Electric Vehicle Battery Storage Concentric Intelligent Home Energy Management System Using Real Life Data Sets
Abstract
:1. Introduction
2. State of the Art Literature Review
Our Contribution
- 1.
- Most significantly, this paper is written keeping in view a call from a special issue of Energies on the subject “Demand Side Management of Distributed and Uncertain Flexibilities”, utilizing real-life yearly data sets of household demands, EV driving patterns, and EV battery (dis)charging patterns to demonstrate the actual iEMS capabilities of the proposed system model. To the best of our knowledge, this is the first paper written introducing energy management system strategy by utilizing the above mentioned explicit data sets.
- 2.
- Introducing a comprehensive converter-based nanogrid model. This model combines real-world data sets and operating limitations for conventional and renewable energy power sources. The model also includes lifespan deterioration of the EV storage’s capacity given in Appendix B. Data sets are re-processed (i.e., Appendix A) to be used in MATLAB.
- 3.
- Adopting a two-stage co-simulation framework to implement a multi-time scale iEMS and control strategy. A robust decision-based operation strategy is proposed to utilize the least expensive energy supply sources and to maximize the consumer’s satisfaction level.
- 4.
- Proposing a computationally efficient mixed integer rule-based sliding horizon dynamical algorithm to tackle the prediction uncertainties and to make cost effective scheduling decisions for supply sources. In addition, comparing daily and seasonal scheduling decisions for various supply sources in the first stage.
3. System Architecture
3.1. Home Area Power Network Architecture
3.2. Battery Degradation Model
3.3. Entities Cost Modeling
4. Problem Formulation & Numerical Solution
4.1. Algorithms and Implementation
- 1.
- Scheme 1: Conventional rule-based strategy involves only the EV storage and grid energy supply (Conv-EG).
- 2.
- Scheme 2: Conventional model predictive rule-based strategy involves PV supply along with EV storage and grid energy supply (Conv-PEG).
- 3.
- Scheme 3: Proposed Model predictive intelligent energy management system (MP-iEMS).
4.1.1. Scheme 1: Conv-EG
4.1.2. Scheme 2: Conv-PEG
4.1.3. Scheme 3: MP-iEMS
- 1.
- Case 1: & & & :
- 2.
- Case 2: & & & :
- 3.
- Case 3: & & & :
- 4.
- Case 4: & & & :
- 5.
- Case 5: & & & :
- 6.
- Case 6: & & & :
Case I
Case II
Case III
Case IV
Case V
Case VI
4.2. Evaluation Indices
PV Utilization Factor ()
PV Penetration Level ()
Grid Utilization Factor ()
Grid Penetration Level ()
EV Storage Utilization Factor ()
EV Storage Penetration Level ()
Degree of Self-Sufficiency ()
5. Case Study & Simulation Results
5.1. Data Preparation
5.2. Comparative Analysis of Power Scheduling Schemes
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Appendix A. Data Preparation
- Fast charging between 0–35% of SOC and;
- Decreased charging between 35–100% of SOC.
Appendix B. Battery Degradation Model
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Ref #. | Objectives | Technique(s) | Scheduling Entities | Dynamic EV Charging | Battery Degradation | Cost Reduction | Energy Balancing | Limitation(s) | ||
---|---|---|---|---|---|---|---|---|---|---|
Grid | PV | EV | ||||||||
[3] | According to this study, using battery storage for PV and EV hosting capacity optimization as well as grid voltage maintenance was critical. | Model Predictive Control | ✓ | ✓ | ✓ | ✗ | ✗ | ✓ | ✗ | The case study is fictitious. It was confirmed that the generation of DG and PVs exceeds the consumption of the load and EV charging and that the ESS maintains all bus voltages within the permitted limit. |
[22] | The purpose of this study is to propose a methodology for simulating plug-in electric vehicle charging in order to quantify the impact of this type of load on power systems. | Monte Carlo Simulation | ✓ | ✓ | ✓ | ✗ | ✗ | ✗ | ✓ | The proposed technique focused on transmission networks and provides a deterministic representation of the EV charge distribution across the network. It made no reference to any real-world data collection. |
[23] | Dynamic programming is used to govern the charging (G2V) and discharging of the storage device (V2G) in order to extend the life of the battery and minimizing grid reliance. | Adaptive Dynamic Programming | ✓ | ✓ | ✓ | ✓ | ✗ | ✗ | ✓ | The model was confined to battery storage alone and did not include specific information about load needs. Additionally, constraint functions that do not have an exact model of the device were estimated. |
[24] | The author discussed the challenge of minimizing the total of energy and thermal discomfort costs. The suggested system stabilized developing queues for indoor temperature control, electric car charging, and energy storage. | Lyapunov Optimization | ✓ | ✓ | ✓ | ✗ | ✗ | ✓ | ✓ | The energy demand model was limited in scope since it examines only thermal loads. Additionally, the algorithm was incapable of addressing the issue of peak forms. |
[25] | Maximizing the utility sums of residential customers while keeping energy consumption costs in check is explored in this article. It is decentralized, but it protected the residents’ private information at the same time. | Generalized Benders Decomposition algorithm | ✓ | ✓ | ✗ | ✗ | ✗ | ✓ | ✗ | The technique might not operate successfully if the homes’ demand information is inaccurate. It also did not address the peak-to-average power demand ratio (PAR). |
[20] | A two-stage optimization approach is devised, in which peak reduction signals are discovered and their flexibility provision determined by aggregating individual users’ energy use histories. | Mixed Integer Linear Programming | ✓ | ✓ | ✗ | ✗ | ✓ | ✓ | ✗ | This study made no allowance for incentives for postponing loading or for the penalty cost associated with reducing customer suffering. |
[26] | The control method outlined in this work is intended to address power factor concerns associated with EV charging stations while still allowing for full PV generation. | Optimal Dynamic Programming | ✓ | ✓ | ✓ | ✗ | ✗ | ✓ | ✗ | The effort was done to boost the power factor. The battery management system was designed to adjust only the power factor, ignoring the demand- supply balance and ignoring real-world data. |
[27] | This study examines the influence of dynamic energy pricing and home PV system incentives on EV charging behavior, grid load, and household economics. | Mixed Integter Linear Programming | ✓ | ✓ | ✓ | ✓ | ✗ | ✓ | ✗ | The battery deterioration model outlined in this study is critical to the model’s success. Realistic information about the actions of prosumers was also not included. |
[15] | The suggested technique uses time-of-use pricing, time-varying residential power demand, solar generating profiles, and EV specifications to reduce electricity prices and flatten the load curve. | Rule Based Optimization | ✓ | ✓ | ✓ | ✗ | ✗ | ✗ | ✓ | The battery degradation model is an important factor in this study’s model. However, realistic data sets on prosumer actions were not included in the investigation. |
[28] | The PV produced more energy than needed to meet load demands and charge the batteries. Battery discharge happens when PV panel output falls short of load needs. The controller prevented over(dis)charging. | Fuzzy Logic Design | ✓ | ✓ | ✗ | ✗ | ✗ | ✗ | ✓ | The focus of this paper was solely on the supply and demand for energy. Cost reduction and customer satisfaction were not adequately addressed. |
Parameters | Value | Parameters | Value | Parameters | Value |
---|---|---|---|---|---|
20 kW | 15 min | ||||
110 kWh | 1 s | ||||
120 kWh | [42] | 130 $/MWh | Figure A4 | ||
1 kWh | [42] | 201 $/MWh | Figure A4 |
Parameters | Value | Unit | Parameters | Value | Unit |
---|---|---|---|---|---|
6684.8 | 39,146 | J/mol | |||
1.368 | 1/Ah | 39,500 | J/mol | ||
R | 8.314 | J/K·mol | - | ||
F | 96,485.3 | C/mol | - |
Scheme/Parameters | |||||||
---|---|---|---|---|---|---|---|
Scheme 1: (Conv-EG) | 0 | 0.0307 | 0.9597 | 0 | 0.8598 | 0.4198 | 0.1402 |
Scheme 2: (Conv-PEG) | 0.6634 | 0.0268 | 0.9598 | 0.1129 | 0.7639 | 0.4098 | 0.2361 |
Scheme 3: (MP-iEMS) | 0.6272 | 0.0269 | 0.9579 | 0.1175 | 0.8447 | 0.3533 | 0.1553 |
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Minhas, D.M.; Meiers, J.; Frey, G. Electric Vehicle Battery Storage Concentric Intelligent Home Energy Management System Using Real Life Data Sets. Energies 2022, 15, 1619. https://doi.org/10.3390/en15051619
Minhas DM, Meiers J, Frey G. Electric Vehicle Battery Storage Concentric Intelligent Home Energy Management System Using Real Life Data Sets. Energies. 2022; 15(5):1619. https://doi.org/10.3390/en15051619
Chicago/Turabian StyleMinhas, Daud Mustafa, Josef Meiers, and Georg Frey. 2022. "Electric Vehicle Battery Storage Concentric Intelligent Home Energy Management System Using Real Life Data Sets" Energies 15, no. 5: 1619. https://doi.org/10.3390/en15051619
APA StyleMinhas, D. M., Meiers, J., & Frey, G. (2022). Electric Vehicle Battery Storage Concentric Intelligent Home Energy Management System Using Real Life Data Sets. Energies, 15(5), 1619. https://doi.org/10.3390/en15051619