Power Quality Improvement for Vehicle-to-Grid and Grid-to-Vehicle Technology in a Microgrid

Justin, Fitrahsya; Peter, Geno; Stonier, Albert Alexander; Ganji, Vivekananda

doi:10.1155/2022/2409188

Cited by 18 publications

(10 citation statements)

References 22 publications

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“…To apply this method to the system under study, the mathematical model of the system should be obtained. The model of the power plant is described as 𝐺(𝑠), given by (8).…”

Section: A Kharitonov Theoremmentioning

confidence: 99%

“…The bidirectional flow of energy provided by the vehicle to grid (V2G) technology enables the EVs to act as an energy source [6]. This promising technology strengthens the renewable energy sources adaption [7] and creates numerous benefits such as grid stability, peak load management, power quality [8] and cost-saving for market participants [9]. In V2G, the EVs work as energy routers that transfer the energy from charging stations powered by renewable energy sources (RES) and other sources to the power grid.…”

Section: Introductionmentioning

confidence: 99%

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A Robust Controller Design based on Kharitonov’s Theorem for Frequency Control in an Interconnected Power System

Raouf

Mousavian

2023

EJECE

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The load frequency control of power systems is often carried out using methods that are dependent on the system load and parameters. Therefore, the controller design is not robust in unforeseen cases such an attack on the power system, variations in system parameters, or changes in load. In such methods, there is a need for an attack detection tool, and moreover, the controller parameters need to be adjusted as the load and power system parameters change. In this paper, Kharitonov's theorem was applied to design a robust decentralized load frequency control for a two-area power system in the presence of electric vehicle fleets as a power source that were targeted by a cyberattack. Furthermore, the robustness of the system against system nonlinearities was demonstrated by testing the efficacy of the controller on both linear and nonlinear systems. The controller design was robust such that there was no need to change the gains of the controller even during an attack. This was compared with the performance of controllers designed using GWO algorithm and fuzzy logic that needed retuning for different case studies with different variations in system parameters, load, or inclusion of a cyberattack to the electric vehicle fleets.

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“…To apply this method to the system under study, the mathematical model of the system should be obtained. The model of the power plant is described as 𝐺(𝑠), given by (8).…”

Section: A Kharitonov Theoremmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Robust Controller Design based on Kharitonov’s Theorem for Frequency Control in an Interconnected Power System

Raouf

Mousavian

2023

EJECE

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“…During the coordination and operation of the grid-connected photovoltaic systems, undesirable efects on both the grid and end-user equipment can arise due to power quality disruptions due to the variations in meteorological conditions and the presence of nonlinear loads into the grid [17]. One of the main and worst power quality disturbances is the injection of harmonic distortions of the current by the solar photovoltaic systems and nonlinear loads into the grid [9,18,19], especially in low irradiance conditions [20,21]. Disturbances caused by these harmonic distortions of the current in the electrical grid are overheating of cables, breakdown of capacitors, increase in line losses, power factor degradation, vibration and acoustic noise from motors, malfunction of metering devices, and aging of lines [15,22].…”

Section: Challengesmentioning

confidence: 99%

Backstepping Controller Design for Power Quality Improvement in a Two-Stage Grid-Connected Photovoltaic Systems with LCL Filter

Bendé,

Tchoffo Houdji,

Tchaya

et al. 2023

International Transactions on Electrical Energy Systems

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In a grid-connected photovoltaic system, the quality of energy injected by the photovoltaic system into the grid is directly linked to the topology of the inverter used and to the efficiency of its control technique. This paper addresses this problem for a two-level grid-connected photovoltaic inverter operating under low irradiance conditions. The aim is to reduce the harmonic distortion on the electrical network and therefore improve its power quality. To achieve this goal, a control strategy was set up considering the nonlinearity of the dynamic system, and the high dimension of the system model. Thus, a nonlinear controller designed using the backstepping technique is proposed. The effectiveness of this control strategy was evaluated by simulation in MATLAB/Simulink. Results show that the proposed control technique significantly improves the power quality of the grid-connected photovoltaic system by minimizing the current harmonic distortion rates in low irradiance conditions. The current harmonic distortion rates obtained for solar irradiance of 1000 W/m2, 750 W/m2, 500 W/m2, and 250 W/m2 are 0.48%, 0.78%, 1.22%, and 2.16%, respectively. The power factor is 0.988, and the DC bus voltage is maintained at its reference voltage of 600 V with a very low response time during the transient phases. A comparison of our simulation results with those found in the literature on other control techniques such as proportional-integral-derivative (PID) and synergetic controls shows the efficiency, superiority, and satisfactory performance of the proposed control scheme to minimize harmonic distortion under low irradiance conditions. The robustness and better dynamic performance of the proposed backstepping controller under varying irradiance conditions have also been shown.

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“…Block parking area of the EGSPEC campus as shown in Figure 2. In our previous study, we developed a QDS solar PV using Copper Indium Selenide as the quantum dot absorber [32]. To realise bandgap optimisation, maximum light-harvesting performance, improved photoluminescence, and decreased surface defect rate, the CuInSe 2 is alloying with Zinc sulfide (ZnS) to develop the CISZS quantum dots.…”

Section: Solar Cellmentioning

confidence: 99%

“…Besides, the vehicle charging profile is changing with time to achieve the highest energy yield [23]. Consecutively, the total number of EVs that are charging at a fixed power can be adapted to make total charging power follow the distribution of solar insolation [32]. The sequential recharging methods perform better than concurrent vehicle charging.…”

Section: Related Workmentioning

confidence: 99%

Design and analysis of a photovoltaic‐powered charging station for plug‐in hybrid electric vehicles in college campus

Sureshbabu

Padmanabhan

Subramanian

et al. 2022

IET Electrical Syst in Trans

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Photovoltaic‐powered electric transportation systems are gaining global momentum owing to their superior enactment and zero carbon emissions. With a growing number of electric vehicles (EVs) on the road, implementation of efficient and well‐organised charging stations is extremely indispensable. The authors investigate the feasibility of creating a charging station for plug‐in‐hybrid EVs at an educational institution, E.G.S. Pillay Engineering College, Nagapattinam, Tamil Nadu, India (10°48.2′N, 79°50.1′E). The statistics related to the solar radiations of the Nagapattinam region are employed to find out the energy availability for the EV charging station (EVCS) and the requirement for grid connection. The authors use a hybrid optimisation model for an electric renewable (HOMER) simulator to determine the optimum specification of the proposed EVCS. Also, the authors carry out a techno‐economic study against the specified load requirement to evaluate the potential of the charging station. The solar irradiance data obtained from NASA ground climatology and the solar power dataset of the designated site are used to realise the precise fallouts. The optimisation results provide minimum annual system cost and reliable power to the EVs. Based on these results, an EVCS is erected in the college campus to charge plug‐in hybrid electric vehicles. The established EVCS contains 3 kW EV charger operating as a microgrid and includes nine solar panels with 335 W each, 48 V, 150 Ah specification. The authors use solar photovoltaic (PV) panels using Copper Indium Selenide‐Zinc sulfide (CISZS) quantum dots for maximising energy yield from the EVCS. The authors consider that eight different charging profiles for different months are employed for estimating the solar irradiance probability density in the designated site. From this study, the authors can conclude that Gaussian mixer model (G4) profile is optimum for the Nagapattinam region to install a potential and reliable EVCS.

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Power Quality Improvement for Vehicle-to-Grid and Grid-to-Vehicle Technology in a Microgrid

Cited by 18 publications

References 22 publications

A Robust Controller Design based on Kharitonov’s Theorem for Frequency Control in an Interconnected Power System

A Robust Controller Design based on Kharitonov’s Theorem for Frequency Control in an Interconnected Power System

Backstepping Controller Design for Power Quality Improvement in a Two-Stage Grid-Connected Photovoltaic Systems with LCL Filter

Design and analysis of a photovoltaic‐powered charging station for plug‐in hybrid electric vehicles in college campus

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