@inproceedings{f406845ea476445cb60016ffb28daf7d,
title = "Typhoon Related Cascading Fault Chain Dynamic Evolution Model in Distribution Systems",
abstract = "The resilience of distribution system is severely influenced by the typhoon disaster and secondary disasters such as floods and debris flows. The cascading propagation of typhoon disasters, coupled with the cascading propagation of failures in the distribution system, creates a dual coupling that results in large-scale failures. The key to mitigating losses from typhoon-related cascading failures lies in understanding the potential paths of cascading propagation and taking corresponding measures to cut off the chain propagation in advance. In this paper, we model the typhoon related cascading fault chain mechanism with coupling of distribution systems and typhoon disaster propagation system. The dynamic evolution of typhoon related cascading fault chains is achieved. The effectiveness of the proposed model in mitigating typhoon related failure risk is verified by using the the case of Guangzhou.",
keywords = "cascading failures, distribution system, resilience, typhoon disaster",
author = "Ying Du and Yuntian Chen and Haoran Zhang and Haoran Ji and Chengshan Wang and Jinyue Yan",
note = "Publisher Copyright: {\textcopyright} 2023 IEEE.; 7th IEEE Conference on Energy Internet and Energy System Integration, EI2 2023 ; Conference date: 15-12-2023 Through 18-12-2023",
year = "2024",
month = may,
doi = "10.1109/EI259745.2023.10512631",
language = "English",
series = "2023 IEEE 7th Conference on Energy Internet and Energy System Integration, EI2 2023",
publisher = "Institute of Electrical and Electronics Engineers Inc.",
pages = "2674--2679",
booktitle = "2023 IEEE 7th Conference on Energy Internet and Energy System Integration, EI2 2023",
}