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Keywords
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Integrated energy systems may simultaneously be exposed to multiple high impacts with low probability events. Its consequents may overlap with different hazards and lead to temporal or permanent damages for infrastructures components. This paper studies the resiliency of integrated energy systems, including interdependence natural gas and electricity networks affected by multi-hazards such as hurricane and earthquakes. The impacts of hazard levels on component and system performance are analyzed. Based on the results, the simultaneous occurrence of the different hazards can boost the impact of a single hazard on integrated energy systems infrastructures.
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Abstract
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Integrated energy systems may simultaneously be exposed to multiple high impacts with low probability events. Its consequents may overlap with different hazards and lead to temporal or permanent damages for infrastructures components. This paper studies the resiliency of integrated energy systems, including interdependence natural gas and electricity networks affected by multi-hazards such as hurricane and earthquakes. The impacts of hazard levels on component and system performance are analyzed. Based on the results, the simultaneous occurrence of the different hazards can boost the impact of a single hazard on integrated energy systems infrastructures.
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