Resilience and Critical Power System Infrastructure

Resilience and Critical Power System Infrastructure

Resilience against infrastructure failure is essential for ensuring the health and safety of communities during and following natural hazard situations. Understanding how natural hazards impact society in terms of economic cost, recovery time, and damages to critical infrastructure is essential for developing robust approaches to increasing resilience. Identifying specific vulnerabilities allows for better communication, planning, and situation-specific interventions. This is particularly relevant in areas recovering from a natural hazard that have the opportunity to build back their infrastructure, and for those currently planning infrastructure expansions. This study considers recent hurricanes, earthquakes, droughts, heat waves, extreme wind and rainfall events, ice and thunder storms as well as wildfires. For many of these, data are available for the same type of hazard in different geographies which provides information not only on specific vulnerabilities, but whether the impacts are location dependent. Where available, specific design considerations, cost information for repairs, and the recommendations for 'building back better' are presented. Above-ground transmission systems were the most commonly affected power system component, with fuel and maintenance supply chains representing a major vulnerability for isolated regions and islands. Generation systems were most commonly affected when a hazard exceeded design limits, particularly in relation to water temperature or wind speeds. Institutional capabilities are important throughout the sector. In all case studies analyzed, the design standards of the infrastructure asset, and the ongoing maintenance of assets and the organized response (or lack of) has major implications for the performance of the electricity grid.

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Bibliographic Details
Main Authors: Schweikert, Amy, Nield, Lindsey, Otto, Erica, Deinert, Mark
Format: Working Paper biblioteca
Language:English
Published: World Bank, Washington, DC 2019-06
Subjects:CRITICAL INFRASTRUCTURE, ENERGY INFRASTRUCTURE, RESILIENT INFRASTRUCTURE, NATURAL DISASTER, NATURAL HAZARDS, SUPPLY CHAIN, INFRASTRUCTURE INVESTMENT, ENERGY TRANSMISSION, ENERGY GENERATION, ELECTRICITY GRID,
Online Access:http://documents.worldbank.org/curated/en/245911560800329681/Resilience-and-Critical-Power-System-Infrastructure-Lessons-Learned-from-Natural-Disasters-and-Future-Research-Needs
https://hdl.handle.net/10986/31920
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spelling dig-okr-10986319202024-08-09T06:52:29Z Resilience and Critical Power System Infrastructure Lessons Learned from Natural Disasters and Future Research Needs Schweikert, Amy Nield, Lindsey Otto, Erica Deinert, Mark CRITICAL INFRASTRUCTURE ENERGY INFRASTRUCTURE RESILIENT INFRASTRUCTURE NATURAL DISASTER NATURAL HAZARDS SUPPLY CHAIN INFRASTRUCTURE INVESTMENT ENERGY TRANSMISSION ENERGY GENERATION ELECTRICITY GRID Resilience against infrastructure failure is essential for ensuring the health and safety of communities during and following natural hazard situations. Understanding how natural hazards impact society in terms of economic cost, recovery time, and damages to critical infrastructure is essential for developing robust approaches to increasing resilience. Identifying specific vulnerabilities allows for better communication, planning, and situation-specific interventions. This is particularly relevant in areas recovering from a natural hazard that have the opportunity to build back their infrastructure, and for those currently planning infrastructure expansions. This study considers recent hurricanes, earthquakes, droughts, heat waves, extreme wind and rainfall events, ice and thunder storms as well as wildfires. For many of these, data are available for the same type of hazard in different geographies which provides information not only on specific vulnerabilities, but whether the impacts are location dependent. Where available, specific design considerations, cost information for repairs, and the recommendations for 'building back better' are presented. Above-ground transmission systems were the most commonly affected power system component, with fuel and maintenance supply chains representing a major vulnerability for isolated regions and islands. Generation systems were most commonly affected when a hazard exceeded design limits, particularly in relation to water temperature or wind speeds. Institutional capabilities are important throughout the sector. In all case studies analyzed, the design standards of the infrastructure asset, and the ongoing maintenance of assets and the organized response (or lack of) has major implications for the performance of the electricity grid. 2019-06-20T15:47:47Z 2019-06-20T15:47:47Z 2019-06 Working Paper Document de travail Documento de trabajo http://documents.worldbank.org/curated/en/245911560800329681/Resilience-and-Critical-Power-System-Infrastructure-Lessons-Learned-from-Natural-Disasters-and-Future-Research-Needs https://hdl.handle.net/10986/31920 English Policy Research Working Paper;No. 8900 CC BY 3.0 IGO http://creativecommons.org/licenses/by/3.0/igo World Bank application/pdf World Bank, Washington, DC
institution Banco Mundial
collection DSpace
country Estados Unidos
countrycode US
component Bibliográfico
access En linea
databasecode dig-okr
tag biblioteca
region America del Norte
libraryname Biblioteca del Banco Mundial
language English
topic CRITICAL INFRASTRUCTURE
ENERGY INFRASTRUCTURE
RESILIENT INFRASTRUCTURE
NATURAL DISASTER
NATURAL HAZARDS
SUPPLY CHAIN
INFRASTRUCTURE INVESTMENT
ENERGY TRANSMISSION
ENERGY GENERATION
ELECTRICITY GRID
CRITICAL INFRASTRUCTURE
ENERGY INFRASTRUCTURE
RESILIENT INFRASTRUCTURE
NATURAL DISASTER
NATURAL HAZARDS
SUPPLY CHAIN
INFRASTRUCTURE INVESTMENT
ENERGY TRANSMISSION
ENERGY GENERATION
ELECTRICITY GRID
spellingShingle CRITICAL INFRASTRUCTURE
ENERGY INFRASTRUCTURE
RESILIENT INFRASTRUCTURE
NATURAL DISASTER
NATURAL HAZARDS
SUPPLY CHAIN
INFRASTRUCTURE INVESTMENT
ENERGY TRANSMISSION
ENERGY GENERATION
ELECTRICITY GRID
CRITICAL INFRASTRUCTURE
ENERGY INFRASTRUCTURE
RESILIENT INFRASTRUCTURE
NATURAL DISASTER
NATURAL HAZARDS
SUPPLY CHAIN
INFRASTRUCTURE INVESTMENT
ENERGY TRANSMISSION
ENERGY GENERATION
ELECTRICITY GRID
Schweikert, Amy
Nield, Lindsey
Otto, Erica
Deinert, Mark
Resilience and Critical Power System Infrastructure
description Resilience against infrastructure failure is essential for ensuring the health and safety of communities during and following natural hazard situations. Understanding how natural hazards impact society in terms of economic cost, recovery time, and damages to critical infrastructure is essential for developing robust approaches to increasing resilience. Identifying specific vulnerabilities allows for better communication, planning, and situation-specific interventions. This is particularly relevant in areas recovering from a natural hazard that have the opportunity to build back their infrastructure, and for those currently planning infrastructure expansions. This study considers recent hurricanes, earthquakes, droughts, heat waves, extreme wind and rainfall events, ice and thunder storms as well as wildfires. For many of these, data are available for the same type of hazard in different geographies which provides information not only on specific vulnerabilities, but whether the impacts are location dependent. Where available, specific design considerations, cost information for repairs, and the recommendations for 'building back better' are presented. Above-ground transmission systems were the most commonly affected power system component, with fuel and maintenance supply chains representing a major vulnerability for isolated regions and islands. Generation systems were most commonly affected when a hazard exceeded design limits, particularly in relation to water temperature or wind speeds. Institutional capabilities are important throughout the sector. In all case studies analyzed, the design standards of the infrastructure asset, and the ongoing maintenance of assets and the organized response (or lack of) has major implications for the performance of the electricity grid.
format Working Paper
topic_facet CRITICAL INFRASTRUCTURE
ENERGY INFRASTRUCTURE
RESILIENT INFRASTRUCTURE
NATURAL DISASTER
NATURAL HAZARDS
SUPPLY CHAIN
INFRASTRUCTURE INVESTMENT
ENERGY TRANSMISSION
ENERGY GENERATION
ELECTRICITY GRID
author Schweikert, Amy
Nield, Lindsey
Otto, Erica
Deinert, Mark
author_facet Schweikert, Amy
Nield, Lindsey
Otto, Erica
Deinert, Mark
author_sort Schweikert, Amy
title Resilience and Critical Power System Infrastructure
title_short Resilience and Critical Power System Infrastructure
title_full Resilience and Critical Power System Infrastructure
title_fullStr Resilience and Critical Power System Infrastructure
title_full_unstemmed Resilience and Critical Power System Infrastructure
title_sort resilience and critical power system infrastructure
publisher World Bank, Washington, DC
publishDate 2019-06
url http://documents.worldbank.org/curated/en/245911560800329681/Resilience-and-Critical-Power-System-Infrastructure-Lessons-Learned-from-Natural-Disasters-and-Future-Research-Needs
https://hdl.handle.net/10986/31920
work_keys_str_mv AT schweikertamy resilienceandcriticalpowersysteminfrastructure
AT nieldlindsey resilienceandcriticalpowersysteminfrastructure
AT ottoerica resilienceandcriticalpowersysteminfrastructure
AT deinertmark resilienceandcriticalpowersysteminfrastructure
AT schweikertamy lessonslearnedfromnaturaldisastersandfutureresearchneeds
AT nieldlindsey lessonslearnedfromnaturaldisastersandfutureresearchneeds
AT ottoerica lessonslearnedfromnaturaldisastersandfutureresearchneeds
AT deinertmark lessonslearnedfromnaturaldisastersandfutureresearchneeds
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