Power Side Risk Assessment of Multi-Energy Microgrids Considering Risk Propagation between Interconnected Energy Networks
Abstract
:1. Introduction
2. Energy Conversion Model Based Considering Risk Propagation
2.1. Energy Conversion Model of Energy Coupling Equipment
2.1.1. Gas Turbine
2.1.2. Turbine
2.1.3. Combined Heat and Power Equipment
2.1.4. Heat Pump
2.2. System Level Energy Conversion Model Considering Risk Propagation
3. Energy Flow Distribution Based Risk Analysis
4. Risk Assessment of Multi-Energy Microgrids
4.1. Risk Index System and Risk Quantification
4.1.1. Voltage Deviation
4.1.2. Branch Flow Limit Violation
4.1.3. Power Shortage
4.1.4. Gas Supply Shortage
4.1.5. Heat Supply Shortage
4.2. The Process of Risk Assessment
5. Case Study
6. Conclusions
- Compared with merely considering the operation of the power side, all levels of line flow violation risks increase when the interaction with the gas network and the heat network is considered.
- The power side nodal voltage violation risk considering the gas network and the heat network is more severe than when only considering the power side. Under different risk factors, when considering the gas network and the heat network, the probability of nodal voltage violation risk becomes greater.
- The risk assessment method proposed in this paper can effectively take the impact of different energy networks into account, and the assessment results are consistent with the actual situation. The risk transfer effect between various energy networks has an extremely important impact on the operation of the multi-energy microgrid, and thus, it is unignorable.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Risk Level | Level 3 Risk | Level 2 Risk | Level 1 Risk | |
---|---|---|---|---|
Risk Index | ||||
Voltage deviation | 2~5% | 5~10% | >10% | |
Branch flow limit violation | 90~100% | 100~120% | >120% | |
Power shortage | 2~5% | 5~10% | >10% | |
Gas supply shortage | 10~15% | 15~20% | >20% | |
Heat supply shortage | 1.5~2.5% | 2.5~3.5% | >3.5% | |
Risk occurrence probability | <10−5 | 10−5~10−4 | >10−4 |
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Ma, Y.; Chen, Y.; Chang, Z.; Li, Q.; Liu, H.; Wei, Y. Power Side Risk Assessment of Multi-Energy Microgrids Considering Risk Propagation between Interconnected Energy Networks. Energies 2023, 16, 7525. https://doi.org/10.3390/en16227525
Ma Y, Chen Y, Chang Z, Li Q, Liu H, Wei Y. Power Side Risk Assessment of Multi-Energy Microgrids Considering Risk Propagation between Interconnected Energy Networks. Energies. 2023; 16(22):7525. https://doi.org/10.3390/en16227525
Chicago/Turabian StyleMa, Yan, Yumin Chen, Zhengwei Chang, Qian Li, Hongli Liu, and Yang Wei. 2023. "Power Side Risk Assessment of Multi-Energy Microgrids Considering Risk Propagation between Interconnected Energy Networks" Energies 16, no. 22: 7525. https://doi.org/10.3390/en16227525
APA StyleMa, Y., Chen, Y., Chang, Z., Li, Q., Liu, H., & Wei, Y. (2023). Power Side Risk Assessment of Multi-Energy Microgrids Considering Risk Propagation between Interconnected Energy Networks. Energies, 16(22), 7525. https://doi.org/10.3390/en16227525