Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO

Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO

Higher penetration of variable renewable energy sources into the grid brings down the plant load factor of thermal power plants. However, during sudden changes in load, the thermal power plants support the grid, though at higher ramping rates and with inefficient operation. Hence, further renewable...

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Main Authors: Ramakrishna S. S. Nuvvula, Devaraj Elangovan, Kishore Srinivasa Teegala, Rajvikram Madurai Elavarasan, Md. Rabiul Islam, Ravikiran Inapakurthi
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:Energies
Subjects:
multi-objective ALA-QPSO
renewable energy sources
floating solar PV
bifacial solar panels
battery energy storage system
Online Access:https://www.mdpi.com/1996-1073/14/17/5368
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spelling doaj-1cf4bb48ab454c1184b5c1c27298a28b2021-09-09T13:43:09ZengMDPI AGEnergies1996-10732021-08-01145368536810.3390/en14175368Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSORamakrishna S. S. Nuvvula0Devaraj Elangovan1Kishore Srinivasa Teegala2Rajvikram Madurai Elavarasan3Md. Rabiul Islam4Ravikiran Inapakurthi5School of Electrical Engineering, Vellore Institute of Technology (VIT), Vellore 632014, IndiaTIFAC-CORE, Vellore Institute of Technology (VIT), Vellore 632014, IndiaElectrical & Electronics Engineering, GMR Institute of Technology, Rajam 532127, IndiaClean and Resilient Energy Systems (CARES) Laboratory, Texas A&M University, Galveston, TX 77553, USASchool of Electrical, Computer, and Telecommunications Engineering, University of Wollongong, Wollongong, NSW 2522, AustraliaElectrical & Electronics Engineering, Raghu Engineering College, Dakamarri, Visakhapatnam 531162, IndiaHigher penetration of variable renewable energy sources into the grid brings down the plant load factor of thermal power plants. However, during sudden changes in load, the thermal power plants support the grid, though at higher ramping rates and with inefficient operation. Hence, further renewable additions must be backed by battery energy storage systems to limit the ramping rate of a thermal power plant and to avoid deploying diesel generators. In this paper, battery-integrated renewable energy systems that include floating solar, bifacial rooftop, and wind energy systems are evaluated for a designated smart city in India to reduce ramping support by a thermal power plant. Two variants of adaptive-local-attractor-based quantum-behaved particle swarm optimization (ALA-QPSO) are applied for optimal sizing of battery-integrated and hybrid renewable energy sources to minimize the levelized cost of energy (LCoE), battery life cycle loss (LCL), and loss of power supply probability (LPSP). The obtained results are then compared with four variants of differential evolution. The results show that out of 427 MW of the energy potential, an optimal set of hybrid renewable energy sources containing 274 MW of rooftop PV, 99 MW of floating PV, and 60 MW of wind energy systems supported by 131 MWh of batteries results in an LPSP of 0.005%, an LCoE of 0.077 USD/kW, and an LCL of 0.0087. A sensitivity analysis of the results obtained through ALA-QPSO is performed to assess the impact of damage to batteries and unplanned load appreciation, and it is found that the optimal set results in more energy sustainability.https://www.mdpi.com/1996-1073/14/17/5368multi-objective ALA-QPSOrenewable energy sourcesfloating solar PVbifacial solar panelsbattery energy storage system
collection DOAJ
language English
format Article
sources DOAJ
author Ramakrishna S. S. Nuvvula
Devaraj Elangovan
Kishore Srinivasa Teegala
Rajvikram Madurai Elavarasan
Md. Rabiul Islam
Ravikiran Inapakurthi
spellingShingle Ramakrishna S. S. Nuvvula
Devaraj Elangovan
Kishore Srinivasa Teegala
Rajvikram Madurai Elavarasan
Md. Rabiul Islam
Ravikiran Inapakurthi
Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO
Energies
multi-objective ALA-QPSO
renewable energy sources
floating solar PV
bifacial solar panels
battery energy storage system
author_facet Ramakrishna S. S. Nuvvula
Devaraj Elangovan
Kishore Srinivasa Teegala
Rajvikram Madurai Elavarasan
Md. Rabiul Islam
Ravikiran Inapakurthi
author_sort Ramakrishna S. S. Nuvvula
title Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO
title_short Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO
title_full Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO
title_fullStr Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO
title_full_unstemmed Optimal Sizing of Battery-Integrated Hybrid Renewable Energy Sources with Ramp Rate Limitations on a Grid Using ALA-QPSO
title_sort optimal sizing of battery-integrated hybrid renewable energy sources with ramp rate limitations on a grid using ala-qpso
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2021-08-01
description Higher penetration of variable renewable energy sources into the grid brings down the plant load factor of thermal power plants. However, during sudden changes in load, the thermal power plants support the grid, though at higher ramping rates and with inefficient operation. Hence, further renewable additions must be backed by battery energy storage systems to limit the ramping rate of a thermal power plant and to avoid deploying diesel generators. In this paper, battery-integrated renewable energy systems that include floating solar, bifacial rooftop, and wind energy systems are evaluated for a designated smart city in India to reduce ramping support by a thermal power plant. Two variants of adaptive-local-attractor-based quantum-behaved particle swarm optimization (ALA-QPSO) are applied for optimal sizing of battery-integrated and hybrid renewable energy sources to minimize the levelized cost of energy (LCoE), battery life cycle loss (LCL), and loss of power supply probability (LPSP). The obtained results are then compared with four variants of differential evolution. The results show that out of 427 MW of the energy potential, an optimal set of hybrid renewable energy sources containing 274 MW of rooftop PV, 99 MW of floating PV, and 60 MW of wind energy systems supported by 131 MWh of batteries results in an LPSP of 0.005%, an LCoE of 0.077 USD/kW, and an LCL of 0.0087. A sensitivity analysis of the results obtained through ALA-QPSO is performed to assess the impact of damage to batteries and unplanned load appreciation, and it is found that the optimal set results in more energy sustainability.
topic multi-objective ALA-QPSO
renewable energy sources
floating solar PV
bifacial solar panels
battery energy storage system
url https://www.mdpi.com/1996-1073/14/17/5368
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