A survey of hybrid energy storage systems applied for intermittent renewable energy systems

Mamen, Attapong; Supatti, Uthane

doi:10.1109/ecticon.2017.8096342

Cited by 34 publications

(12 citation statements)

References 5 publications

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“…In addition, a comparative study is performed to demonstrate that an MG with HESS exhibits a better performance than the battery storage system. Reference [41] presents a comparative study on HESS applied to a power system integrated with RES. Reference [42] proposes a model predictive control scheme for an HESS to decrease the charging rate of batteries and maintain the current and voltage of the ultra-capacitor, thus increasing the lifetime of the battery.…”

Section: B Reliability Improvement At Subsystem Levelmentioning

confidence: 99%

Reliability Evaluation and Improvement of Islanded Microgrid Considering Operation Failures of Power Electronic Equipment

Zhong

Wang

Liu

et al. 2020

Journal of Modern Power Systems and Clean Energy

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With the high integration of power electronic technologies in microgrids, the reliability assessment considering power electronic devices has become a hot topic. However, so far no research has considered the impact of the operation failure probability of power electronic equipment on the overall reliability of the microgrid. This paper aims to construct a holistic operation failure rate model of power electronic systems based on the overall reliability assessment of islanded microgrid with high penetration of renewable energy sources (RESs). In addition, to improve the reliability of islanded microgrid, the conventional battery energy storage system (BESS) is replaced by the hybrid energy storage system (HESS). Based on the proposed model, the operation failure models for the power electronic modules in microgrid are built and tested, and then the sensitivity analysis is performed for exploring the influence of various factors on the reliability of the microgrid.

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Section: B Reliability Improvement At Subsystem Levelmentioning

confidence: 99%

Reliability Evaluation and Improvement of Islanded Microgrid Considering Operation Failures of Power Electronic Equipment

Zhong

Wang

Liu

et al. 2020

Journal of Modern Power Systems and Clean Energy

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“…To account for the impact of high penetrations of ES applications, the load profile changes established in Munson's research was applied to the typical profile [4]. These profile augmentations align with changes produced by hybrid PV and ES systems that are utilized to improve grid stability and customer participation [21][22][23][24]. Utilizing time-of-use practices by utility companies such as Pacific Gas & Electric in California that incentivize customers to charge during the period between 11pm and 7am, the impact of EV charging was applied to the typical load profile [25].…”

Section: Historical Profile Vs Flattened Profilementioning

confidence: 99%

Demand Side Management Effects on Substation Transformer Capacity Limits

2019

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In high penetrations, demand side management (DMS) applications augment a substation power transformer’s load profile, which can ultimately affect the unit’s capacity limits. Energy storage (ES) applications reduce the evening peaking demand, while time-of-use rates incentivize end-users to charge electric vehicles overnight. The daily load profile is further augmented by high penetrations of photovoltaic (PV) systems, which reduce the midday demand. The resulting load profile exhibits a more flattened characteristic when compared to the historical cyclic profile. Although the initial impact of PV and ES applications may reduce a unit’s peak demand, long-term system planning and emergency conditions may require operation near or above the nameplate rating. Researchers have already determined that a flattened load profile excessively ages a unit’s dielectrics more rapidly. The focus of this research was to identify an approach for establishing new transformer capacity limits for units serving flattened load profiles with a high harmonic content. The analysis utilizes IEEE standards C57.91 and C57.110 to develop an aging model of a 50 MVA SPX Waukesha transformer. The results establish a guideline for determining transformer capacity limits for normal operation, long-term emergency operation, and short-term emergency operation when serving systems with high penetrations of DSM applications.

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“…Coordination control regarding energy storage devices has been widely developed in solving wind power problems including smoothing the output active power of wind farms, suppressing the shafting oscillation of the DFIG, and assisting the DFIG to realize low-voltage ride through [16,17]. It also provides a new idea for coordinating the DFIG and energy storage to participate in frequency regulation.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, if relying only on an energy storage device or rotor kinetic energy to participate in frequency regulation, it cannot meet the power grid's requirements for a DFIG that simultaneously has a frequency regulation ability and maximum economic benefit. Coordination control regarding energy storage devices has been widely developed in solving wind power problems including smoothing the output active power of wind farms, suppressing the shafting oscillation of the DFIG, and assisting the DFIG to realize low-voltage ride through [16,17]. It also provides a new idea for coordinating the DFIG and energy storage to participate in frequency regulation.…”

Section: Introductionmentioning

confidence: 99%

Inertia and Droop Frequency Control Strategy of Doubly-Fed Induction Generator Based on Rotor Kinetic Energy and Supercapacitor

Yan

Sun

2020

Energies

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The large-scale application of wind power eases the shortage of conventional energy, but it also brings great hidden danger to the stability and security of the power grid because wind power has no ability for frequency regulation. When doubly-fed induction generator (DFIG) based wind turbines use rotor kinetic energy to participate in frequency regulation, it can effectively respond to frequency fluctuation, but has the problems of secondary frequency drop and output power loss. Furthermore, it cannot provide long-term power support. To solve these problems, a coordinated frequency control strategy based on rotor kinetic energy and supercapacitor was proposed in this paper. In order to ensure the DFIG provides fast and long-term power support, a supercapacitor was used to realize the droop characteristic, and rotor kinetic energy was used to realize the inertia characteristic like synchronous generator (SG). Additionally, the supercapacitor is also controlled to compensate for the power dip of the DFIG when rotor kinetic energy exits inertia support to avoid secondary frequency drop. Additionally, a new tracking curve of DFIG rotor speed and output power was adopted to reduce the power loss during rotor speed recovery.

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A survey of hybrid energy storage systems applied for intermittent renewable energy systems

Cited by 34 publications

References 5 publications

Reliability Evaluation and Improvement of Islanded Microgrid Considering Operation Failures of Power Electronic Equipment

Reliability Evaluation and Improvement of Islanded Microgrid Considering Operation Failures of Power Electronic Equipment

Demand Side Management Effects on Substation Transformer Capacity Limits

Inertia and Droop Frequency Control Strategy of Doubly-Fed Induction Generator Based on Rotor Kinetic Energy and Supercapacitor

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