Optimal sizing of a utility-scale energy storage system in transmission networks to improve frequency response

•Optimal sizing of a grid-scale battery energy storage system is investigated.•Frequency deviation and ROCOF are minimized through the BESS sizing.•Parameter tuning of BESS PQ controller (active power part) is performed.•Both power and energy sizes of the BESS are estimated.•Frequency response of tr...

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Published in:Journal of energy storage 2020-06, Vol.29, p.101315, Article 101315
Main Authors: Das, Choton K., Mahmoud, Thair S., Bass, Octavian, Muyeen, S.M., Kothapalli, Ganesh, Baniasadi, Ali, Mousavi, Navid
Format: Article
Language:English
Subjects:
Artificial bee colony
Battery sizing
Battery storage
BESS
Change of frequency
Controller tuning
DIgSILENT PowerFactory
Energy storage system
Fitness-scaled chaotic
Frequency deviation
Frequency nadir
Frequency response
Generator dispatch
Hybrid meta-heuristic
IEEE 39 bus data
PSO
ROCOF
Transmission network planning
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cited_by cdi_FETCH-LOGICAL-c297t-6844672e6de1fae9ebc7b79c9fc26f01db266361eb6b28004cbc8339b96359e63
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container_end_page
container_issue
container_start_page 101315
container_title Journal of energy storage
container_volume 29
creator Das, Choton K.
Mahmoud, Thair S.
Bass, Octavian
Muyeen, S.M.
Kothapalli, Ganesh
Baniasadi, Ali
Mousavi, Navid
description •Optimal sizing of a grid-scale battery energy storage system is investigated.•Frequency deviation and ROCOF are minimized through the BESS sizing.•Parameter tuning of BESS PQ controller (active power part) is performed.•Both power and energy sizes of the BESS are estimated.•Frequency response of transmission networks is improved. The frequency response of a large power system is affected by the penetration of renewable energy sources (RESs), where a utility-scale energy storage system (ESS) can alleviate the problem. This paper presents a strategy for sizing an ESS to improve frequency response of transmission networks. The location of the ESS in the transmission network is determined through a sensitivity analysis targeting minimum line loading around a bus. The ESS sizing strategy considers the minimization of frequency deviation as well as rate of change of frequency (ROCOF) after generator or load tripping events. The tuning of PQ controller parameters of the ESS (active power part) is also performed for frequency response improvement. The proposed approach is tested in a modified IEEE-39 bus power system considering a variety of scenarios where RESs are integrated as four different schemes for peak and off-peak load conditions. DIgSILENT PowerFactory is used for developing, testing, and analyzing the system models. A fitness-scaled chaotic artificial bee colony (FSCABC) optimization algorithm (a hybrid meta-heuristic approach) is used for optimization through a Python script automating simulation events in PowerFactory. The results obtained from the FSCABC approach are verified through the application of a particle swarm optimization algorithm. The simulation results suggest that the proposed ESS sizing technique including ESS controller tuning can successfully improve the frequency response of a transmission network.
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The frequency response of a large power system is affected by the penetration of renewable energy sources (RESs), where a utility-scale energy storage system (ESS) can alleviate the problem. This paper presents a strategy for sizing an ESS to improve frequency response of transmission networks. The location of the ESS in the transmission network is determined through a sensitivity analysis targeting minimum line loading around a bus. The ESS sizing strategy considers the minimization of frequency deviation as well as rate of change of frequency (ROCOF) after generator or load tripping events. The tuning of PQ controller parameters of the ESS (active power part) is also performed for frequency response improvement. The proposed approach is tested in a modified IEEE-39 bus power system considering a variety of scenarios where RESs are integrated as four different schemes for peak and off-peak load conditions. 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The frequency response of a large power system is affected by the penetration of renewable energy sources (RESs), where a utility-scale energy storage system (ESS) can alleviate the problem. This paper presents a strategy for sizing an ESS to improve frequency response of transmission networks. The location of the ESS in the transmission network is determined through a sensitivity analysis targeting minimum line loading around a bus. The ESS sizing strategy considers the minimization of frequency deviation as well as rate of change of frequency (ROCOF) after generator or load tripping events. The tuning of PQ controller parameters of the ESS (active power part) is also performed for frequency response improvement. The proposed approach is tested in a modified IEEE-39 bus power system considering a variety of scenarios where RESs are integrated as four different schemes for peak and off-peak load conditions. 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subjects Artificial bee colony
Battery sizing
Battery storage
BESS
Change of frequency
Controller tuning
DIgSILENT PowerFactory
Energy storage system
Fitness-scaled chaotic
Frequency deviation
Frequency nadir
Frequency response
Generator dispatch
Hybrid meta-heuristic
IEEE 39 bus data
PSO
ROCOF
Transmission network planning
title Optimal sizing of a utility-scale energy storage system in transmission networks to improve frequency response
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