Smart City Gnosys
Smart city article details
| Title | Smart City Design Method For Feasible Energy Storage Introduction Toward 100% Renewable Electricity |
|---|---|
| ID_Doc | 50161 |
| Authors | Matsumoto T.; Tanaka K. |
| Year | 2021 |
| Published | 21st IEEE International Conference on Environment and Electrical Engineering and 2021 5th IEEE Industrial and Commercial Power System Europe, EEEIC / I and CPS Europe 2021 - Proceedings |
| DOI | http://dx.doi.org/10.1109/EEEIC/ICPSEurope51590.2021.9584523 |
| Abstract | The necessity to utilize renewable energy sources such as photovoltaic and wind power has infiltrated our society. Batteries play a crucial role in absorbing the fluctuations of these power sources, but few studies focus on the cost of introducing such energy storage. To promote renewable energy sources and achieve a 100% renewable electricity supply (RE100), it is vital to investigate the economic optimal solution to determine who will afford the necessary infrastructure costs. In this paper, a smart city design method for feasible energy storage introduction in achieving RE100 is shown by introducing the notion of external income and developing a detailed simulator. External income is used for calculating the substantial costs of batteries for agents in the smart city such as the power system or electric vehicles (EVs). By sharing the assets in the city, which in this case are batteries, and minimizing the substantial costs, an optimal battery distribution plan is derived. The simulator is run to assess the feasibility of the gained distribution plan as a time series since batteries on EVs cannot be charged or discharged while the vehicles are in use. The results show that a feasible distribution plan is proposed and by minimizing the substantial costs for the smart city, the power system can reduce its necessary battery capacity, leading to a lower cost burden. |
| Author Keywords | Battery Distribution; Electric Vehicles; Energy Storage; External Income; Renewable Energy; Smart City |
Similar Articles
| Id | Similarity | Authors | Title | Published |
|---|---|---|---|---|
40438  | 0.87 | Yabiku T.; Isomura R.; Takahashi H.; Senjyu T. | Optimal Operation And Capacity Plan Of Smart City With A Large Introduction Of Renewable Energy Sources | Asia-Pacific Power and Energy Engineering Conference, APPEEC, 2020-September (2020) |
| 3477 | 0.863 | Shokri M.; Niknam T.; Sarvarizade-Kouhpaye M.; Pourbehzadi M.; Javidi G.; Sheybani E.; Dehghani M. | A Novel Optimal Planning And Operation Of Smart Cities By Simultaneously Considering Electric Vehicles, Photovoltaics, Heat Pumps, And Batteries | Processes, 12, 9 (2024) |
| 39529 | 0.861 | Dincer F.; Ozer E. | Numerical And Experimental Analysis Of Photovoltaic-Integrated Energy Storage For Electric Vehicle Fast Charging | IEEE Access (2025) |
| 51618 | 0.858 | Jiang J.; Li Y.; Li Y.; Li C.; Yu L.; Li L. | Smart Transportation Systems Using Learning Method For Urban Mobility And Management In Modern Cities | Sustainable Cities and Society, 108 (2024) |
| 737 | 0.853 | Coelho, VN; Coelho, IM; Coelho, BN; de Oliveira, GC; Barbosa, AC; Pereira, L; de Freitas, A; Santos, HG; Ochi, LS; Guimaraes, FG | A Communitarian Microgrid Storage Planning System Inside The Scope Of A Smart City | APPLIED ENERGY, 201 (2017) |
| 22278 | 0.852 | Kuhada R.B.; Jha B.K.; Pindoriya N.M.; Ahuja A.; Srivastava A.K. | Efficient Coupling Of Energy Management Devices In Smart Sustainable Cities: A Case Study | 2024 IEEE 4th International Conference on Sustainable Energy and Future Electric Transportation, SEFET 2024 (2024) |
| 26246 | 0.851 | Lone A.H.; Navid T.; Siddiqui A.S. | Feasibility Investigation Of Energy Storage Systems Of Hybrid Power System And Its Benefits To Smart Cities | Lecture Notes in Civil Engineering, 58 (2020) |