Authors: Berna Eren Tokgoz, Mahdi Safa, Seokyon Hwang

Abstract:

Power distribution systems are essential and crucial infrastructures for the development and maintenance of a sustainable society. These systems are extremely vulnerable to various types of natural and man-made disasters. The assessment of resilience focuses on preparedness and mitigation actions under pre-disaster conditions. It also concentrates on response and recovery actions under post-disaster situations. The aim of this study is to present a methodology to assess the resilience of electric power distribution poles against wind-related events. The proposed methodology can improve the accuracy and rapidity of the evaluation of the conditions and the assessment of the resilience of poles. The methodology provides a metric for the evaluation of the resilience of poles under pre-disaster and post-disaster conditions. The metric was developed using mathematical expressions for physical forces that involve various variables, such as physical dimensions of the pole, the inclination of the pole, and wind speed. A three-dimensional imaging technology (photogrammetry) was used to determine the inclination of poles. Based on expert opinion, the proposed metric was used to define zones to visualize resilience. Visual representation of resilience is helpful for decision makers to prioritize their resources before and after experiencing a wind-related disaster. Multiple electric poles in the City of Beaumont, TX were used in a case study to evaluate the proposed methodology.  

Keywords: Photogrammetry, power distribution systems, resilience metric, system resilience, wind-related disasters.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1131313

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References:

[1] T. Gonen, Electric Power Distribution System Engineering. New York: McGraw-Hill, ch. 5.
[2] M. Panteli and P. Mancarella, “Influence of extreme weather and climate change on the resilience of power systems: impacts and possible mitigation strategies,” Electric Power Systems Research, vol. 127, pp. 259-270, 2015.
[3] Y. J. Park, C. R. Glagola, K. R. Gurley, and K. Son, “Performance assessment of the Florida electric-power network system against hurricanes,” Natural Hazards Review, vol. 4, pp. 1-7, 2014.
[4] R. J. Campbell, “Weather-related power outages and electric system resilience,” Congressional Research Service, CRS Report for Congress, pp. 1-15, 2012.
[5] M. Ouyang and L. Duenas-Osorio, “Multi-dimensional hurricane resilience assessment of electric power systems,” Structural Safety, vol. 48, pp. 15-24, 2014.
[6] G. L. Daugherty, “The Realistic Expectation of an In-place Wood Pole Inspection Program,” Utility Poles and Structures (Revised version of a paper presented at the International Conference on Utility Line Structures). March 1998.
[7] B. Eren Tokgoz, and A. Gheorghe, “Probabilistic resilience for building systems exposed to natural disasters”, International Journal of Critical Infrastructures, vol.10, no. 3(4), 2014, pp. 375-397.
[8] B. Eren Tokgoz, and A. Gheorghe, “Resilience quantification and its application to a residential building subject to hurricane winds,” Int. J. Disaster Risk Sci, vol. 4, no. 3, 2013.
[9] L. Carlson, G. Bassett, W. Buehring, M. Collins, S. Folga, B. Haffenden, F. Petit, J. Phillips, D. Verner, and R. Whitfield, “Resilience: Theory and Applications,” Argonne National Laboratory, 2012.
[10] The White House. Presidential Policy Directive – Critical Infrastructure Security and Resilience. Office of the Press Secretary, (February12, 2013) < https://obamawhitehouse.archives.gov/the-press-office/2013/02/12/presidential-policy-directive-critical-infrastructure-security-and-resil>S.
[11] Technical Workshop: Resilience Metrics for Energy Transmission and Distribution Infrastructure. < https://energy.gov/epsa/downloads/technical-workshop-resilience-metrics-energy-transmission-and-distribution>
[12] H. H. Willis and K. Loa, “Resilience Metrics for Energy Systems,” RAND Corporation (April 29,2014) https://energy.gov/sites/prod/files/2015/01/f19/RAND.Resiliency%20Metrics%20workshop.pdf
[13] J. Phillips and T. Angeli. “Resilience Metrics,” Argonne National Laboratory, (April 28, 2014). https://energy.gov/sites/prod/files/2015/01/f19/Argonne%20National%20Lab.Resiliency%20Metrics%20workshop.pdf
[14] Energy Infrastructure Resilience, Framework and Sector-Specific Metrics. Sandia National Laboratories. (April 29,2014). < https://energy.gov/sites/prod/files/2015/01/f19/SNLResilienceApril29.pdf>.
[15] M. Ouyang, “Review on modeling and simulation of interdependent critical infrastructure systems,” Reliability Engineering and System Safety, vol. 121, pp. 43-60, 2014.
[16] S Hosseini, K. Barker, and J.E. Ramirez-Marquez, “A review of definitions and measures of systems resilience,” Reliability Engineering and System Safety, vol. 145, pp. 47-61, 2016.
[17] R. Francis, and B. Bekera, “A metric and frameworks for resilience analysis of engineered and infrastructure systems,” Reliability Engineering and System Safety, vol. 121, pp. 90-103, 2014.
[18] D. Henry and J.E. Ramirez-Marquez, “Generic metrics and quantitative approaches for system resilience as a function of time,” Reliability Engineering and System Safety, vol. 99, pp. 114–22, 2012.
[19] M. Ouyang, L. Duenas-Osorio, and X. Min, “A Three-Stage Resilience analysis framework for urban infrastructure systems,” Structural Safety, vol. 36-37, pp. 23-31, 2012.
[20] A. F. Mensah, and L. Duenas-Osoria, “Efficient resilience assessment framework for electric power systems affected by hurricane events,” Journal of Structural Engineering, vol. 142, no. 8, 2016.
[21] H. Liu, R. A. Davidson and T. V. Apanasovich, “Statistical Forecasting of Electric Power restoration times in hurricane and ice storms,” IEEE Transactions on Power Systems, vol.22, no.4, 2007.
[22] S. D. Guikema, S. M. Quiring, and S.R. Han, “Prestorm estimation of hurricane damage to electric power distribution systems. Risk Analysis, vol. 30, no. 12, 2010.
[23] G. Li, P. Zhang, P.B. Luh, W. Li, Z. Bie, C. Serna and Z. Zhao, “Risk analysis for distribution systems in the Northeast U.S. under wind storms,” IEEE Transactions on Power Systems, vol.29, no. 2, 2014.
[24] A. Arab, A. Khodaei, S.K. Khator, K. Ding, V. A. Emesih, and Z. Han, “Stochastic pre-hurricane restoration planning for electric power systems infrastructure,” IEEE Transactions on Smart Grid, vol.6, no. 2, 2015.
[25] C. Nan and G. Sansavini, “A quantitative method for assessing resilience of interdependent infrastructure,” Reliability Engineering and System Safety, vol. 157, pp. 35-53, 2017.
[26] M. Espinoza, Pantelli and P. Mancarella, “Multi-phase assessment and adaptation of power systems resilience to natural hazards,” Electric Power Systems Research, vol. 136, pp. 352-361, 2016.
[27] P. C. Ryan, M. G. Stewart, N. Spencer, and Y. Li, “Reliability assessment of power pole infrastructure incorporating deterioration and network maintenance,” Reliability Engineering and System Safety, vol. 132, pp. 261-273, 2014.
[28] Y. M. Darestani, A. Shafieezadeh, and R. DesRoches, “An equivalent boundary model for effect of adjacent spans on wind reliability of wood utility poles in overhead distribution lines,” Engineering Structures, vol. 128, pp. 441-452, 2016.
[29] P. Tang, B. Akinci, and D. Huber, “Quantification of edge loss of laser scanned data at spatial discontinuities,” Automation in Construction, vol. 18, no. 8, pp.1070-1083, 2009.
[30] K. Ghahremani, M. Safa, J. Yeung, S. Walbridge, C. Haas, and S. Dubois. "Quality assurance for high-frequency mechanical impact (HFMI) treatment of welds using handheld 3D laser scanning technology." Welding in the World, 59, no. 3, 391-400, 2015.
[31] M. Safa, M. Nahangi, A. Shahi, and C.T. Haas, “An integrated quality management system for piping fabrication using 3D laser scanning and photogrammetry,” 30th International Association for Automation and Robotics in Construction (IAARC), Montreal, Canada, 2013.
[32] M. Safa, A. Sabet, K. Ghahremani, C. Haas, and S. Walbridge. "Rail corrosion forensics using 3D imaging and finite element analysis." International Journal of Rail Transportation, 3, no. 3, 164-178, 2015.
[33] Standard Specifications for Structural Supports for Highway Signs, Luminaires, and Traffic Signals, The American Association of State Highway and Transportation Officials (AASHTO), 6th Edition, 2013.