied to CHP system in a microgrid system contains various types of DGs. Many islanding and non-islanding situation in various operation conditions in the studied microgrid are simulated. The results of simulation results are show that the proposed relay is suitable for microgrid application. Negligible NDZ, high detection time, zero fail detection and low cost of this relay are the main advantages of the proposed technique.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2018.09.028