Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid

Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid

It is known that keeping the power balance between generation and demand is crucial in containing the system frequency within acceptable limits. This is especially important for renewable based distributed hybrid microgrid (DHμG) systems where deviations are more likely to occur. In order to address...

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Main Authors: Abdul Latif, S. M. Suhail Hussain, Dulal Chandra Das, Taha Selim Ustun
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Energies
Subjects:
dual-level proportional-integral-one plus double derivative controller
frequency control
distributed hybrid microgrid system
mine blast algorithmic technique
Online Access:https://www.mdpi.com/1996-1073/14/9/2418
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spelling doaj-f3ae14d926fd4eb787204689f264c92a2021-04-23T23:06:00ZengMDPI AGEnergies1996-10732021-04-01142418241810.3390/en14092418Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid MicrogridAbdul Latif0S. M. Suhail Hussain1Dulal Chandra Das2Taha Selim Ustun3Department of Electrical Engineering, National Institute of Technology Silchar, Assam 788010, IndiaFukushima Renewable Energy Institute, AIST (FREA), National Institute of Advanced Industrial Science and Technology (AIST), Koriyama 9630298, JapanDepartment of Electrical Engineering, National Institute of Technology Silchar, Assam 788010, IndiaFukushima Renewable Energy Institute, AIST (FREA), National Institute of Advanced Industrial Science and Technology (AIST), Koriyama 9630298, JapanIt is known that keeping the power balance between generation and demand is crucial in containing the system frequency within acceptable limits. This is especially important for renewable based distributed hybrid microgrid (DHμG) systems where deviations are more likely to occur. In order to address these issues, this article develops a prominent dual-level “proportional-integral-one plus double derivative {PI−(1 + DD)} controller” as a new controller for frequency control (FC) of DHμG system. The proposed control approach has been tested in DHμG system that consists of wind, tide and biodiesel generators as well as hybrid plug-in electric vehicle and an electric heater. The performance of the modified controller is tested by comparing it with standard proportional-integral (PI) and classical PID (CPID) controllers considering two test scenarios. Further, a recently developed mine blast technique (MBA) is utilized to optimize the parameters of the newly designed {PI − (1 + DD)} controller. The controller’s performance results are compared with cases where particle swarm optimization (PSO) and firefly (FF) techniques are used as benchmarks. The superiority of the MBA-{PI − (1 + DD)} controller in comparison to other two strategies is illustrated by comparing performance parameters such as maximum frequency overshoot, maximum frequency undershoot and stabilization time. The displayed comparative objective function (J) and J<sub>FOD</sub> index also shows the supremacy of the proposed controller. With this MBA optimized {PI − (1 + DD)} controller, frequency deviations can be kept within acceptable limits even with high renewable energy penetration.https://www.mdpi.com/1996-1073/14/9/2418dual-level proportional-integral-one plus double derivative controllerfrequency controldistributed hybrid microgrid systemmine blast algorithmic technique
collection DOAJ
language English
format Article
sources DOAJ
author Abdul Latif
S. M. Suhail Hussain
Dulal Chandra Das
Taha Selim Ustun
spellingShingle Abdul Latif
S. M. Suhail Hussain
Dulal Chandra Das
Taha Selim Ustun
Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid
Energies
dual-level proportional-integral-one plus double derivative controller
frequency control
distributed hybrid microgrid system
mine blast algorithmic technique
author_facet Abdul Latif
S. M. Suhail Hussain
Dulal Chandra Das
Taha Selim Ustun
author_sort Abdul Latif
title Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid
title_short Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid
title_full Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid
title_fullStr Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid
title_full_unstemmed Design and Implementation of Maiden Dual-Level Controller for Ameliorating Frequency Control in a Hybrid Microgrid
title_sort design and implementation of maiden dual-level controller for ameliorating frequency control in a hybrid microgrid
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2021-04-01
description It is known that keeping the power balance between generation and demand is crucial in containing the system frequency within acceptable limits. This is especially important for renewable based distributed hybrid microgrid (DHμG) systems where deviations are more likely to occur. In order to address these issues, this article develops a prominent dual-level “proportional-integral-one plus double derivative {PI−(1 + DD)} controller” as a new controller for frequency control (FC) of DHμG system. The proposed control approach has been tested in DHμG system that consists of wind, tide and biodiesel generators as well as hybrid plug-in electric vehicle and an electric heater. The performance of the modified controller is tested by comparing it with standard proportional-integral (PI) and classical PID (CPID) controllers considering two test scenarios. Further, a recently developed mine blast technique (MBA) is utilized to optimize the parameters of the newly designed {PI − (1 + DD)} controller. The controller’s performance results are compared with cases where particle swarm optimization (PSO) and firefly (FF) techniques are used as benchmarks. The superiority of the MBA-{PI − (1 + DD)} controller in comparison to other two strategies is illustrated by comparing performance parameters such as maximum frequency overshoot, maximum frequency undershoot and stabilization time. The displayed comparative objective function (J) and J<sub>FOD</sub> index also shows the supremacy of the proposed controller. With this MBA optimized {PI − (1 + DD)} controller, frequency deviations can be kept within acceptable limits even with high renewable energy penetration.
topic dual-level proportional-integral-one plus double derivative controller
frequency control
distributed hybrid microgrid system
mine blast algorithmic technique
url https://www.mdpi.com/1996-1073/14/9/2418
work_keys_str_mv AT abdullatif designandimplementationofmaidenduallevelcontrollerforamelioratingfrequencycontrolinahybridmicrogrid
AT smsuhailhussain designandimplementationofmaidenduallevelcontrollerforamelioratingfrequencycontrolinahybridmicrogrid
AT dulalchandradas designandimplementationofmaidenduallevelcontrollerforamelioratingfrequencycontrolinahybridmicrogrid
AT tahaselimustun designandimplementationofmaidenduallevelcontrollerforamelioratingfrequencycontrolinahybridmicrogrid
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