Review of Challenges and Opportunities in the Integration of Electric Vehicles to the Grid
Abstract
:1. Introduction
2. Categories of EVs
2.1. BEV
2.2. HEV
2.3. PHEV
2.4. FCEV
3. EV as a Source and Store of Energy-V2G, V2H, V2V
4. Vehicle-to-Grid
5. V2G Opportunities
- A.
- Renewable Energy Storage
- B.
- Peak Shaving and Valley Filling
- C.
- Frequency Regulation
- D.
- Benefits for Existing Power Generation Units
- E.
- Revenue Generation for EV Owners
Aspects | Literature | Area of Study | Remarks |
---|---|---|---|
Environmental | [34,35] | PEV contributing to RES integration | Role of PEVs in integrating intermittent RES in the utility is discussed. |
[35] | VGI impact on RES Integration | Performs a quantitative analysis of VGI aspects. V2G power required for stabilization of RES like solar and wind are calculated. | |
[36] | V2G in a solar- hydrogen microgrid | Studies the effect of V2G technology in a solar-hydrogen microgrid. Results on real world data prove that daily operating costs can be reduced by up to 27.5%. | |
[37] | EV-Wind-Energy Storage Integrated System | Fuzzy Logic Control employed to achieve the energy management between wind, EV, storage system and the utility. | |
Technical | [15,43] | Peak Shaving and Valley Filling | Considering various EV power, battery pack SOC and user constraints, V2G optimization strategies are suggested. |
[49] | Frequency Regulation | Quantitatively analyses the financial aspects of V2G in frequency regulation. | |
[50,52] | Frequency Regulation | Aggregator based control strategies for V2G based regulation is presented. | |
Financial | [53] | Savings on new generation units | Studies the impact of V2G in reducing operation costs and need for new generation units. |
[54] | Savings by optimized charging. | Optimized energy consumption in a Solar incorporated household. | |
[55] | Benefits from Ancillary Services | An optimization framework to maximize the economic benefits from selling ancillary services. |
6. V2G Challenges
- A.
- Battery Degradation
- B.
- Power Electronics—Charging Infrastructure
- C.
- Impacts on Grid Power Quality
Aspects | Literatures | Area of Study | Remarks |
---|---|---|---|
Technical | [56,57,58] | Battery Degradation | Studies the effect of bidirectional power flow on the lifecycle of batteries. |
[59,60,61,62] | Charging Infrastructure | Various Bidirectional topologies and associated Power Electronics challenges | |
[63,64,65,66,67,68,69,70,71] | Grid Power Quality | VGI has a huge impact on the power quality. Issues like voltage instability, harmonics and undesired peaks due to non-coordinated charging are discussed. | |
[94,95,96,97,98,99,100,101,102] | Communication Requirements | Discusses secure protocols for V2G communication. | |
Environment | [103,104,105,106,107,108,109,110,111,112] | Impacts on environment | Environmental Concerns including extraction of rare earth minerals |
Financial | [113] | Initial Cost | Grid Integration capabilities can cause an increase in the initial cost of EVs. |
Socio-Cultural | [39,114] | Market Availability | Availability of GEVs is a concern discussed. |
[115,116,117] | Consumer Interests | Studies the approaches of EV owners towards grid integration of their vehicles. |
Literatures | Optimization Objective | Merits | Remarks |
---|---|---|---|
[75] | Minimize total cost and user discomfort | Cost-savings, flexibility in setting the trade-off between cost and user comfort, peak demand reduction | Centralized Scheduling Technique. Assumes there are no losses in the transmission between EV and residential system. |
[76] | Minimize total cost | Both global and local optimal solutions computed. Local optimal solution gives a very practical and satisfying performance | Distributed Scheduling |
[77] | Minimize total electricity cost of users as well as utility companies | Flattened demand response, reduced bills. Considers renewable generations also | Distributed Scheduling |
[78] | Maximize parking lot revenue & Maximize the number of fully recharged EVs | Considers the mobility aspects of EVs. | Does not consider V2G aspects and Distributed Generation |
[79] | Maximize Aggregator Revenue by optimizing Ancillary Services | Significant profits for aggregator, reduction in consumer cost and peak load reduction | Considerable battery degradation cost |
[80] | Minimize total daily price incurred by CSO | Considers both V2G and G2V operations at an interval of at least 30 min | - |
[81] | Minimize Average time cost, Minimize Average Charging Expense, Minimize the difference between final and expected SoC | Less run time cost | Charging scheduling carried out from the viewpoint of an EV-hailing company |
Literatures | AI Technique Employed | Performance Metric | Results |
---|---|---|---|
[86] | Support Vector | MAPE, RMSE | Charging Load in kW is forecasted. MAPE: 3.69%, RMSE: 50.13 kW |
[87] | Linear Regression, SVM, Random Forest, XGBoost | R2, RMSE | Charging Demand in kWh is predicted. XGBoost performs better with R2: 0.519, RMSE: 6.68 kWh |
[88] | Multivariate LSTM | MAE, RMSE | Charging Power in kW is predicted. LSTM with calendar and weather features has the leading performance with MAE of 0.89 kW and RMSE of 1.92 kW |
[89] | Multiple Linear Regression, Quantile Regression, SVM, LSTM, LSTM-Bayesian Deep Learning (LSTM-BDL) | RMSE, MAE, R2 | Charging Load in kWh is forecasted. LSTM-BDL with MAE: 2.78 kWh, RMSE: 4.367 kWh and R2: 0.918 outperforms the other models. |
[90] | Transformer model | RMSE | Charging demand in kW is predicted. RMSE: 0.085 kW, 0.096 kW, and 0.112 kW for forecasting demand ahead of 30 days, 60 days and 90 days, respectively |
- D.
- Communication
- E.
- Environmental Concerns
- F.
- Initial Cost
- G.
- Availability and Suitability of EVs
- H.
- Non-cooperation from EV owners
7. Current Policies
8. Conclusions
9. Future Directions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Vishnu, G.; Kaliyaperumal, D.; Jayaprakash, R.; Karthick, A.; Kumar Chinnaiyan, V.; Ghosh, A. Review of Challenges and Opportunities in the Integration of Electric Vehicles to the Grid. World Electr. Veh. J. 2023, 14, 259. https://doi.org/10.3390/wevj14090259
Vishnu G, Kaliyaperumal D, Jayaprakash R, Karthick A, Kumar Chinnaiyan V, Ghosh A. Review of Challenges and Opportunities in the Integration of Electric Vehicles to the Grid. World Electric Vehicle Journal. 2023; 14(9):259. https://doi.org/10.3390/wevj14090259
Chicago/Turabian StyleVishnu, Gayathry, Deepa Kaliyaperumal, Ramprabhakar Jayaprakash, Alagar Karthick, V. Kumar Chinnaiyan, and Aritra Ghosh. 2023. "Review of Challenges and Opportunities in the Integration of Electric Vehicles to the Grid" World Electric Vehicle Journal 14, no. 9: 259. https://doi.org/10.3390/wevj14090259
APA StyleVishnu, G., Kaliyaperumal, D., Jayaprakash, R., Karthick, A., Kumar Chinnaiyan, V., & Ghosh, A. (2023). Review of Challenges and Opportunities in the Integration of Electric Vehicles to the Grid. World Electric Vehicle Journal, 14(9), 259. https://doi.org/10.3390/wevj14090259