A comprehensive study of battery-supercapacitor hybrid energy storage system for standalone PV power system in rural electrification

Jing, Wenlong; Lai, Chean Hung; Wong, Wallace; Wong, M. L. Dennis

doi:10.1016/j.apenergy.2018.04.106

Cited by 205 publications

(89 citation statements)

References 45 publications

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“…The performance in IEEE 33 bus before and after optimization based on the PV size with the location is described in Figure 5. The voltage profile is obtained through Equation (16); the active loss and the reactive loss are calculated according to Equations (19) and (22); then the total loss index is calculated using Equation (23); the energy storage in the battery, when it is required, supplies the energy to the consumer, and it is obtained through Equation (15), and the power loss in Equation (18) has been derived. The performance in IEEE 33 bus voltage before and after optimization is illustrated in Figure 6.…”

Section: Ieee 33 Busmentioning

confidence: 99%

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Optimal location and sizing of hybrid system by analytical crow search optimization algorithm

Pandey

Kirmani

2020

Int Trans Electr Energ Syst

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Summary This study presents a strategy for selecting an optimal location and placing the optimal photovoltaic (PV) and energy storage system. The power loss, voltage stability of the system, and also sizes of PV and storage are the major objectives, which are obtained through analytical crow search optimization (CSO) algorithm. Initially, the Newton‐Raphson load flow analysis is performed; and voltage, and losses of active and reactive power are calculated. The dynamic modelling of the proposed system time interval varies between 1 and 24 hours. The injection of active and reactive power is based on the nondispatchable PV, which can work under the optimal load flow. The major calculation of this work includes the fill factor, load, maximum power, battery, energy loss, and voltage stability. The two test systems, IEEE 33 and IEEE 69 bus systems, have been utilized for validating the performance of a proposed strategy. Finally, the proposed strategy has been compared with some different methods such as improved analytical (IA), exhaustive load flow (ELF), analytical multiobjective index (AIMO), analytical particle swarm optimization (A‐PSO), and fast IA (FIA). From the comparison results, the proposed strategy proves the efficient PV size selection for an optimal location to minimize power and voltage losses.

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Section: Ieee 33 Busmentioning

confidence: 99%

“…14 If the battery internal losses and heating are minimized, dynamic stress is automatically reduced. 15 In this way, these systems reduce environmental contamination, which is controlled to the zero percentage minimum, which means also pollution free. 16 The PV panel generated power that also generated higher performance of the system.…”

Section: Introductionmentioning

confidence: 99%

Optimal location and sizing of hybrid system by analytical crow search optimization algorithm

Pandey

Kirmani

2020

Int Trans Electr Energ Syst

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“…A number of studies have been conducted to analyze and quantify the extent of this HESS combination [28]. A comparative study between ESS and HESS is presented in [29], where the authors present a semi-active topology in which SCSS absorbs abrupt peak power fluctuations with BESS passively connected to the wind turbine generator (WTG), regulating the DC link voltage and absorbing the low power fluctuations.…”

Section: Topologies Of Hybrid Energy Storage System and Its Applicationsmentioning

confidence: 99%

“…The concept of multi-level HESS in proposed in studies [28,36]. The methodology proposes the idea of implementing primary BESS, secondary BESS and an SCSS.…”

Section: Topologies Of Hybrid Energy Storage System and Its Applicationsmentioning

confidence: 99%

“…Therefore, lead-acid batteries are considered as primary BESS, and Li-ion batteries constituting a comparatively lower power rating is taken as secondary BESS; this configuration provides a pragmatic approach to HESS implementation as low life expectancy of commonly preferred lead-acid battery leads to low reliability of BESS, that can be compensated by techno-economic integration of Li-ion batteries. Ultimately, the flexibility and reliability of operation is more enhanced specifically for standalone/ rural electrification scenarios [28].…”

Section: Topologies Of Hybrid Energy Storage System and Its Applicationsmentioning

confidence: 99%

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A Review on the Selected Applications of Battery-Supercapacitor Hybrid Energy Storage Systems for Microgrids

Khalid

2019

Energies

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This paper presents a comprehensive categorical review of the recent advances and past research development of the hybrid storage paradigm over the last two decades. The main intent of the study is to provide an application-focused survey where every category and sub-category herein is thoroughly and independently investigated. Implementation of energy storage systems is one of the most interestingly effective options for further progression in the field of alternative energy technology. Apart from a meticulous garnering of the energy resources regulated by the energy storage, the main concern is to optimize the characteristic integrity of the storage devices to achieve a practically techno-economic size and operation. In this paper, hybrid energy storage consisting of batteries and supercapacitors is studied. The fact that the characteristic of batteries is mostly complementary to that of supercapacitors, hybridizing these storage systems enhances their scope of application in various fields. Therefore, the objective of this paper is to present an inclusive review of these applications. Specifically, the application domain includes: (1) regulation of renewable energy sources, (2) contributions to grid regulation (voltage and frequency compensation, contribution to power system inertia), (3) energy storage enhancements (life cycle improvement, and size reduction), (4) regenerative braking in electric vehicles, (5) improvement in wireless power transfer technology. Further, this review also descriptively highlights the control strategies implemented in these domains of applications. The application-oriented review explicates the principle advantages with the hybridization of battery and supercapacitor energy storage systems that can be used as an insight for further development in the field of energy storage technology and its applications. Power Ratings (MW) 0-0.03 [12,13] 0-20 [12,13] 0-0.01 [12,13] 0.05-8 [12,13] 0.03-3 [12,13] 0-0.3 [12] 50 [13] Energy Density, Wh/L

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Coordination of hybrid energy storage system, photovoltaic systems, smart lighting loads, and thermostatically controlled loads for microgrid frequency control

Bagheri-Sanjareh

Nazari

2021

Int Trans Electr Energ Syst

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Summary The supercapacitors (SCs) are suitable for short‐term fast power regulations, while the batteries are suitable for long‐term slow energy management of microgrid (MG). As SCs and batteries complement each other's deficiencies, the SC‐battery hybrid energy storage systems (SBHESS) have been commonly used for mixed applications of fast transient and slow long‐term power regulations. The SC reduces the stress of fast power variations on the battery, which prolongs its lifetime. However, it increases the cost of the energy storage in comparison to the case that battery is just used. Therefore, the drawback of SBHESS is its increased cost. The sizes of SC and its converter, which directly determine their costs, should be enough to handle primary frequency control (PFC) in the worst cases of shortage and surplus power generation that the MG ever experiences. In this paper, the potentials of Photovoltaic (PV) systems, smart LED lighting loads (SLEDLLs), and thermostatically controlled loads (TCLs) in PFC is used to decrease the participation share of SC in the PFC and hence decrease the sizes and costs of SC, and its converter. The simulation results show that with the coordination of SBHESS, SLEDLLs, PVs, and TCLs, the required sizes of SC and its converter are decreased by 64% and 50%, respectively. Also, for a 10‐year period operation, the total cost of SC and its converter is decreased by 51.5%.

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A comprehensive study of battery-supercapacitor hybrid energy storage system for standalone PV power system in rural electrification

Cited by 205 publications

References 45 publications

Optimal location and sizing of hybrid system by analytical crow search optimization algorithm

Optimal location and sizing of hybrid system by analytical crow search optimization algorithm

A Review on the Selected Applications of Battery-Supercapacitor Hybrid Energy Storage Systems for Microgrids

Coordination of hybrid energy storage system, photovoltaic systems, smart lighting loads, and thermostatically controlled loads for microgrid frequency control

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