Abstract
Electric vehicles (EVs) are being well known because of no emissions and eco-friendly and consequently these are extremely preferred for transportation. Conversely, the increasing demand for EVs results in several challenges in the maintenance of the distribution system. In general, EVs are often charged in residential areas. Due to this uncoordinated EV charging the low voltage (LV) distribution network has to encounter many challenges to sustain for the new load conditions without any power outages and voltage fluctuations. If this impact of EVs on the distribution network is not measured and rectified properly, it leads to the replacement and reinforcement of the distribution system which is pronounced and tedious. This work proposes Demand Side Management (DSM) technique to decrease the hassle in the residential distribution system embedded with EVs. DSM is the best alternative technique for the distribution system to avoid the most awful power peaks. In this paper, the DSM algorithm is proposed and implemented in two cases—when both household and EV loads are shifted and only EV loads are shifted. The corresponding results are presented. The impact of the uncoordinatedly scheduled EV loads has been compared with the outcomes obtained by employing the DSM strategy to a residential distribution system and are discussed corresponding to the stability of the distribution system and end-user contentment.
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Taylor J, Maitra A, Alexander M, Brooks D, Duvall M (2010) Evaluations of plug-in electric vehicle distribution system impacts. In: Proc. IEEE Power and Energy Society General Meeting, pp 1–6
Hajian M, Zareipour H, Rosehart WD (2009) Environmental benefits of plug in electric vehicles: the case study. In: IEEE Power and Energy Society General Meeting
Clement-Nyns K, Haesen E, Driesen J (2010) The impact of charging plug-in hybrid electric vehicles on a residential distribution grid. IEEE Trans Power Syst 25(1):371–380
Weiller C (2011) Plug-in hybrid electric vehicle impacts on hourly electricity demand in the United States. Energy Policy 39(6):3766–3778
Darabi Z, Ferdowsi M (2011) Aggregated impact of plug-in hybrid electric vehicles on electricity demand profile. IEEE Trans Sustain Energy 2(4):501–508
Badugu J, Obulesu YP, Babu CS (2018) Investigation of THD analysis in residential distribution systems with different penetration levels of electric vehicles. Int J ElectrComputEngSyst (IJECES) 9(1):21–27
Xu L, Marshall M, Dow L (2011) A framework for assessing the impact of plugin electric vehicle to distribution systems. In: Proc. IEEE/PES Power Systems Conference and Exposition, Phoenix, USA
Taylor J et al (2009) Evaluation of the impact of plug-in electric vehicle loading on distribution system operations. In: Proc. IEEE Power and Energy Society General Meeting, Calgary, Canada
Masoum AS et al (2011) Smart load management of plug-in electric vehicles in distribution and residential networks with charging stations for peak shaving and loss minimization considering voltage regulation. IET GenerTransmDistrib 5(8):877–888
Fernandez LP et al (2011) Assessment of the impact of plug-in electric vehicles on distribution networks. IEEE Trans Smart Grid 26(1):206–213
Gong Q, Midlam-Mohler S, Marano V, Rizzoni G (2012) Study of PEV charging on residential distribution transformer life. IEEE Trans Smart Grid 3(1):404–412
Callaway DS, Hiskens IA (2011) Achieving controllability of electric loads. Proc IEEE 99(1):184–199
Stroehle P et al (2011) The impact of charging strategies for electric vehicle on power distribution networks. In: Proc. IEEE International Conference on the European Energy Market, Zagreb, Croatia
Mets K et al (2010) Optimizing smart energy control strategies for plug-in hybrid electric vehicle charging. In: IEEE/IFIP Network Operations and Management Symposium workshops, Osaka, Japan
Ma Z, Callaway DS, Hiskens IA (2013) Decentralized charging control of large populations of plug-in electric vehicles. IEEE Trans Control Syst Technol 21(1):67–78
Narimani MR, Joo J-Y, Crow ML (2015) The effect of demand response on distribution system operation. https://doi.org/10.1109/PECI.2015.7064916
Narimani MR, Joo J-Y, Crow M (2017) Multi-objective dynamic economic dispatch with demand side management of residential loads and electric vehicles. Energies 10(624):1–18
Narimani MR, Joo J-Y, Crow ML (2015) Dynamic economic dispatch with demand side management of individual residential loads. N Am Power Symp NAPS. https://doi.org/10.1109/NAPS.2015.7335144
Badugu J, Obulesu YP, Babu CS (2019) Recharging methods of electric vehicles in residential distribution systems. J EurSystAutom 52(6):617–623
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Badugu, J., Yeddula Pedda, O. & Choppavarapu, S.B. Role of Demand Side Management in Residential Distribution Systems with the Integration of Electric Vehicles. J. Electr. Eng. Technol. 16, 43–54 (2021). https://doi.org/10.1007/s42835-020-00566-8
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DOI: https://doi.org/10.1007/s42835-020-00566-8