Power systems modeling for multiple infrastructure damage and repair simulations

The interdependencies that exist within and between infrastructures can cause unexpected system properties to emerge when their components fail due to large disruptions. As witnessed following emergencies such as Hurricane Katrina, the complexities of these interdependencies make it very difficult...

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Main Author: Ozog, Nathan
Language:English
Published: University of British Columbia 2008
Subjects:
Online Access:http://hdl.handle.net/2429/1406
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-BVAU.2429-14062014-03-26T03:35:20Z Power systems modeling for multiple infrastructure damage and repair simulations Ozog, Nathan Infrastructure interdependencies Repair model Bulk power system restoration Damage model Simulation Risk modeling The interdependencies that exist within and between infrastructures can cause unexpected system properties to emerge when their components fail due to large disruptions. As witnessed following emergencies such as Hurricane Katrina, the complexities of these interdependencies make it very difficult to effectively recover infrastructure because of the challenges they create in prioritizing the most critical components for repair. The Joint Infrastructure Interdependencies Research Program was initiated by Public Safety Canada (PSC) and the Natural Sciences and Engineering Research Council of Canada (NSERC) in 2005 to research methods for remedying this problem. As a part of this research, the University of British Columbia (UBC) is developing an infrastructure interdependency simulator, named I2Sim, to simulate disasters and develop strategies for dealing with emergencies. Part of this development is to construct a model of the UBC electrical distribution system and interface it with I2Sim. In this research, a general methodology for such a model is presented, which employs an off-the-shelf powerflow modeling tool. In addition, a model of the UBC information technology infrastructure is developed to provide a second infrastructure model to demonstrate the electrical model's usefulness in multi-infrastructure disaster recovery simulations. Simulations with these models have shown that the recovery of this two-infrastructure system can be carried out more effectively following an earthquake if both infrastructures are considered together in the repair approach, rather than individually. This difference was on the order of thirty percent. To extend this research from electrical distribution systems to electrical bulk systems, an interdependency model of the British Columbia Transmission Corporation bulk power network and its communications system was also developed, along with a post-blackout restoration procedure. Using these, simulations of a post-blackout recovery were carried out to study the level of risk that communications outages may pose to the electrical network's recovery. These simulations revealed a correlation between restoration time and the number of communication points lost. This research also demonstrates there is value in combining the results of such simulations with risk evaluation tools. Together these results provided a clearer indication of where vulnerabilities exist. 2008-08-18T21:02:06Z 2008-08-18T21:02:06Z 2008 2008-08-18T21:02:06Z 2008-11 Electronic Thesis or Dissertation http://hdl.handle.net/2429/1406 eng University of British Columbia
collection NDLTD
language English
sources NDLTD
topic Infrastructure interdependencies
Repair model
Bulk power system restoration
Damage model
Simulation
Risk modeling
spellingShingle Infrastructure interdependencies
Repair model
Bulk power system restoration
Damage model
Simulation
Risk modeling
Ozog, Nathan
Power systems modeling for multiple infrastructure damage and repair simulations
description The interdependencies that exist within and between infrastructures can cause unexpected system properties to emerge when their components fail due to large disruptions. As witnessed following emergencies such as Hurricane Katrina, the complexities of these interdependencies make it very difficult to effectively recover infrastructure because of the challenges they create in prioritizing the most critical components for repair. The Joint Infrastructure Interdependencies Research Program was initiated by Public Safety Canada (PSC) and the Natural Sciences and Engineering Research Council of Canada (NSERC) in 2005 to research methods for remedying this problem. As a part of this research, the University of British Columbia (UBC) is developing an infrastructure interdependency simulator, named I2Sim, to simulate disasters and develop strategies for dealing with emergencies. Part of this development is to construct a model of the UBC electrical distribution system and interface it with I2Sim. In this research, a general methodology for such a model is presented, which employs an off-the-shelf powerflow modeling tool. In addition, a model of the UBC information technology infrastructure is developed to provide a second infrastructure model to demonstrate the electrical model's usefulness in multi-infrastructure disaster recovery simulations. Simulations with these models have shown that the recovery of this two-infrastructure system can be carried out more effectively following an earthquake if both infrastructures are considered together in the repair approach, rather than individually. This difference was on the order of thirty percent. To extend this research from electrical distribution systems to electrical bulk systems, an interdependency model of the British Columbia Transmission Corporation bulk power network and its communications system was also developed, along with a post-blackout restoration procedure. Using these, simulations of a post-blackout recovery were carried out to study the level of risk that communications outages may pose to the electrical network's recovery. These simulations revealed a correlation between restoration time and the number of communication points lost. This research also demonstrates there is value in combining the results of such simulations with risk evaluation tools. Together these results provided a clearer indication of where vulnerabilities exist.
author Ozog, Nathan
author_facet Ozog, Nathan
author_sort Ozog, Nathan
title Power systems modeling for multiple infrastructure damage and repair simulations
title_short Power systems modeling for multiple infrastructure damage and repair simulations
title_full Power systems modeling for multiple infrastructure damage and repair simulations
title_fullStr Power systems modeling for multiple infrastructure damage and repair simulations
title_full_unstemmed Power systems modeling for multiple infrastructure damage and repair simulations
title_sort power systems modeling for multiple infrastructure damage and repair simulations
publisher University of British Columbia
publishDate 2008
url http://hdl.handle.net/2429/1406
work_keys_str_mv AT ozognathan powersystemsmodelingformultipleinfrastructuredamageandrepairsimulations
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