Analysis of Grid-Forming Inverter Controls for Grid-Connected and Islanded Microgrid Integration
Abstract
:1. Introduction
2. Overview of the Support Framework
2.1. GFM Inverter Control Characteristics
2.2. Microgrids in Operation in West Texas
3. Proposed GFM Inverter Control
3.1. GFM Inverter Controller Structure
3.2. GFM Inverter Control Operation Modes
3.2.1. Self—Synchronized Mode
3.2.2. Droop Mode
3.3. Parameter Design Guideline for the GFM Inverter Control Strategy
3.4. Black Start Capability
4. Case Study
Modeling and Analysis
5. Case Studies Results
5.1. Results for Case Study I
5.1.1. Grid-Connected and Islanded Mode
5.1.2. Black Start Capability on Grid-Disconnected Mode
5.2. Results for Case Study II
5.2.1. Performance of Six GFM Inverter Controllers in Grid-Connected and Islanded Modes in the Test Feeder
5.2.2. Black Start Capability of Six GFM Inverter Controllers in the IEEE 123 Test Feeder
6. Discussion
7. Conclusions
- Dependency Pattern Analysis:
- Proposed and systematically evaluated the current state of an electrical grid with a focus on decarbonization using GFM power inverters.
- Quantified the dependency pattern of GFL inverters, providing a clear understanding of their role within the grid.
- Voltage and Frequency Regulation:
- Implemented and assessed a novel adoption model incorporating the latest GFM inverter controller in both small electrical networks and large-scale test feeders.
- Quantitatively demonstrated the model’s efficacy in regulating voltage and frequency in grid-connected and islanded photovoltaic microgrids.
- Fossil Fuel Dependence Reduction:
- Quantified the tangible impact of adopting GFM power inverter controller, showcasing a measurable reduction in dependence on fossil fuels.
- Established the paper’s contribution in steering the grid towards cleaner and more sustainable energy sources.
- Enhanced DER Penetration Index:
- Evaluated, in quantitative terms, how the GFM power inverter controller enhances the penetration index of DERs into the grid.
- Provided numerical insights into the scalability of the adoption model, determining the optimal number of GFM inverters for effective DER integration.
- Future Scaling Plans:
- Outlined a concrete plan for future work, involving the application of the proposed adoption model using 60 GFM power inverter controller.
- Anticipated quantitative outcomes from an additional test feeder grid with more electrical nodes, promising a deeper understanding of scalability and performance.
- Advanced Control Strategies:
- Investigate and implement more advanced control strategies for GFM power inverter controllers beyond the current technology. Explore predictive control methods or artificial intelligence-based approaches to further enhance grid stability and performance.
- Cybersecurity Considerations:
- Address the growing importance of cybersecurity in the context of GFM power inverters. Assess vulnerabilities and propose robust security measures to protect against potential cyberthreats, ensuring the resilience of the grid.
- Integration of Energy Storage:
- Explore the integration of energy storage systems in conjunction with GFM power inverters. Investigate how energy storage technologies can be synergistically employed to enhance grid reliability, mitigate intermittency issues, and support continuous power supply during fluctuations.
- Resilience to Extreme Events:
- Evaluate the resilience of GFM power inverter systems to extreme weather events, natural disasters, and other unforeseen challenges. Develop strategies to ensure grid continuity and rapid recovery in the face of adverse conditions.
- GFM in Hybrid Systems:
- Investigate the role of GFM power inverters in hybrid energy systems, where multiple energy sources (renewable and conventional) coexist. Analyze their performance in complex grid architectures and assess the potential for improved hybrid system optimization.
- Economic Viability and Cost–Benefit Analysis:
- Conduct a comprehensive economic analysis to assess the cost-effectiveness of widespread GFM power inverter adoption. Explore potential incentives, subsidies, and cost savings associated with reduced reliance on traditional power generation methods.
- Real-World Implementation and Case Studies:
- Collaborate with utility providers or relevant stakeholders to implement GFM power inverter systems in real-world scenarios. Conduct case studies to validate the scalability, reliability, and performance under actual grid conditions.
- Policy and Regulatory Considerations:
- Examine the existing policy and regulatory frameworks governing the integration of GFM power inverters. Propose recommendations for policy adjustments or regulatory updates to encourage and facilitate their widespread deployment.
- Quantification of Environmental Impact:
- Quantify the environmental impact of adopting GFM power inverters compared to traditional grid configurations. Assess the reduction in carbon emissions and other environmental benefits associated with the transition to cleaner energy sources.
- Public Awareness and Stakeholder Engagement:
- Develop strategies to enhance public awareness and engage relevant stakeholders in the adoption of GFM power inverters. Investigate public perception, potential barriers, and methods to promote acceptance and collaboration.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Parameters | Values |
---|---|
Voltage (V) | 1 |
ω* (angular frequency) | 377 |
IMAX (maximum current) (A) | 0.5 |
IMIN (minimum current) (A) | 0.033 |
Ke (constant) | 20 |
ω | 5 |
Kω | 5 |
Ksyn (synchronization gain) | 5 |
mi (constant) | 3 |
ni (constant) | 2 |
Apparent power (VA) | 1 |
Aspects | Small Network | IEEE 123 |
---|---|---|
Network size | Small | Large |
Number of inverter controls | 6 | 6 |
Grid complexity | Small network | IEEE 123 |
Available generation resources | Simple | Complex |
Voltage stability | Easy to maintain | More challenging |
System protection | Simplified | Extensive |
Fault analysis | Easier | Comprehensive |
Power flow management | Simpler | Demanding |
Integration with existing systems | Easier | Complex |
System modeling and simulation | Detailed | Extensive |
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Ward, L.; Subburaj, A.; Demir, A.; Chamana, M.; Bayne, S.B. Analysis of Grid-Forming Inverter Controls for Grid-Connected and Islanded Microgrid Integration. Sustainability 2024, 16, 2148. https://doi.org/10.3390/su16052148
Ward L, Subburaj A, Demir A, Chamana M, Bayne SB. Analysis of Grid-Forming Inverter Controls for Grid-Connected and Islanded Microgrid Integration. Sustainability. 2024; 16(5):2148. https://doi.org/10.3390/su16052148
Chicago/Turabian StyleWard, Laura, Anitha Subburaj, Ayda Demir, Manohar Chamana, and Stephen B. Bayne. 2024. "Analysis of Grid-Forming Inverter Controls for Grid-Connected and Islanded Microgrid Integration" Sustainability 16, no. 5: 2148. https://doi.org/10.3390/su16052148
APA StyleWard, L., Subburaj, A., Demir, A., Chamana, M., & Bayne, S. B. (2024). Analysis of Grid-Forming Inverter Controls for Grid-Connected and Islanded Microgrid Integration. Sustainability, 16(5), 2148. https://doi.org/10.3390/su16052148