Smart Control Strategies for Primary Frequency Regulation through Electric Vehicles: A Battery Degradation Perspective

Nowadays, due to the decreasing use of traditional generators in favor of renewable energy sources, power grids are facing a reduction of system inertia and primary frequency regulation capability. Such an issue is exacerbated by the continuously increasing number of electric vehicles (EVs), which results in enforcing novel approaches in the grid operations management. However, from being an issue, the increase of EVs may turn to be a solution to several power system challenges. In this context, a crucial role is played by the so-called vehicle-to-grid (V2G) mode of operation, which has the potential to provide ancillary services to the power grid, such as peak clipping, load shifting, and frequency regulation. More in detail, EVs have recently started to be effectively used for one of the most traditional frequency regulation approaches: the so-called frequency droop control (FDC). This is a primary frequency regulation, currently obtained by adjusting the active power of generators in the main grid. Because to the decommissioning of traditional power plants, EVs are thus recognized as particularly valuable solutions since they can respond to frequency deviation signals by charging or discharging their batteries. Against this background, we address frequency regulation of a power grid model including loads, traditional generators, and several EVs. The latter independently participate in the grid optimization process providing the grid with ancillary services, namely the FDC. We propose two novel control strategies for the optimal control of the batteries of EVs during the frequency regulation service. On the one hand, the control strategies ensure re-balancing the power and stabilizing the frequency of the main grid. On the other hand, the approaches are able to satisfy different types of needs of EVs during the charging process. Differently from the related literature, where the EVs perspective is generally oriented to achieve the optimal charge level, the proposed approaches aim at minimizing the degradation of battery devices. Finally, the proposed strategies are compared with other state-of-the-art V2G control approaches. The results of numerical experiments using a realistic power grid model show the effectiveness of the proposed strategies under the actual operating conditions.

[1]  Alain Tchagang,et al.  V2B/V2G on Energy Cost and Battery Degradation under Different Driving Scenarios, Peak Shaving, and Frequency Regulations , 2020, World Electric Vehicle Journal.

[2]  Jianxiao Zou,et al.  Dispatching strategies of electric vehicles participating in frequency regulation on power grid: A review , 2017 .

[3]  Nikolaos G. Paterakis,et al.  Optimizing the operation of energy storage using a non-linear lithium-ion battery degradation model , 2020, Applied Energy.

[4]  Giuseppe Coviello,et al.  DDS-PLL Phase Shifter Architectures for Phased Arrays: Theory and Techniques , 2019, IEEE Access.

[5]  A. Oudalov,et al.  Optimizing a Battery Energy Storage System for Primary Frequency Control , 2007, IEEE Transactions on Power Systems.

[6]  P. G. Vidal,et al.  Primary frequency control and dynamic grid support for vehicle-to-grid in transmission systems , 2018, International Journal of Electrical Power & Energy Systems.

[7]  Michel Noussan,et al.  Impact of Grid-Scale Electricity Storage and Electric Vehicles on Renewable Energy Penetration: A Case Study for Italy , 2019, Energies.

[8]  Remus Teodorescu,et al.  Operation of a Grid-Connected Lithium-Ion Battery Energy Storage System for Primary Frequency Regulation: A Battery Lifetime Perspective , 2017, IEEE Transactions on Industry Applications.

[9]  Stephan Koch,et al.  Provision of Load Frequency Control by PHEVs, Controllable Loads, and a Cogeneration Unit , 2011, IEEE Transactions on Industrial Electronics.

[10]  Filipe Joel Soares,et al.  Integration of Electric Vehicles in the Electric Power System , 2011, Proceedings of the IEEE.

[11]  Zechun Hu,et al.  Decentralized Vehicle-to-Grid Control for Primary Frequency Regulation Considering Charging Demands , 2013, IEEE Transactions on Power Systems.

[12]  Andreas Jossen,et al.  Fundamentals of Using Battery Energy Storage Systems to Provide Primary Control Reserves in Germany , 2016 .

[13]  Jianxiao Zou,et al.  An optimal dispatching strategy for V2G aggregator participating in supplementary frequency regulation considering EV driving demand and aggregator’s benefits , 2017 .

[14]  Jin-Young Choi,et al.  Optimal Scheduling and Real-Time State-of-Charge Management of Energy Storage System for Frequency Regulation , 2016 .

[15]  Yi Huang,et al.  iParker—A New Smart Car-Parking System Based on Dynamic Resource Allocation and Pricing , 2016, IEEE Transactions on Intelligent Transportation Systems.

[16]  Pao-Yu Oei,et al.  Exploring Energy Pathways for the Low-Carbon Transformation in India—A Model-Based Analysis , 2018, Energies.

[17]  Josep M. Guerrero,et al.  Coordination of EVs Participation for Load Frequency Control in Isolated Microgrids , 2017 .

[18]  Milos Cvetkovic,et al.  Ancillary Services Market Design in Distribution Networks: Review and Identification of Barriers , 2020, Energies.

[19]  Ujjwal Datta,et al.  Battery Energy Storage System for Aggregated Inertia-Droop Control and a Novel Frequency Dependent State-of-Charge Recovery , 2020 .

[20]  Matthieu Dubarry,et al.  Durability and Reliability of EV Batteries Under Electric Utility Grid Operations: Impact of Frequency Regulation Usage on Cell Degradation , 2020, ECS Meeting Abstracts.

[21]  Birgitte Bak-Jensen,et al.  Integration of Vehicle-to-Grid in the Western Danish Power System , 2011, IEEE Transactions on Sustainable Energy.

[22]  Akihiko Yokoyama,et al.  Autonomous Distributed V2G (Vehicle-to-Grid) Satisfying Scheduled Charging , 2012, IEEE Transactions on Smart Grid.

[23]  Mariagrazia Dotoli,et al.  Distributed control of electric vehicle fleets considering grid congestion and battery degradation , 2020, Internet Technol. Lett..

[24]  Yufei Tang,et al.  Load Frequency Control in Isolated Micro-Grids with Electrical Vehicles Based on Multivariable Generalized Predictive Theory , 2015 .

[25]  Ahmad H. Besheer,et al.  Primary Frequency Response Enhancement for Future Low Inertia Power Systems Using Hybrid Control Technique , 2018 .

[26]  Remus Teodorescu,et al.  Field Experience from Li-Ion BESS Delivering Primary Frequency Regulation in the Danish Energy Market , 2014 .

[27]  Gang Mu,et al.  A cost accounting method of the Li-ion battery energy storage system for frequency regulation considering the effect of life degradation , 2018 .

[28]  Taisuke Masuta,et al.  Supplementary Load Frequency Control by Use of a Number of Both Electric Vehicles and Heat Pump Water Heaters , 2012, IEEE Transactions on Smart Grid.

[29]  Taher Niknam,et al.  A new load frequency control strategy for micro-grids with considering electrical vehicles , 2017 .

[30]  Sekyung Han,et al.  Economic Feasibility of V2G Frequency Regulation in Consideration of Battery Wear , 2013 .

[31]  Ertuğrul Çam,et al.  Use of the Genetic Algorithm-Based Fuzzy Logic Controller for Load-Frequency Control in a Two Area Interconnected Power System , 2017 .