Journal
IEEE TRANSACTIONS ON POWER DELIVERY
Volume 37, Issue 4, Pages 2684-2692Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TPWRD.2021.3114279
Keywords
Substations; Analytical models; Directed graphs; Earthquakes; Electronics packaging; MIMO communication; Computational modeling; Multi-input-multi-output system (MIMOS); substation; directed graph logic model; Monte Carlo simulation; performance indicator; vulnerability; earthquake
Categories
Funding
- National Natural Science Foundation of China [51878508]
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This study presents a flow-based analysis model integrating the flow block diagram and state tree method to evaluate the earthquake-resistance capability of a complex multi-input-multi-output system substation. The developed directed graph logic system analysis model provides reliability indicators associated with the overall system. A case study on a practical substation demonstrates the potential of the analysis results in assisting decision-makers in seismic optimization.
To evaluate the earthquake-resistance capability of an entire substation, which is a complex multi-input-multi-output system (MIMOS) composed of many various types of electrical equipment interconnected by conductors, a flow-based analysis model integrating the merit of the flow block diagram and state tree method was introduced. Two performance indicators of a substation were defined from different stakeholders, one is the expected total power transmission capacity and the other is the power accessibility to the targeted users from the substation. And directed graph logic system analysis models were developed on the Simulink platform based on the original internal logic relationship among distributed components and the power delivery path in the substation with different function types. Afterward, the defined reliability indicators associated with the overall system under a certain seismic intensity level can be obtained by combining the seismic vulnerability curve at the equipment level through the Monte Carlo simulation method. The feasibility and accuracy of the proposed system vulnerability analysis model were verified by comparison with the analytical solution through the illustrative simple MIMOS. Then A case study on a practical 220/110 kV substation was conducted, the analysis results can assist decision-makers in seismic optimization of different retrofitting measures and distribution plans for substations.
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