Optimal sizing and location of PV, wind and battery storage for electrification to an island: A case study of Kavaratti, Lakshadweep

Singh, Garima; Baredar, Prashant; Singh, Anand; Kurup, Deepa

doi:10.1016/j.est.2017.04.003

Cited by 61 publications

(14 citation statements)

References 35 publications

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“…Moreover, other technical issues such as the yearly electricity production, the excess energy supplied, the demand covered using renewables, etc., are also studied. Some recent examples about the use of HOMER to specifically design wind‐PV‐battery systems in developing countries can be found in: Bangladesh (Nandi & Ghosh, ), India (Lal, Dash, & Akella, ), Bhutan (Dorji, Urmee, & Jennings, ), Ethiopia (Bekele & Tadesse, ), China (Li et al, ), Nigeria (Olatomiwa, Mekhilef, Huda, & Ohunakin, ), Iran (Gheiratmand, Effatnejad, & Hedayati, ), and Southern India (Singh et al, ). Figure shows an example of a wind‐PV‐battery system modeled using HOMER to supply a set of houses and a school.…”

Section: Systematized Toolsmentioning

confidence: 99%

“…This combinatorial optimization problem becomes even more challenging when including additional equipment for the appropriate functioning of electrification systems. First, wind-PV solutions are generally implemented together with a battery storage to bridge the gap between the electricity production and consumption periods (Li et al, 2013;Singh, Baredar, Singh, & Kurup, 2017). Batteries are loaded when there is production but no consumption (usually daily hours), while they supply electricity in nonproduction periods (usually nonwindy nights).…”

Section: Problem Definitionmentioning

confidence: 99%

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Comparison of various approaches to design wind‐PV rural electrification projects in remote areas of developing countries

Domenech

Ferrer‐Martí

Pastor

2018

WIREs Energy & Environment

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Nowadays, around 1.1 billion people in rural and remote areas of developing countries remain without electricity. Stand-alone projects that combine the wind and photovoltaic generation technologies as well as microgrids and individual supplies for the distribution network are an adequate strategy to reach such isolated regions. However, the design of electrification projects is complex, having to define the best combination of generation and distribution technologies, under a challenging social context and tight technoeconomic resources. In order to ease decision-making, several tools have been developed in the literature and are here reviewed, grouped into three main categories: optimization processes, aiming to minimize project costs subject to technical constraints, through exact or heuristic algorithms; multicriteria processes, using different methods to select the best among a set of predefined scenarios according to economic, technical, social, and environmental criteria; and systematized tools, that have been developed to provide user-friendly interface for their larger dissemination in different regions and contexts. Hence, this paper aims to provide researchers and practitioners an analysis of the advantages and limitations of approaches used over the last decade when addressing the designing of wind and/or photovoltaic electrification projects for extremely poor and isolated areas in developing countries, as well as some areas for further research.

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Section: Systematized Toolsmentioning

confidence: 99%

Section: Problem Definitionmentioning

confidence: 99%

Comparison of various approaches to design wind‐PV rural electrification projects in remote areas of developing countries

Domenech

Ferrer‐Martí

Pastor

2018

WIREs Energy & Environment

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“…It not only absorb intermittency of renewables but can also take advantage of energy arbitrage to generate profit in retail energy markets. Moreover, the reliability, security and efficiency of the system can also be enhanced if BESSs in coordination with DGs are managed effectively [10,11]. The coordinated management of BESSs in ADS can systematically optimize the network operations, make renewable DGs act as dispatchable sources, can help in improving the load deviation index, etc.…”

Section: Introductionmentioning

confidence: 99%

Multiobjective nested optimization framework for simultaneous integration of multiple photovoltaic and battery energy storage systems in distribution networks

Thokar

Gupta

Niazi

et al. 2021

Journal of Energy Storage

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“…A photovoltaic system, a wind turbine, energy storage, and an AC load is a brief description of the hybrid system that has been presented, and where a power converter is connected to each DC-link [2]. Remedial measures for power fluctuations through energy storage have also been investigated in some studies [3][4][5][6][7][8]. Most of the research indicates overcoming fluctuations in the output power of the hybrid system controlled by the state of charge (SOC) of the battery [8].…”

Section: Introductionmentioning

confidence: 99%

Integrated Grid-connected Hybrid Power Generating System with Optimized PLL-based Power Control

Pandey¹,

Sandhu

2021

Walailak J Sci & Tech

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In this paper, grid-connected photovoltaic-wind energy, including a battery energy storage system (BESS) with a novel topology base proposed controller, is presented. The battery can be reflected in a smooth and stable output under variation of weather and load conditions for the grid-connected system. Robust phase-locked loop- (PLL) based hybrid Voltage Source Converter (VSC) controller is designed to enhance power quality (PQ) with mitigating power fluctuation at DC-link by applied BESS on the DC side. The results can be summarized in 2 stages; in the 1st stage, the performance of the designed hybrid system can be analyzed with untuned parameters of the converter, and in the 2nd stage, a simple strategy base proposed controller to improve the operation stability and analyze the PQ of the hybrid power generating (HPG) system is developed. Finally, the proposed hybrid system is modeled in MATLAB/Simulink and the simulation results as obtained are compared with an existing controller. HIGHLIGHTS Performance analysis of design a grid connected hybrid power generating system The system achieved stability and reliability with proposed controllers The presence of a battery, providing smooth movement of the generated power of the system A coordinated controller designed to improve power fluctuation and power quality Highly robust grid-connected HPG system designed using hybrid VSC and bidirectional controller GRAPHICAL ABSTRACT

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Optimal sizing and location of PV, wind and battery storage for electrification to an island: A case study of Kavaratti, Lakshadweep

Cited by 61 publications

References 35 publications

Comparison of various approaches to design wind‐PV rural electrification projects in remote areas of developing countries

Comparison of various approaches to design wind‐PV rural electrification projects in remote areas of developing countries

Multiobjective nested optimization framework for simultaneous integration of multiple photovoltaic and battery energy storage systems in distribution networks

Integrated Grid-connected Hybrid Power Generating System with Optimized PLL-based Power Control

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