Optimal Sizing of Battery Energy Storage for Grid-Connected and Isolated Wind-Penetrated Microgrid

Salman, Umar T.; Al–Ismail, Fahad Saleh; Khalid, Muhammad

doi:10.1109/access.2020.2992654

Cited by 88 publications

(42 citation statements)

References 30 publications

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“…The authors propose a sizing scheme for Battery Energy Storages, which solely depends on optimizing operational cost of a microgrid and minimizing BESS charging and discharging capacity in [21]. This research work investigates the competence of the proposed method in three different scenarios depending on whether the microgrid is connected with the host grid and power can be sold to the host grid.…”

Section: Introductionmentioning

confidence: 99%

Exploring the Utilization of Energy Storage Systems for Frequency Response Adequacy of a Low Inertia Power Grid

et al. 2021

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The utilization of Energy Storage Systems (ESS) for improving the frequency response of a low inertia power system is investigated in this article. Substantial wind power penetration is causing the replacement of conventional synchronous generators in several power systems. Variable speed wind machines traditionally do not contribute to frequency regulation without additional control strategy. As a result, a wind dominated power grid may have inadequate inertia and governor responsive reserve. In such situation, a large contingency may yield undesirable Rate of Change of Frequency (ROCOF) and frequency deviation. To overcome this problem, deployment of ESS, namely, Superconducting Magnetic Energy Storage (SMES) and Battery Energy Storage System (BESS) can be a worthwhile solution. Since these devices are costly, their appropriate sizing and operational approach are crucial. Therefore, in this paper, analytical expressions are derived to find the minimum ratings of SMES and BESS. To this end, system frequency deviation, ROCOF, inertial response and governor response are taken into account. Also, a coordinated operational strategy is proposed to retain frequency response adequacy and minimize under frequency load shedding where SMES is triggered when system ROCOF supersedes a certain limit and BESS is activated due to system frequency surpassing a preset threshold. The performance of the proposed strategy is explored in a low inertia network under substantial wind penetration considering several different wind penetration levels. Also, the results are validated against two existing approaches. Simulation results reveal that the proposed methodology considerably enhances the frequency response in various operating conditions.

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Section: Introductionmentioning

confidence: 99%

Exploring the Utilization of Energy Storage Systems for Frequency Response Adequacy of a Low Inertia Power Grid

et al. 2021

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“…Concerning solar energy, a photovoltaic (PV) cell provides a DC source at unregulated low voltage, and thus power electronics systems must be able to adjust this DC voltage level to one suitable for supplying the load [5]. In the 21st century, therefore, modern solutions based on different energy sources coming from wind, solar, energy storage and micro-turbines have been used to feed the load or different loads [6,7]. Particularly, in a stand-alone microgrid, more energy sources are connected to energy sources coming from wind, solar, energy storage and micro-turbines have been used to feed the load or different loads [6,7].…”

Section: Introductionmentioning

confidence: 99%

“…In the 21st century, therefore, modern solutions based on different energy sources coming from wind, solar, energy storage and micro-turbines have been used to feed the load or different loads [6,7]. Particularly, in a stand-alone microgrid, more energy sources are connected to energy sources coming from wind, solar, energy storage and micro-turbines have been used to feed the load or different loads [6,7]. Particularly, in a stand-alone microgrid, more energy sources are connected to a single DC-bus to supply the load, as shown in Figure 1.…”

Section: Introductionmentioning

confidence: 99%

High-Performance 3-Phase 5-Level E-Type Multilevel–Multicell Converters for Microgrids

et al. 2021

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This paper focuses on the analysis and design of two multilevel–multicell converters (MMCs), named 3-phase 5-Level E-Type Multilevel–Multicell Rectifier (3Φ5L E-Type MMR) and 3-phase 5-Level E-Type Multilevel–Multicell Inverter (3Φ5L E-Type MMI) to be used in microgrid applications. The proposed 3-phase E-Type multilevel rectifier and inverter have each phase being accomplished by the combination of two I-Type topologies connected to the T-Type topology. The two cells of each phase of the rectifier and inverter are connected in interleaving using an intercell transformer (ICT) in order to reduce the volume of the output filter. Such an E-Type topology arrangement is expected to allow both the high efficiency and power density required for microgrid applications, as well as being capable of providing good performance in terms of quality of the voltage and current waveforms. The proposed hardware design and control interface are supported by the simulation results performed in Matlab/Simulink. The analysis has been then validated in terms of an experimental campaign performed on the converter prototype, which presented a power density of 8.4 kW/dm3 and a specific power of 3.24 kW/kg. The experimental results showed that the proposed converter can achieve a peak efficiency of 99% using only silicon power semiconductors.

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“…Similarly, demand varies across the day; it is higher during working hours, i.e., from morning until evening [3,4]. Incidentally, renewable power generation from wind and solar also varies with season, and this has a significant impact on the operation of a wind-penetrated MG in these seasons [5]. However, the MG extensively relies on the support provided from the available dispatchable sources, such as battery energy storage systems (BESS), the grid, or any other source integrated within the MG system.…”

Section: Introductionmentioning

confidence: 99%

Techno-Economic Assessment and Operational Planning of Wind-Battery Distributed Renewable Generation System

et al. 2021

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Electrical energy and power demand will experience exponential increase with the rise of the global population. Power demand is predictable and can be estimated based on population and available historical data. However, renewable energy sources (RES) are intermittent, unpredictable, and environment-dependent. Interestingly, microgrids are becoming smarter but require adequate and an appropriate energy storage system (ESS) to support their smooth and optimal operation. The deep discharge caused by the charging–discharging operation of the ESS affects its state of health, depth of discharge (DOD), and life cycle, and inadvertently reduces its lifetime. Additionally, these parameters of the ESS are directly affected by the varying demand and intermittency of RES. This study presents an assessment of battery energy storage in wind-penetrated microgrids considering the DOD of the ESS. The study investigates two scenarios: a standalone microgrid, and a grid-connected microgrid. The problem is formulated based on the operation cost of the microgrid considering the DOD and the lifetime of the battery. The optimization problem is solved using non-linear programming. The scheduled operation cost of the microgrid, the daily scheduling cost of ESS, the power dispatch by distributed generators, and the DOD of the battery storage at any point in time are reported. Performance analysis showed that a power loss probability of less than 10% is achievable in all scenarios, demonstrating the effectiveness of the study.

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Optimal Sizing of Battery Energy Storage for Grid-Connected and Isolated Wind-Penetrated Microgrid

Cited by 88 publications

References 30 publications

Exploring the Utilization of Energy Storage Systems for Frequency Response Adequacy of a Low Inertia Power Grid

Exploring the Utilization of Energy Storage Systems for Frequency Response Adequacy of a Low Inertia Power Grid

High-Performance 3-Phase 5-Level E-Type Multilevel–Multicell Converters for Microgrids

Techno-Economic Assessment and Operational Planning of Wind-Battery Distributed Renewable Generation System

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