Empowering smart grid: A comprehensive review of energy storage technology and application with renewable energy integration

Tan, Kang Miao; Babu, Thanikanti Sudhakar; Ramachandaramurthy, Vigna K.; Kasinathan, Padmanathan; Solanki, Sunil Govinda; Raveendran, Shangari K.

doi:10.1016/j.est.2021.102591

Cited by 372 publications

(115 citation statements)

References 141 publications

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“…Pore engineering is an essential component of the electrolyte fabrication process as it directly relates to ionic conductivity, with fine pores in poly(vinylidene fluoride‐ co ‐hexafluoropropylene) (PVdF‐HFP) based electrolytes enabling greater amounts of entrapped liquid electrolyte prior to the formation of the gel‐like polymer electrolyte. [69] The other important external component is the fillers that help improve the mechanical strength (from 3.1 MPa tensile strength to 9.86 MPa, [70] ) and ionic conductivity (from 0.22 mS cm −1 to 0.68 mS cm −1 , [71] ). Various processing strategies have been implemented with polymer electrolyte assemblies: solution casting, [66] phase separation, [67] electro‐spinning [68] and in‐situ polymerization, [72] shown in Figure 2 .…”

Section: Combining and Mixingmentioning

confidence: 99%

“…The widespread adoption of renewable energy sources is complicated by inconsistent availability of wind and sun radiation, presenting a need for high volume energy storage before fossil fuel and nuclear generators can be fully replaced. [1] In the current competition to meet the accelerating demand for energy storage technologies, sodium‐ion (Na‐ion) battery development lags that of lithium ion (Li‐ion), Zn‐Air, and redox flow batteries. [2] Na‐ion batteries have several advantages that make them worth pursuing, and they could avoid supply constraints and cost increases as the demand for Li‐ion batteries increases exponentially with the move to electrify vehicle fleets across the world.…”

Section: Introductionmentioning

confidence: 99%

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Process‐Structure‐Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review

Sawhney

Wahid²,

Griffin

et al. 2022

ChemPhysChem

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Before the viability of a cell formulation can be assessed for implementation in commercial sodium ion batteries, processes applied in cell production should be validated and optimized. This review summarizes the steps performed in constructing sodium ion (Na‐ion) cells at research scale, highlighting parameters and techniques that are likely to impact measured cycling performance. Consistent process‐structure‐performance links have been established for typical lithium‐ion (Li‐ion) cells, which can guide hypotheses to test in Na‐ion cells. Liquid electrolyte viscosity, sequence of mixing electrode slurries, rate of drying electrodes and cycling characteristics of formation were found critical to the reported capacity of laboratory cells. Based on the observed importance of processing to battery performance outcomes, the current focus on novel materials in Na‐ion research should be balanced with deeper investigation into mechanistic changes of cell components during and after production, to better inform future designs of these promising batteries.

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Section: Combining and Mixingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Process‐Structure‐Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review

Sawhney

Wahid²,

Griffin

et al. 2022

ChemPhysChem

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“…However, there are projects in progress related to renewable energy integration [55], green-house gases reduction [56] and rural electrification [57]. Finally, the wind energy resources are known for their non-dispatchability and poor load following, which add challenges in the forecasting [58], operation of the transmission systems and planning future Energy Storage Systems (ESS) [59].…”

Section: The Wind Power Dynamics In the Bolivian Andesmentioning

confidence: 99%

Wind Power Potential in Highlands of the Bolivian Andes: A Numerical Approach

Mamani

Hendrick

2022

Energies

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Wind resource assessment is a key factor for the development and implementation of wind farms with the purpose of generating green, eco-friendly and clean electricity. The Bolivian Andes, as a large dry region, represents an important source of renewable energy. However, the altitude and high wind energy resources of the Bolivian Andes require further knowledge and understanding of the wind energy resources. In this study, the GWA have been used to determine the total area available to install wind farms considering the protected areas, roads, cities and transmission lines. In addition, the Weather Research and Forecasting (WRF v3.8.1) model is employed to complement the results of the GWA based on the validation of WRF simulations with measurements from Qollpana wind farm. The main purpose is to estimate the wind power potential along the Bolivian Andes and its variability in time. The wind power simulations have been compared with the power generated by the Qollpana wind farm to verify the WRF’s performance. The wind power potential in the highlands of the Bolivian Andes could reach between 225 (WRF) and 277 (GWA) GW, distributed mainly over the Western and Eastern Cordillera of the Altiplano.

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“…A comprehensive review for empowering smart grids by energy storage system and application with integration of renewable energy was investigated in [9]. Integration of SPV systems in commercial and industrial utilization was reviewed in [10].…”

Section: Literature Reviewmentioning

confidence: 99%

Optimal planning of solar photovoltaic and battery storage for electric vehicle owner households with time‐of‐use tariff

Merrington

Khezri

Mahmoudi

2021

IET Generation Trans & Dist

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This paper presents a practical optimal planning of solar photovoltaic (SPV) and battery storage system (BSS) for electric vehicle (EV) owner households with time of use (TOU) electricity pricing. The main aim of the optimisation problem is to minimize the Cost of Electricity (COE) while satisfying the design constraints over 20‐year project lifespan. Novel rule‐based home energy management systems are created to investigate the optimal sizing of two system configurations: (1) SPV‐EV, and (2) SPV‐BSS‐EV. The arrival and departure times of the EV's availability, as well as its initial state‐of‐charge are incorporated into the energy management system via stochastic functions. Sensitivity analyses of the feed in tariff, grid constraint, electricity demand, and available rooftop area are provided to investigate the variations of cost of electricity and capacities of SPV and BSS. From the study results, practical guidelines for grid‐connected households, based on TOU energy pricing, are provided to select the optimal capacity of SPV and BSS to accommodate the existing EV. The optimisation method is general and applicable to any household owning EV; however, in this study realistic data of solar insolation and temperature as well as household electricity demand and electricity prices are implemented for South Australia. Uncertainty analysis is investigated based on 10‐year real and stochastic data to prove the optimal results. It is found that the optimal configuration for a typical SA household utilising TOU pricing with an EV requires a 10‐kW SPV with a 10‐kWh capacity of BSS.

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Empowering smart grid: A comprehensive review of energy storage technology and application with renewable energy integration

Cited by 372 publications

References 141 publications

Process‐Structure‐Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review

Process‐Structure‐Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review

Wind Power Potential in Highlands of the Bolivian Andes: A Numerical Approach

Optimal planning of solar photovoltaic and battery storage for electric vehicle owner households with time‐of‐use tariff

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