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Home My WebLink About20150812AVU to Staff 50 Attachment G.pdf2012 Wood Pole Management – Complete System Analysis Background Avista’s Wood Pole Management Department is tasked with overseeing the maintenance and repair of the wood poles in Avista’s electric transmission and distribution systems. Part of the wood pole management program involves inspecting all of the poles in the distribution system on a twenty year cycle and conducting maintenance as needed to avoid future failures, which have the potential to cause an outages. Avista’s Asset Management Department has conducted some analysis that looks very closely at the current twenty year inspection interval. The intent of this report is to communicate the details of that analysis. Model Assumptions The following assumptions were made in the construction of the distribution system model Poles • The electric distribution system consists of 246,000 wood distribution poles • Poles that fail will be replaced with another equivalent (45’) cedar wood pole • Poles that do not meet code requirements are either reinforced with a steel stub or replaced with another equivalent (45’) cedar wood pole • The age of the poles is based on the age distribution of a representative sample • The poles are inspected on a 20 year interval Cross arms • Each of the 246,000 poles has one cross arm • The age of the cross arm is initially assumed to be the same as the age of the pole Pin • Each of the 246,000 poles has three pins • The age of the pins is initially assumed to be the same as the age of the pole Insulators • Each of the 246,000 pole locations has three insulators • The age of the pins is initially assumed to be the same as the age of the pole Transformers • There are approximately 118,000 transformers in the distribution system • The age of the transformers is based on the age distribution of a representative sample Lightning Arrestors • Each transformer has one lightning arrestor • The age of the lightning arrestor is initially based on the age of the transformer at each location Wildlife Guards • Each transformer has one wildlife guard • The age of the wildlife guard is initially based on the age of the transformer at each location Cutout • Each transformer has one cutout • The age of the cutout is initially based on the age of the transformer at each location Ground Rod • Each pole with a transformer has one ground rod • The age of the ground rod is initially based on the age of the transformer at each location Staff_PR_050 Attachment G Page 1 of 11 Model Assumptions (cont.) Since the actual age of the distribution components is not exactly the same as the pole or transformer, the model’s initial predictions don’t match the 2011 actual replacement quantities. The initial values and the errors can be seen in Figure 1. Figure 1 Error in initial calculations due to unknown age of components It can be seen from the chart above that the model fairly closely predicts the number of replaced failed poles, stubbed poles stubbed and transformers that are replaced (all highlighted green). The other components which have age profiles based on either the poles or the transformers are not as accurate so the failure curves of each component were shifted so that the predictions would more closely match the 2011 replacements. Figure 2 below, shows the actual failure data points and the adjusted failure curve that is used by the software to calculate failures. Figure 2 Offsetting Weibull Curve Staff_PR_050 Attachment G Page 2 of 11 Analysis Results - 20 yr Inspection vs. No Inspection The system was modeled to closely match the current scenario where each pole and its additional components are inspected on a twenty year cycle. This case was compared to a hypothetical case where no inspection was completed. Results from this comparison show that a twenty year inspection cycle has financial benefits to the customer. The results can be seen tabulated in Figure 3 and graphically in Figure 4. Figure 3 Comparison of Financial Data Between 20 yr inspection and no inspection Figure 4 Cumulative Cost Comparison Figure 5 20 yr Inspection vs. No Inspection - Labor Prediction Comparison Staff_PR_050 Attachment G Page 3 of 11 Figure 6 20 yr Inspection vs. No Inspection – Effects Prediction Comparison Staff_PR_050 Attachment G Page 4 of 11 Figure 7 20 yr Inspection vs. No Inspection - Equipment Prediction Comparison Figure 8 20 yr vs. No Inspection - Spares Prediction Comparison Staff_PR_050 Attachment G Page 5 of 11 Analysis Results - Inspection Interval Optimization In addition to comparing our current inspection scenario to a case where no inspection is done, analysis was conducted to see if a shorter or longer maintenance interval would be more cost effective. Five, ten, fifteen and twenty year inspection intervals were compared. The results of this comparison show that increasing the frequency of the inspection to approximately 10 yrs would yield financial advantages. A separate calculation was also done within Availability Workbench to optimize the inspection interval. This calculation shows that there is a slight advantage to increasing the inspection interval to approximately eight years. The results of this calculation can be seen in Figure 11. The charts and figures below show the comparison between the current base case 20yr inspection interval with a 10yr inspection interval as well as a comparison between the 10 year inspection interval and the no inspection case. Figure 9 Figure 10 Figure 11 Staff_PR_050 Attachment G Page 6 of 11 Figure 12 Optimization of Inspection Interval Figure 13 20 yr vs. 10 yr Inspection - Labor Prediction Comparison Staff_PR_050 Attachment G Page 7 of 11 Figure 14 20 yr vs. 10 yr Inspection - Effects Prediction Comparison Staff_PR_050 Attachment G Page 8 of 11 Figure 15 20 yr vs. 10 yr Inspection - Equipment Prediction Comparison Staff_PR_050 Attachment G Page 9 of 11 Figure 16 20 yr vs. 10 yr Inspection - Spares Prediction Comparison Staff_PR_050 Attachment G Page 10 of 11 Recommendations – While the advantage is slight, all of the analysis indicates that increasing the frequency of inspection would yield financial benefits to the customers. It may not be practical to immediately increase the inspection frequency to 10 years but the goal should be to increase the inspection interval on a regular basis until such time as the number of yearly pole replacements per year begins to stabilize. Although the budgetary requirements for increasing the inspection frequency are considerably more than the current 20 year inspection frequency (See Figure 16) the increased costs will ultimately yield financial advantages as few poles are replaced each year. (See Figure 17). Figure 17 Staff_PR_050 Attachment G Page 11 of 11