The URL can be used to link to this page

Home My WebLink About20080403DeFelice Direct.pdf1!¡t:D.4..._ .DAVID J. MEYER VICE PRESIDENT, GENERAL COUNSEL, GOVERNENTAL AFFAIRS AVISTA CORPORATION P.O. BOX 3727 1411 EAST MISSION AVENUE SPOKAE, WASHINGTON 99220-3727 TELEPHONE: (509) 495-4316 FACSIMILE: (509) 495-8851 REGULATORY &"ntl''!'Ut, ~ f'D')u 1'1 i\ _ ')v Pf1 /: 116 BEFORE THE IDAHO PUBLIC UTILITIES COMMISSION IN THE MATTER OF THE APPLICATION OF AVISTA CORPORATION FOR THE AUTHORITY TO INCREASE ITS RATES AN CHARGES FOR ELECTRIC AN NATURA GAS SERVICE TO ELECTRIC AND NATURL GAS CUSTOMERS IN THE STATE OF IDAHO CASE NO. AVU-E-08-01 CASE NO. AVU-G-08-01 DIRECT TESTIMONY OF DAVE B. DEFELICE FOR AVISTA CORPORATION (ELECTRIC AND NATUR GAS) 1 2 I. INTRODUCTION Q.Please state your name, employer and business 3 address. 4 A.My name is Dave B. DeFelice.I am employed by 5 Avista Corporation as a Senior Business Analyst.My 6 business address is 1411 East Mission, Spokane, washington. 7 Q.Please briefly describe your education backgroun 8 and professional experience. 9 A.I graduated from Eastern Washington University in 10 June of 1983 with a Bachelor of Arts Degree in Business 11 Administration majoring in Accounting.I have served in 12 various positions within the Company, including Analyst 13 positions in the Finance Department (Rates section and 14 Plant Accounting) and in Marketing/Operations Departments, 15 as well.In 1999, I accepted the Senior Business Analyst 16 posi tion that focuses on economic analysis of various 17 18 project proposals as well as evaluations and recommendations pertaining to' business policies and 19 practices. 20 Q.As a Senior Business Anlyst, what are your 21 responsibilities? 22 A.As a Senior Business Analyst I am involved in 23 activities ranging from financial analysis of numerous 24 proj ects with various departments such as Engineering, 25 Operations, Marketing/Sales and Finance.Also, a portion DeFelice, Di 1 Avista Corporation 1 of my job tasks involve advisory and informal training of 2 employees pertaining to regulatory finance and ratemaking 3 concepts. 4 5 Q.What is the scope of your testimony? A.My testimony and exhibits in this proceeding will 6 cover the Company's proposed regulatory treatment of 7 capital investments in utility plant through 2008. 8 9 Q.Are you sponsoring any exhibits? A.Yes.I am sponsoring Exhibit No. 11, Schedule 1 10 ("Rising Utility Construction Costs: Sources and Impacts" 11 study from The Brattle Group),Schedule 2 (Capital 12 Expenditures) , and Schedule 3 (2008 Capital Additions 13 Detail), which were prepared under my direction. 14 15 16 II. CAPITAL INVSTMNT RECOVERY Q.What does the Company's request for rate relief 17 include regarding new investment in utility plant to serve 18 customers? 19 A.In this filing, we are proposing to include in 20 retail rates the costs associated with utility plant that 21 is in-service, and will be used to provide energy service 22 to our customers during the 2009 pro forma rate year. This 23 is consistent with prior ratemaking practice in the State 24 of Idaho. DeFelice, Di 2 Avista Corporation 1 The utility plant investment that we have included in 2 this filing represents utility plant that will be "used and 3 useful" in providing service to customers during the 4 approximate period that new retail rates from this filing 5 will be in effect.The costs associated with the 6 investment will be "known and measurable," and finally, 7 including the costs associated with this investment in 8 retail rates provides a proper "matching" of revenues from 9 customers, with the costs associated with providing service 10 to customers (including the cost of utility plant to serve 11 cus tomers) . 12 In the IPUC's Order No. 29602, in Case Nos. AVU-E-04-1 13 and AVU-G-04-1, dated October 8, 2004, the Commission 14 stated, at page 10, that: 15 "Once a test year is selected, adjustments are16 made to test year accounts and rate base to 17 reflect known and measurable changes so that test18 year totals accurately reflect anticipated19 amounts for the future period when rates will be 20 in effect. The Idaho Supreme Court has described21 "rate base" as "the utility's capital investment22 amount." Industrial Customers of Idaho Power v. 23 Idaho PUC 134 Idaho 285, 291, 1 P. 3d 786, 79224 (2000) . Adjustments to test year accounts25 generally fall into three categories: 1) 26 normalizing adjustments made for unusual27 occurrences, like one-time events or extreme28 weather conditions, so they do not unduly affect 29 the test year i 2) annualizing adjustments made30 for events that occurred at some point in the31 test year to average their effect as if they had32 been in existence during the entire year ¡and 3) 33 known and measurable adjustments made to include34 events that occur outside the test year but will35 continue in the future to affect Company income36 and expenses." DeFelice, Di 3 Avista Corporation 1 If utility plant investment that is being used to 2 serve customers is not reflected in retail rates then the 3 retail rates will not be "just,reasonable,and 4 sufficient," i.e., it would not be just or reasonable for 5 customers to receive the benefit provided by the utility 6 investment without paying for it, and the retail rates 7 would not provide revenues "sufficient" to provide recovery 8 of the costs associated with providing service to 9 customers. 10 Q.Is the Company' s application of these ratemking 11 principles in this filing consistent with prior general 12 rate cases? 13 14 A.Yes.In prior cases, the obj ecti ve has been the same to include in retail rates the investment, or rate 15 base, that is providing service to customers, and ensure 16 that there is a proper matching of revenues and expenses 17 during the period that rates are in effect. 18 Q.How does new investment in utility plant change 19 rate base over time for ratemking purposes? 20 A.Historically, the annual dollars spent by the 21 Company on new utility plant has generally been relatively 22 close to the level of depreciation expense, with the 23 exception of years where the Company has invested in major DeFel ice, Di 4 Avista Corporation 1 new utility . iproJects.I will use an example to 2 illustrate, in general terms, how new investment in utility 3 plant changes rate base over time.Let's assume that the 4 Company's rate base (adjusted net plant in service used to 5 serve customers) at the beginning of Year 1 is $1.5 6 billion.Also assume that depreciation expense in Year 1 7 is $80 million, and the Company's new investment in utility 8 plant in Year 1 is also $80 million.During Year 1, rate 9 base increased by $80 million (new investment), and 10 decreased by $80 million (depreciation), and ended up at 11 the same level of $1.5 billion at the end of the year. In 12 this simplified example, the Company i s rate base is $1.5 13 billion, both at the beginning of Year 1, and at the end of 14 Year 1. For ratemaking purposes, the $1.5 billion of rate 15 base is representative of the level of plant investment 16 used to serve customers, both at the beginning of the year 17 and at the end 0 f the year.Over time, if depreciation 18 expense continues to be approximately equal to new plant 19 investment, rate base would continue at a relatively 20 constant $1.5 billion. Under these circumstances, the use 21 of the $1.5 billion rate base amount from a prior year, 22 i. e., a historical test year, would be adequate for setting 23 rates for the upcoming year (pro forma rate year), because i Recognzing that a porton of the costs associated with capita additions are offet by additional revenues. DeFelice, Di 5 Avista Corporation 1 there is little change in the net plant investment used to 2 serve customers. 3 In a similar manner, in prior general rate cases we 4 have used a rate base amount from a historical test year as 5 the starting point for the pro forma rate year.If there 6 were no major plant additions between the historical test 7 year and the upcoming pro forma rate year, the historical 8 test year rate base amount would be used for the pro forma 9 rate year as being representative of the net plant used to 10 serve customers. If there were known major plant additions 11 that would be in service for the pro forma rate year, such 12 as the recent addition of Coyote Springs II for Avista, the 13 major transmission upgrades,and the hydroelectric 14 upgrades, then rate base for the pro forma rate year is 15 adjusted for these major investments, so that rate base for 16 the pro forma rate year is representative of the level of 17 investment used to serve customers. 18 Q.Is Avista' s new investment in utility plant 19 exceeding its annual depreciation expense, causing an 20 increase in rate base? 21 A.Yes.Avista's investment in plant in 2007 and 22 2008, is well above the annual depreciation expense, and 23 will result in an increase in net plant in service (rate 24 base) that will be used to serve customers in the 2009 pro 25 forma rate year. Much of this new investment in plant for DeFelice, Di 6 Avista Corporation 1 2007 and 2008 is spread among many different utility plant 2 categories, as opposed to a few major plant additions. 3 Therefore, the Company's pro forma adjustment for new 4 investment in plant in this filing involves a more detailed 5 analysis of the net change in rate base from the historical 6 test period to the pro forma rate year.The end resul t , 7 however, is the same in this case as in prior cases - to 8 reflect in retail rates the level of net plant investment 9 that is used to serve customers during the pro forma rate 10 year, and to have a proper matching of revenues and 11 expens es . 12 Q.How was rate base for the pro form rate year 13 developed for this filing? 14 A.As in prior rate cases, Avista started with rate 15 base for the historical test year, which for this case is 16 the calendar year 2007.Adjustments were made to reflect 17 new additions and accumulated depreciation through December 18 2008, such that the proposed rate base reflects the net 19 plant in service that will be used to serve customers 20 during the 2009 pro forma rate year. Later in my testimony 21 i will provide the details of the adjustments to rate base. 22 Although there is a strong case to be made that the 23 new capital investment in 2009 will be used to serve 24 customers during the 2009 rate year, and should be DeFelice, Di 7 Avista Corporation 1 reflected in this case, the Company has only included new 2 investment through Decemer 2008. 3 The capital additions through 2008 will be in-service 4 at the approximate time new rates become effective from 5 this rate filing, and customers will be receiving benefits 6 from this investment. The following chart illustrates the 7 2007 historical test period and the April 2008 filing of 8 this case.The chart also illustrates that the capital 9 additions for 2007 and 2008 will be completed and in 10 service prior to January 1, 2009.During 2009 customers 11 will receive the benefit from the full investment in 2007 12 and 2008, and it is appropriate for this investment to be 13 reflected in the retail rates for 2009. 14 15 Illustration 1 16 Capital Additions 2007 - 2009Avista Utilties 17 18 19 20 21 22 23 24 25 12/3112009~.- .-._.-. .._.. ._._.-.-. .I I. .I I. .I I. .I I . _. l1'~Q!._._. _. _'_' _. _ .-! i i I I.--- .-._._.--_._-_._._. ~ I 2007 Historical Test Year 2008 2009 Filing Date: Apr.20oa DeFelice, Di 8 Avista Corporation 1 As illustrated by the chart, if the proposed rates in 2 this case go into effect near the end of 2008, the 2007 3 plant additions will be entering their third year of 4 service during calendar year 2009, . and the 2008 capital 5 additions will be in their second year of service in 2009. 6 Clearly the 2007 and 2008 investment will be providing 7 service to customers, and would reflect the true cost of 8 funding assets that are necessary, and used and useful, to 9 provide service to customers during the year that new rates 10 will be in effect.It would result in a mismatch of 11 revenues and expense during 2009 if the costs associated 12 with these investments are not reflected in new retail 13 rates. 14 Q.You stated earlier that new utility investment in 15 2007 and 2008 will be substantially higher than the annual 16 depreciation expense.What is driving the significant 17 investment in new utility plant? 18 A.The Company is currently being required to add 19 significant new transmission and distribution facilities, 20 including strengthening the "back bone" of our system, due 21 in part to customer growth in our service area, reliability requirements, and capacity upgrades.Other issues driving22 23 24 the need for capital investment include an aging infrastructure,physical degradation,and municipal 25 compliance issues (i.e., street/highway relocations), etc. DeFelice, Di 9 Avista Corporation 1 While the overall economy is slowing on a national basis, 2 Kootenai County is still growing.In 2007, employment 3 growth in Kootenai County ranked in the top 5% of all 4 metropoli tan areas. 5 In addition, the cost of raw materials, including 6 concrete, steel, copper, aluminum and other materials, have 7 sky-rocketed in recent years, causing the cost of these new 8 facilities to be significantly higher than in the past. 9 Because the cost of adding new facilities is significantly 10 higher than the existing facilities, the investment in new 11 facilities will be significantly higher than the annual 12 depreciation expense on the existing facilities. 13 Q.What is causing the substantial increase in raw 14 materials for Avista, and the utility industry in general? 15 A.In September 2007,The Edison Foundation 16 commissioned a study from The Brattle Group titled, "Rising 17 Utility Construction Costs: Sources and Impacts," which 18 identified cost trends specifically related to the utility 19 industry pertaining to critical materials and equipment, as 20 well as labor support services used for building capital 21 infrastructure. This study is attached as Exhibit No. 11, 22 Schedule 1.The study identifies the reasons for drastic 23 cost increases in critical raw materials, such as global 24 competition and an aging domestic utility infrastructure as DeFelice, Di 10 Avista Corporation 1 well as the need for additional infrastructure to 2 accommodate growth in the near future. 3 Q.What are some of the key cost drivers that are 4 ci ted in the study? 5 A.The study, at page 16, cites four major cost 6 drivers," (1) material input costs, including the cost of 7 raw physical inputs, such as steel and cement as well as 8 increased costs of components manufactured from these 9 inputs (e.g., transformers, turbines, pumps) i (2) shop and 10 fabrication capacity for manufactured components (relative 11 to current demand) i (3) the cost of construction field 12 labor, both unskilled and craft labor ¡and (4) the market 13 14 for large construction project management,i.e. ,the queuing and bidding for projects."The study goes on to 15 compare cost trends for various raw materials, critical 16 equipment and labor services relative to the general 17 inflation rate (GDP deflator).In addition, a cost trend 18 is sumarized by three key utility functional plant 19 20 categories,including generation,transmission,and distribution plant.The study concludes that these 21 inflation impacts have been outside the utility industry's 22 control and there are no immediate indications of cost 23 relief in the near future. 24 25 Illustration 2 below depicts what has occurred to infrastructure costs nationally.From the chart, it is DeFelice, Di 11 Avista Corporation 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 1 apparent that starting in 2003, costs of distribution, 2 transmission and generation infrastructure increased at a 3 far more significant rate than the overall economy, as measured by the GDP deflator. Illustration 2 Natonal Aleraie Utilit Infasucture Cost Ind -Tól Pl.AllSt Geiar 190 -- DeI-o~"'Ti$I -Di*iblar 180 - -- - - -- -- -- - - - -- -- - -- - - --- - ----.-- -- - -- -_.-.-- ~- ------- uo 140 I' 150 .!:: l.ie ¡13O iS 120 110 100 90 191 lØ 193 19 199 U9 191 19 im 20 201 200 ~ 2Ø 20 2G 207 Yar s...: Th. H..cI.Wb\l..O BiilOl No. 165 ID tbe u.s. Bue.. of EcOlomc Ål,si..Si1e a..... of OIL reoi COIItOl ad eqiJlcos ia.. ror the sped .-eaL .ll.. U1ilil) Co.ir1iOl C_: s... ..d I'to Prd b, Tho Bta. c:.. rorThell.OI Fouacl.. Septber 20 Q.Is there specific evidence that Avista is 21 experiencing cost escalations s~ilar to that indicated in 22 the study? 23 A.Yes. A sample was compiled of some materials and 24 equipment that Avista routinely uses in order to support 25 various infrastructure construction efforts that are part DeFelice, Di 12 Avista Corporation 1 of the Company's annual capital requirements of purchases 2 made from 2003 through 2008.The sample of materials was 3 grouped into categories for typical electric and gas 4 distribution capital projects as well as major electric 5 substation proj ects. The cost sumary indicated that the 6 cost of the materials reviewed has risen sharply in most 7 categories from 2003 to 2008.For the distribution group 8 of materials, the average annual escalation impact from 9 2003 through 2007 is approximately 37%, which is equal to a 10 cumulative increase over the four-year period of 178%. The 11 escalation for the substation group of materials and 12 equipment has been approximately 12% per year for the 13 purchases Avista has made from 2003 to 2008, or a 14 cumulative increase of 55%. 15 Q.What is the historical and projected level of 16 annual capital spending for Avista? 17 A.Avista's capital requirements have steadily 18 increased from approximately $100 million to $200 million 19 over the last several years.Exhibit No. 11, Schedule 2 20 reflects this trend that Avista has experienced and what is 21 planned for in the near future.This clearly shows that 22 the amount of capital proj ects is well in excess of 23 revenue-supported capital expenditures to connect new 24 customers, and beyond the level of revenues that is being 25 collected from customers related to existing plant.The DeFelice, Di 13 Avista Corporation 1 difference between the total capital requirements, less the 2 new revenue related capital, and allowed revenues represent 3 a significant discrepancy that is negatively impacting the 4 Company. 5 Q.What is the likelihood that Avista's capital 6 investment will continue at this level? 7 A.There are many factors that will influence 8 capital expenditures going forward. One factor is the cost 9 of raw materials is expected to continue to inflate over 10 time and the fact that there is more demand for capital 11 proj ects for such things as compliance work with municipal 12 highway and road proj ects, sewer proj ects, etc.Also, as 13 critical systems age, there will be more utility plant that 14 will be reaching the end of physical life and, in some 15 cases, plant may be replaced prior to the end of its 16 physical life based on power efficiency improvements that 17 can be recognized. 18 19 20 III. DESCRIPTION OF CAPITAL PROJECTS Q.For the 2008 capital projects pro for.ed in this 21 filing, please provide a description of the projects. 22 A.Exhibit No. 11, Schedule 3 details the capital 23 projects that will be transferred to plant in service in 24 2008 and included in this filing.A short description of 25 these proj ects follows: DeFelice, Di 14 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 Generation: Thermal - Colstrip Capital Additions - $3,424,000 There will be a planned outage on Unit #4 so the Company can install NOX (pollution control equipment) to be in compliance with state and federal mandates. Further, there will be a replacement of a cooling tower. Thermal - Kettle Falls Capital Projects - $1,131,000 The primary project at the Kettle Falls Generating Station is the re-roofing of the power house. Other smaller proj ects include: replacement of wood screw conveyors which feeds wood into the hopper, replacement of electronic recip. controllers, and replacement of the 4160 protective relays. Thermal - Other Small Proj ects - $130,000 Please refer to the workpapers of Mr. DeFelice for detailed listing of projects. Hydro Cabinet Gorge Bypass Tunnel Proj ect $5,353,000 Feasibility study pertaining to the Company's FERC mandated license obligation regarding gas super- saturation issues within the Clark Fork River License Agreement for the Cabinet Gorge Dam. This study will be completed in August 2008. Company witness Mr. Vermillion discusses this study further in histestimony. Hydro Clark Fork Implement PME Agreement $2,243,000 Over twenty projects are planned for 2008 as part of the protection, mitigation and enhancement (PME) plan. These proj ects were agreed to as part of the settlement agreement and FERC license received in 2001. Hydro - Noxon Capital Projects - $1,628,000Proj ects include finishing the replacement of the stator frame, stator core, and stator windings on unit#5. Further, after spring runoff, the #1 turbine will be upgraded, including a complete mechanical overhaul, upgraded high efficiency turbine, stator core ands ta tor winding. DeFelice, Di 15 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 Hydro - Other Small Proj ects - $1,461,000The primary other small project involves the replacement of the duct bank that runs from the Post Street Substation to the Upper Falls Generating Facili ty. Further, the 80 year old cables which have had two recent failures will be replaced. Please refer to the workpapers of Mr. DeFelice for detailed listing of proj ects. Coyote Springs 2 (CS2) Joint Share Projects $2,200,000 The primary Joint Share proj ect is the hot gas path overhaul. This includes the replacement of the 1ststage rotating and stationary blades and 1st stage nozzles. This work is part of the long term service agreement with General Electric. Coyote Springs 2 (CS2) Capital Proj ects - The primary proj ect is the replacement of on the heat recovery steam generator, result in more generation output from the $1,400,000 duct burnerswhich willturbine. Other Small Proj ects - $807,000 The control system at the Northeast Combustion Turbine will be upgraded for standby reserve. Further, the failed Mark 5 controller and low voltage bus duct between the step transformer and the generator breaker will be replaced, as they failed in 2007. Electric Transmission: West Plains Transmission Reinforcement Project $1,993,000 This item includes constructing 4.7 miles of 115 kV transmission lines from the Airway Heights substation to the existing South Fairchild tap west of Spokane. The line is required to reduce thermal loading on area transmission lines and is the first phase of a multi- phase proj ect . Power Transformer - Transmission - $1,595,000 The primary project in this category is the purchase and installation of a new 230/115 kV auto-transformer at the Benewah Substation. The existing auto- transformer has reached its end of life. DeFelice, Di 16 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 Spokane/Coeur d i Alene 115 kW Line Relay upgrades $1,247,000 Improvements to the Spokane-Coeur d' Alene area 115 kV line protection schemes are required in order to improve system reliability. This proj ect includes the installation of high speed communications between area substations and the replacement of protective relays for improved fault clearing. Nez Perce 115 kV Sub-Inst Capacitor Bank - $751,000 This project involves the installation of a 15 MVAR capacitor bank at the Nez Perce substation and the installation of a 15 MVAR capacitor bank at the Grangeville substation. These capacitor banks are needed to provide area voltage support during peak load conditions. Beacon 230 Bus Convert to DB-DB - $750,000 This project will add a sectionalizing breaker at the Beacon 230 kV substation to meet national reliability compliance standards. Currently there is a 230 kV bus tie breaker, which could be a single point of failure for the entire substation. Lolo 230 - Rebuild 230 kV Yard - $737,000 As a result of the 5- Year Transmission Upgrade Project, fault duties at the Lolo substation have increased. The substation is being rebuilt to meet Company operating standards. Transmission Air Switch Ground Mat - $697,000 This safety project involves the installation of above ground switch platforms to all 115 kV line air swi tches . The platforms will allow company personnel to operate switches safely. Other Small Proj ects - $4,316,000 Please refer to the workpapers of Mr. DeFelice for detailed listing of projects. Electric Distribution: Electric Distribution Minor Blanket Proj ects $5,800,000 Replace crossarms and poles on distribution lines as required, due to storm damage, fires, or obsolescence. DeFel ice, Di 17 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 Wood Pole Mgmt Capital - $4,923,000 The distribution wood-pole management program is the strength evaluation of a certain percentage of the pole population each year. Depending on the test results for a given pole, that pole is either considered satisfactory, reinforced with a steel stub, or replaced. Electric Underground Replacement - $3,000,000Replace high and low vol tage underground cable asrequired. T&D Line Replacement - $2,250,000 Relocation of transmission and distribution lines asrequired. Power Transformer - Distribution - $1,755,000 Installation of distribution power transformers asrequired. Failed Electric Plant - $1,750,000 Installation of distribution plant for failed plant asrequired. Distribution Reliability and Energy Efficiency Program (DREEP) - $1,500,000 This new process at Avista analyzes many aspects of the distribution system, including distribution feederlengths, optimum amperage levels, phase balancing, conservation voltage reduction, etc. , in order to evaluate how the system can be made more efficient. Plumer - Increase Capacity/Rebuild - $1,425,000 This proj ect is required to replace the existing deteriorated wood substation, and increase transformer capacity to meet system demand during all operatingconditions. C & W Kendall Project - $3,050,000 This project involves the relocation and replacement of transmission and distribution facilities for the Kendall Yards project in Downtown Spokane from the Post Street substation to the College and Walnutsubstation. DeFelice, Di 18 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 Indian Trail 115-13kV Sub-Construct New Sub $2,275,000 This project involves the construction of a new 115-13 kV substation in the Indian Trail area to meet capacity demands in northwestern Spokane. This will be a 20 MVA, 2 feeder (13 kV) substation. Critchfield 115 Sub-Construct - $1,614,000 This project involves the construction of a new South Clarkston 115-13 kV substation (20 MVA transformer and 2 feeders) to reduce loading on other area transformers, which are reaching full capacity. Spokane Electric Network Incr Capacity - $1,445,000 These proj ects are associated with the DowntownSpokane electric network. The proj ects involve the installation of vaults, cables, network transformers and protectors as required to serve new networkcustomers, and to maintain service to existingcustomers by replacing overloaded and deteriorated equipment. WSDOT Highway Franchise Consolidation - $800,000 In order to operate our electric system within State highway rights of way, the Company needs to establish new Franchises. Existing franchises have expired and Avista must seek new agreements with the State or riskpenal ties or non -approval by the State. Other Small Projects - $4,737,000 Please refer to the workpapers of Mr. DeFelice for detailed listing of projects. General: Computer/Network Hardware/Software - $9,225,000 Proj ects for replacement of obsolete technology according to Avista' s refresh cycles that are generally driven by hardware/software manufacturer and industry trends. Further investment includes hardware and software investments that address capacity and performance constraints due to technology consumption and growth. Finally, the Company will have technologyinvestments that support business ini tiati ves generally relating to back-office automation, reliability/safety/compliance for electric and gas infrastructure, and systems that service the Customer. DeFelice, Di 19 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 HVAC Renovation Project - $4,990,000 The heating, ventilating, and air conditioning systemsthroughout the Spokane Central Operating Facilities are approximately fifty years old and are in need ofreplacement. The project involves replacing central air handling units and distribution systems in three buildings - the Spokane Service Center, the general office building, and the cafeteria audi torium building. The building envelope of the general office building will also be renovated with high efficiency glass and insulation. New controls will also be installed which will enable energy conservation. Backup Control Center - $1,911,000 This project involves creating a redundant controlcenter to meet NERC reliability standard for transmission and operations groups. Tools Lab and Shop Equipment - $1,200,000 This request is for general replacement and additionsrequired for capi tal proj ects . Structures and Improvements - $1,174,000 This is a group of capital maintenance projects that Facilities Management coordinates at the Spokane Central Operating Facilities and Avista branch facilities - offices and service centers. For 2008, some of the projects includei paving employee parking at Coeur d' Alene, constructing a vehicle storage building at Pullman Service Center, remodel the Spokane Meter Shop, new carpet on General Office 4th floor, remodel of the Cafeteria/ Audi torium building, and multiple small capital maintenance projects acrossAvista's service territory. Other Small Proj ects - $4,205,000 These proj ects include communication and security initiatives, radio equipment, SCADA controls, telephone systems, office and other general facilityupgrades. Transportation: Transportation Equipment - $5,985,000 Capi tal additions in transportation purchase of new fleet vehicles and heavy on-road and off-road applications. include theequipment for DeFelice, Di 20 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 Gas Distribution: Gas Non-Revenue Blanket - $2,297,000 This annual proj ect will replace sections of existing gas piping that require replacement to improve theoperation of the gas system but are not directly linked to new revenue. The proj ect includes relocation of main related to overbuilds, improvement in equipment and/or technology to improve system operation and/or maintenance, replacement of obsolete facili ties, replacement of main to improve cathodic performance, and projects to improve public safety and/or improve system reliability. Gas Replacement Street and Highways - $2,060,000 This annual project will replace sections of existing gas piping that require replacement due to relocation or improvement of streets or highways in areas where gas piping is installed. Avista installs many of its facilities in public right-of-way under established franchise agreements. Avista is required under the franchise agreements, in most cases, to relocate its facilities when they are in conflict with road orhighway improvements. Replace Deteriorated pipe - $1,339,000 This annual proj ect will replace sections of existing gas piping that is suspect for failure or hasdeteriorated within the gas system. This project will address the replacement of sections of gas main thatno longer operate with reliability and/or safety. Sections of the gas system require replacement due tomany factors including material failures, environmental impact, increase leak frequency, orcoating problems. This proj ect will identify and replace sections of main to improve public safety and system reliability. Reinforce Gate Station Post Falls, ID - $1,500,000 This proj ect will build a larger Gate Station at the existing Post Fall, ID Tap. New metering, regulation, and a line heater will be installed. Due to system growth, demand for gas in the Post Falls area has exceeded the capacity of the current Gate Station. The existing facilities are inadequate during high system demand. Rebuilding the gate station will insure continued reliable operation of the gatestation facilities. DeFelice, Di 21 Avista Corporation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 East Medford /Roseburg /Sutherlin HP Reinforcement Projects - $10,020,000 These Oregon gas distribution projects are not included in this filng. Kettle Falls Relocation/Gate - $1,300,000 This multi-'phased project will install a new gate station on the west side of Spokane to serve the existing HP distribution and future replacement pipe that is part of the Kettle Falls HP main. The existing Kettle Falls Gate Station and high pressure (HP) Kettle Falls main has experienced significant encroachment due to growth in the north Spokane area. Sections of the main will be relocated to ensure continued safe reliable operation of the pipe system. The new gate station will improve the safety and reliability of operating the high pressure main and improve the gate station delivery capacity into the Kettle Falls HP system. Future phases of this project will re-route sections of the existing HP Kettle Falls main to improve system capacity and public safety. Qualchan Reinforcement - $1,200,000 This project will reinforce the southeast Spokane area west of Hwy 195 by looping the existing distributionsystem. The southeast Spokane distribution system experiences low pressures during high system demand in the winter. The area fails the gas planning model for a design day. Growth in the area has reduced Avista' sabili ty to reliably serve gas from its existing distribution system during a design day. This project will improve delivery pressure and position the system for future growth. Other Small Proj ects - $4,981,000 Please refer to the workpapers of Mr. DeFelice for detailed listing of proj ects. Jackson Prairie Storage: Jackson Prairie Storage Proj ect - $18,056,000 Avista and its partners started an expansion project at Jackson Prairie for deliverability that will be in service in the Fall of 2008. Mr. Vermillion describes this project in his testimony in this case. DeFelice, Di 22Avis ta Corporation 1 2 iV. ADJUSTMNT METHODOLOGY Q.What was the general approach to computing the 3 pro form adjustments for investment in capital projects? 4 A.The Company chose to track the 2007 and 2008 5 capital investments separately to simplify the computation 6 and to make it easier to follow. For each vintage, capital 7 additions, depreciation and DFIT were computed to derive 8 rate base at December 31, 2007 and December 31, 2008 and to 9 compute operating expenses in the pro forma rate year. 10 Q.What reports or data were used in the 11 computation? 12 A.The Company maintains results of operations 13 reports that are prepared for each service and jurisdiction 14 on an average of monthly averages (AM) basis and on an end 15 of period (EOP) basis that were used in this computation. 16 Actual 2007 plant additions were used from the plant 17 accounting system to determine the month of addition and 18 the amount of additions that were for revenue producing 19 projects.Capital additions for 2008 (described above) 20 were based on specific capital requirements for 2008. 21 Capital additions for 2008 that were for revenue producing 22 projects were separated out and excluded. The Company did 23 not include any 2009 capital additions in this filing.. 24 Q.Are the computations for all services and 25 jurisdictions the same? DeFelice, Di 23 Avista Corporation 1 A.Yes, they are.Because of this, only the Idaho 2 electric data will be used below to describe the 3 methodology for computing the adjustments. The adjustments 4 for Idaho gas were computed in a similar manner. 5 Q.Please exlain in detail the computation of the 6 adjustment as it relates to rate base. 7 A.There are three steps to determine the rate base 8 adjustment at December 31, 2007 and December 31, 2008, as 9 follows: 10 Step 1 - Adjust AH 2007 to EOP Decemer 31, 2007 11 (Pro For. Capital Additions 2007 Adjustment) 12 The first step was to determine an adjusted Decemer 13 31, 2007 EOP net plant balance that includes only the AM 14 revenue producing capital. The Company's Decemer 31, 2007 15 EOP results of operations reports was the starting point. 16 The gross plant at Decemer 31, 2007 at EOP includes 17 all revenue producing capital added in 2007.It is 18 necessary to remove only the average of monthly averages of 19 those addi tions ,since 2007 test year includes AM 20 customers and revenue (this is explained further below). 21 To accomplish this, all revenue producing capital additions 22 were deducted from the EOP balance and then the AM 23 additions were added back. The EOP gross plant at December 24 31, 2007 was computed as follows: 25 DeFelice, Di 24 Avista Corporation EOP Gross Plant at 12/31/07 per Results of Operations Less: EOP 2007 Revenue Producing Capital Additions ($OOO's) $912,978 ($9,637) Add: AMA 2007 Revenue Producing Capital Additions $4.138 EOP Adjusted Gross Plant at 12/31/07 $907.479 1 2 The pro forma capital additions 2007 adjustment in 3 Company witness Ms. Andrews' testimony at Exhibit No. 13, 4 Schedule 1, page 8, for gross plant of $27,983,000 was 5 computed by subtracting the AM gross plant balance used in 6 the filing of $879,496,000 from the calculated EOP adjusted 7 gross plant balance of $907,479,000.Additional details 8 regarding these adjustments are provided in Ms. Andrews' 9 workpapers . 10 This same process was used for both accumulated 11 depreciation and deferred income taxes,. to arrive at EOP 12 adjusted amount at Decemer 31, 2007 for the 2007 vintage 13 plant assets. The pro forma capital additions adjustment 14 for accumulated depreciation of $8,449,000 was computed by 15 subtracting the AM accumulated depreciation balance used 16 in the filing of $300,320,000 from the calculated EOP 17 adjusted accumulated depreciation balance of $308,769,000. 18 The pro forma capital additions adjustment for DFIT of 19 ($1,758,000) was computed by subtracting the AM DFIT DeFelice, Di 25 Avista Corporation 1 balance used in the filing of ($80,527,000) from the 2 calculated EOP adjusted DFIT balance of ($82,285,000). 3 4 Step 2 - Adjust 2007 vintage Plant to EOP Decemer 31, 2008 5 (Pro Form Capital Additions 2008 Adjustment - Part A) 6 The second step was to determine rate base at Decemer 7 31, 2008 for the 2007 vintage plant assets.Only 8 accumulated depreciation and deferred taxes are impacted. 9 Depreciation expense of $24,241,000 was computed on gross 10 plant at December 31, 2007, adjusted for projected 2008 11 retirements, using the average effective depreciation rates 12 by functional plant group.Depreciation expense of 13 $269,000 on the 2007 revenue producing capital additions 14 was removed, for a net increase to accumulated depreciation 15 of $23,972,000.The deferred tax impact on the 2007 16 vintage plant assets i adjusted for the revenue producing 17 capital additions, was ($3,726,000). These changes to rate 18 base at December 31, 2008 are added to the 2008 vintage 19 plant additions (discussed below) to derive the pro formal 20 capital additions adjustment for 2008, detailed in Ms. 21 Andrews' testimony at Exhibit No. 13, Schedule 1, page 8. 22 Addi tional details regarding these adjustments are provided 23 in Ms. Andrews' workpapers. 24 Step 3 - Add 2008 vintage Plant to EOP Decemer 31, 200825 (Pro Form Capital Additions 2008 Adjustment - Part B) 26 The capital additions for 2008 were sumarized by 27 functional plant categories and either directly assigned or DeFelice, Di 26 Avista Corporation 1 allocated to the services and jurisdictions based on 2 standard Company practices.The amount of revenue 3 producing capital additions in 2008 by service and 4 jurisdiction was excluded.The additions were further 5 sumarized by the month they are expected to be transferred 6 7 to plant in service.using the average effecti ve depreciation rates by functional plant group,AM 8 depreciation expense was computed in order to include the 9 partial year convention of depreciation that will actually 10 be recorded in 2008. 11 For the Idaho electric service, plant additions were 12 $29,475,000, depreciation expense was $542,000 and DFIT was 13 ($519,000). These 2008 costs are added to the 2007 vintage 14 plant 2008 costs (discussed above) to derive the pro forma 15 capital additions adjustment to rate base for 2008. 16 A sumary of the pro forma capital additions 2008 17 adjustment follows: ($OOO's)Part A Part B Total 2007 Vintage 2008 Vintage Adjustment to Plant Plant Rate Base Plant in Service $0 $29,475 $29,475 Accumulated Depreciation $23,972 $542 $24,514 DFIT ($3,726)($519)($4,245) 18 19 20 Q.What other impact does the 2007 and 2008 capital 21 additions have on this case in addition to the rate base 22 impact? DeFelice, Di 27 Avista Corporation 1 A.Depreciation expense and property taxes have been 2 computed for the 2007 and 2008 plant vintages for the pro 3 forma rate year. 4 The pro forma capital additions 2007 pre-tax 5 depreciation adjustment of $185,000 is computed as follows: 6 ($OOO's) Estimated full-year of depreciation expense in 2009 on the 2007 vintage plantbalance at December 31, 2008 $24,082 Less: Depreciation expense on 2007 revenue producing capital additions ($268) Total Depreciation Expense $23,814 2007 test year depreciation expense, adjusted for the depreciation true-upadjustment. $23,627State Taxes ii Pro forma Capital Additions 2007 Adjustment - Depreciation Expense $185 7 8 The pro forma capital additions 2008 pre-tax 9 depreciation and property tax adjustment of $1,563,000 is 10 computed as follows: 11 ($OOO's) Estimated full-year of depreciation expense in 2009 on the 2008 vintage plant balance at December 31, 2008, net of revenue producing capital additions $1,144 Estimated full-year of propert taxes in 2009 on the 2008 vintage plant balance at December 31, 2008, net of revenue producing capital additions $435State Taxes i1 Pro Forma Capital Additions 2008 Adjustment - Depreciation and Propert Tax ~ Expense 12 13 DeFelice, Di 28 Avista Corporation 1 2 V. OTHER CONSIDERATIONS Q.Did the Company consider the impact of 2009 3 capital additions? 4 A.Yes, it did.A similar process was used by the 5 Company to compute the adjustment that would be necessary 6 to include the AM capital additions for 2009, and to 7 adjust both the 2007 and 2008 vintage plant to June 30, 8 2009 (which represents an AM 2009 net rate base balance 9 for all plant through 2009.)Al though there is a case to 10 be made that the AM 2009 level of net rate base will be 11 used and useful and providing service to customers (i. e. 12 customers will be receiving benefit from the investment) 13 and therefore should be reflected in this case, the Company 14 has opted to only include the net effect of adjusting net 15 rate base to a pro forma December 31, 2008 level. 16 Q.What is the rationale behind the removal of 17 capital expenditures for connecting new customers? 18 A.The pro forma capital expenditures for 2008 that 19 the Company included in this filing excludes distribution 20 related capital expenditures made that are associated with 21 connecting new customers to the Company's system.The 22 Company recognizes the fact that new customers provide 23 incremental revenue that helps offset the revenue 24 requirements of the distribution related capital additions 25 that the Company incurs to provide service to those DeFel ice, Di 29 Avista Corporation 1 customers. These adjustments completely eliminated the AM 2 2007 and EOP 2008 capital activity related to new customer 3 connections in order to avoid an unintended mismatch of 4 revenues exceeding the cost to serve customers. 5 Q.In addition to excluding new customer related 6 capital additions, does the Company address the 2009/2007 7 revenue difference in other ways? 8 9 A.Yes.The production property adjustment (discussed in Company witness Ms.Knox's testimony) 10 addresses the production and transmission related retail 11 revenue that would be produced by the change in retail load 12 expected in 2009 compared to the 2007 normalized test year. 13 All production and transmission rate base and operating 14 expenses, including those from these capital additions 15 adjustments, are reduced in order to reflect the amount 16 needed to be recovered from 2007 sales volumes. 17 18 19 20 VI. CONCLUSION Q.What is the impact of the pro form adjustment? A.The proposed adjustment will result in a closer 21 matching of revenues to cost of service to customers at the 22 time new rates go into effect at the conclusion of this 23 general rate proceeding. Without the proposed adjustment, 24 the Company would not have the opportunity to earn its 25 allowed rate of return on investment during the rate year. DeFelice, Di 30 Avista Corporation 1 Q. 2 testimony? 3 A. Does this Yes, it does. conclude your pre-filed direct DeFelice, Di 31 Avista Corporation DAVID J. MEYER VICE PRESIDENT, GENERA COUNSEL, GOVERNENTAL AFFAIRS AVISTA CORPORATION P .0. BOX 3727 1411 EAST MISSION AVENU SPOKAE, WASHINGTON 99220-3727 TELEPHONE: (509) 495-4316 FACSIMILE: (509) 495-8851 REG~R&-3 PI'l 1:06 BEFORE THE IDAHO PUBLIC UTILITIES COMMISSION IN THE MATTER OF THE APPLICATION ) CASE NO. AVU-E-08-01 OF AVISTA CORPORATION FOR THE ) CASE NO. AVU-G-08-01 AUTORITY TO INCREASE ITS RATES ) AN CHAGES FOR ELECTRI C AN ) NATU GAS SERVICE TO ELECTRIC ) EXHIBIT NO. 11 AN NATU GAS CUSTOMERS IN THE )STATE OF IDAHO ) DAVE B. DEFELICE ) FOR AVISTA CORPORATION (ELECTRIC AN NATU GAS) Rising Utility Construction Costs: Sources and Impacts Prepared by: Marc W. Chupka Gregory Basheda The Brattle Group Prepared for: ti'~-- ~" The ~ FO;~!~?or: Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page i of 33 SEPTEMBER 2007 The Edison Foundation is a nonprofit organization dedicated to bringing the benefits of electricity to families, businesses, and industries worldwide. Furthering Thomas Alva Edison's spirit of invention, the Foundation works to encourage a greater understanding of the production, delivery, and use of electric power to foster economic progress; to ensure a safe and clean environment; and to improve the quality of life for all people. The Edison Foundation provides knowledge, insight and leadership to achieve its goals through research, conferences, grants, and other outreach activities. The Bratte Group The Bratte Group provides consulting services and expert testimony in economics, finance, and regulation to corporations, law firms, and public agencies worldwide. Our principals are internationally recognized experts, and we have strong partnerships with leading academics and highly credentialed industry specialists around the world. The Bratte Group has offces in Cambridge, Massachusetts; San Francisco; Washington, D.C.; Brussels; and London. Detailed information about The Brattle Group is available at ww.brattle.com.Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 2 of 33 (Ç 2007 by The Edison Foundation. All Rights Reserved under U.S. and foreign law, treaties and conventions. This Work canot be reproduced, downloaded, disseminated, published, or transferred in any form or by any means without the prior written permission of the copyrght owner or pursuant to the License below. . License - The Edison Foundation grants users a revocable, non-exclusive, limited license to use this copyrghted material for educational and/or non-commercial puroses conditioned upon the Edison Foundation being given appropriate attribution for each use by placing the following language in a conspicuous place, "Reprinted with the permission of The Edison Foundation." This limited license does not include any resale or commercial use. Published by: The Edison Foundation 701 Pennsylvania Avenue, NoW. Washington, D.C. 20004-2696 Phone: 202-347-5878 Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 3 of 33 Table of Contents Introduction and Executive Summary .................................................................................................... i Projected Investment Needs and Recent Infrastructure Cost Increases............................................. 5 Curent and Projected U.S. Investment in Electricity Infrastructue ......................................................................5 Generation...................................................................... ................................................................................. ........5 High-Voltage Transmission ...... ... ........ ....... ...... ........ ..... ................... ......... ........... ........... ................ .... ...................6 Distrbution .............................................................................................................................................................6 Constrction Costs for Recently Completed Generation .................... ....................... ........................ .......... ...........7 Rising Projected Constrction Costs: Examples and Case Studies .....................................................................10 Coal-Based Power Plants .................... ..........................................................................................................1 0 Transmission Projects ...................................................................................................................................11 Distrbution Equipment.................................................................................................................................12 Factors Spurring Rising Construction Costs ....................................................................................... 13 Material Input Costs..............................................................................................................................................13 Metals............................................................................................................................................................13 Cement, Concrete, Stone and Gravel... ..... ....... ..... ..... ...... ....... ............ ....... ............. .... ................................. .17 Manufactued Products for Utility Infrastrctue ....... ..... .............. ........... ........ ......... ...... ..... .... ... .......... .......18 Labor Costs.......................... ....................................................... ................................................................. .20 Shop and Fabrication Capacity .............................................................................................................................21 Engineerig, Procurement and Construction (EPC) Market Conditions ......... ............. ..... ..................... ..............23 Sumar Constrction Cost Indices. ............ ...... ....... ..... ................... ....... ...... ... ..... ..... ..... .... ......... ... ........ ........ ...24 Comparison with Energy Information Admstration Power Plant Cost Estimates ..... ....... ............... .................27 Conclusion ................................................................................................................................................31 Exhibit No. 11 Case Nos AVU-E-OB-Ol & AVU-G-OB-Ol D. DeFelice, Avista Schedule 1 Page 4 of 33 iii~ .. Introduction and Executive Summary In Why Are Electricity Prices Increasing? An Industr-Wide Perspective (June 2006), The Brattle Group identified fuel and purchased-power cost increases as the primar drver of the electrcity rate increases that consumers curently are facing. That report also noted that utilties are once again enterig an infrastrctu expansion phase, with signficant investments in new baseload generating capacity, expansion of the bulk transmission system, distrbution system enhancements, and new environmental controls. The report concluded that the industr could make the needed investments cost-effectively under a generally supportive rate environment. The rate increase pressures arising from elevated fuel and purchased power prices continue. However, another major cost drver that was not explored in the previous work also will impact electrc rates, naely, the substantial increases in the costs of buildig utility inastrctue projects. Some of the factors underlying these constrction cost trends are straightforward-such as shar increases in materials cost- while others are complex, and sometimes less transparent in their impact. Moreover, the recent rise in many utility constrction cost components follows roughly a decade of relatively stable (or even declinng) real constrction costs, adding to the "sticker shock" that utilities experience when obtainng cost estimates or bids and that state public utility commssions experience durng the process of reviewing applications for approvals to proceed with constrction. While the full rate impact associated with constrction cost increases wil not be seen by customers until infrastrctue projects are completed, the issue of rising constrction costs curently affects industr investment plans and presents new challenges to regulators. The purose of this study is to a) document recent increases in the constrction cost ofutility infrastrctue (generation, transmission, and distribution), b) identify the underlying causes of these increases, and c) explain how these increased costs wil translate into higher rates that consumers might face as a result of required infrastrctue investment. This report also provides a reference for utilties, regulators and the public to understand the issues related to recent constrction cost increases. In sumar, we find the following: · Dramatically increased raw materials prices (e.g., steel, cement) have increased constrction cost directly and indirectly though the higher cost of manufactued components common in utility infastrctue projects. These cost increases have priarly been due to high global demand for commodities and manufactued goods, higher production and transportation costs (in par owing to high fuel prices), and a weakenig U.S. dollar. · Increased labor costs are a smaller contributor to increased utility constrction costs, although that contrbution may rise in the futue as large constrction projects across the countr raise the demand for specialized and skilled labor over curent or projected supply. There also is a growing backlog of Exhibit No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 5 of 33 1 "I Introduction and Executive Summary project contracts at large engineering, procurement and constrction (EPC) firms, and constrction management bids have begu to rise as a result. Although it is not possible to quantify the impact on futue project bids by EPC firms, it is reasonable to assume that bids wil become less cost-competitive as new constrction projects are added to the queue. · The price increases experienced over the past several years have affected all electric sector investment costs. In the generation sector, all technologies have experienced substantial cost increases in the past three years, from coal plants to windpower projects. Large proposed transmission projects have undergone cost revisions, and distrbution system equipment costs have been rising rapidly. This is seen in Figue ES-l, which shows recent price trends in generation, transmission and distribution infrastrctue costs based on the Handy- Whitman Index~ data series, compared with the general price level as measured by the gross domestic product (GDP) deflator over the same time period.! As shown in Figue ES-l, inastrctue costs were relatively stable durng the 1990s, but have experienced substantial price increases in the past several years. Between January 2004 and January 2007, the costs of steam-generation plant, transmission projects and distrbution equipment rose by 25 percent to 35 percent (compared to an 8 percent increase in the GDP deflator). For example, the cost of gas tubines, which was fairly steady in the early part of the decade, increased by 17 percent durng the year 2006 alone. As a result of these cost increases, the levelized capital cost component of baseload coal and nuclear plants has risen by $20/MWh or more-substantially narrowing coal' s overall cost advantages over natual gas-fired combined-cycle plants-and thus liiiting some of the cost-reduction benefits expected from expanding the solid-fuel fleet. Figure ES-l National Average Utilty Infrastrcture Cost Indices uo -------------------- -Tota Plant.AII Sic Genention -Gas Twbgctoni -GOP Def -Transmiion 190 180 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - no - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - i~ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -s ~ 150.!ø- ê 140.. i 130 lIO 100 90 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 200 2005 200 2007 Year Sourcs: The Handy-WhitmanO Bulleli No. 165 and the U.S. Bure of Ecoomic Analysis. Simple averge of all regionl constrtion and equipment cosl indexes for the specified components. 1 The GDP deflator measures the cost of goods and services purchased by households, industr and governent, and as such is a broader price index than the Consumer Price Index (CPI) or Producer Price Index (pPI), which track the costs of goods and servces purchased by households and industr, respectively. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 6 of 33 ""2 Rising Utilty Construction Costs: Sources and Impacts · The rapid increases experienced in utility constrction costs have raised the price of recently completed infrastrctue projects, but the impact has been mitigated somewhat to the extent that constrction or materials acquisition preceded the most recent price increases. The impact of rising costs has a more dramatic impact on the estimated cost of proposed utility infrastrctue projects, which fully incorporates recent price trends. Ths has raised signficant concerns that the next wave of utilty investments may be imperiled by the high cost environment. These rising constrction costs have also motivated utilities and regulators to more actively pursue energy effciency and demand response initiatives in order to reduce the futue rate impacts on consumers. · Despite the overwhelmng evidence that constrction costs have risen and wil be elevated for some time, these increased costs are largely absent from the capital costs specified in the Energy Information Admstration's (BIA's) 2007 Annual Energy Outlook (ABO). The ABO generation capital cost assumptions since 2001 are shown in Figue ES-2. Since 2004, capital costs of all technologies are assumed to grow at the general price level-a pattern that contradicts the market evidence presented in this report. The growing divergence between the AEO data assumptions and recent cost escalation is now so substantial that the ABO data need to be adjusted to reflect recent cost increases to provide reliable indicators of curent or future capital costs. Figure ES.2 EIA Generation Construction Cost Estimates Convtiona Co Contional CC Conventional CT Wind Advanc Nuclear-ioce -Wind -AdvaNuclear -Conven1ODICT -GpPPefl 135 100 -GDP- Denator 130 125 120s ;: 115,!."." 110~"~ 105 .s 95 ~ --------------------- 85 2001 2002 2003 2004 2005 2006 Year Source: Dat collected from the U.S. Energy Infonoation Administation Assump,ion to ,he Annual Ener au,look 2002 to 2007 and from the U.S. Buru of Economic Analysis. Exhibit No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelicer Avista Schedule 1 Page 7 of 33 3~ ~ Projected Investment Needs and Recent Infrastructure Cost Increases Current and Projected U.S. Investment in Electricity Infrastructure The electrc power industr is a very capital-intensive industr. The total value of generation, transmission and distrbution infrastrctue for regulated electrc utilities is roughly $440 bilion (propert in service, net of accumulated depreciation and amortization), and capital expenditues are expected to exceed $70 bilion in 2007.2 Although the industr as a whole is always investing in capital, the rate of capital expenditues was relatively stable durng the 1990s and began to rise near the tu of the centu. As shown in Why Are Electricity Prices Increasing? An Industry-Wide Perspective (June 2006), utilties anticipate substantial increases in generation, transmission and distrbution investment levels over the next two decades. Moreover, the signficant need for new electrcity infrastrctue is a world-wide phenomenon: According to the World Energy Investment Outlook 2006, investments by power-sector companies thoughout the world wil total about $11 trilion dollars by 2030.3 Generation As of December 31, 2005, there were 988 gigawatts (GW) of electric generating capacity in service in the U.S., with the majority of ths capacity owned by electrc utilities. Close to 400 GW of ths total, or 39 percent, consists of natual gas-fired capacity, with coal-based capacity comprising 32 percent, or slightly more than 300 GW, ofthe US. electrc generation fleet. Nuclear and hydroelectrc plants comprise approximately 10 percent of the electric generation fleet. Approximately 49 percent of energy production is provided by coal plants, with 19 percent provided by nuclear plants. Natual gas-fired plants, which tend to operate as intermediate or peaking plants, also provided about 19 percent of US. energy production in 2006. The need for installed generating capacity is highly correlated with load growt and projected growt in peak demand. According to EIA's most recent projections, US. electrcity sales are expected to grow at an anual rate of about 1.4 percent through 2030. Accordig to the North American Electrc Reliabilty Corporation (NERC), U.S. non-coincident peak demand is expected to grow by 19 percent (141 GW) from 2006 to 2015. According to EIA, utilities wil need to build 258 GW of new generating capacity by 2030 to meet the 2 Net propert in service figue as of December 3 i, 2006, derived from Federal Energy Regulatory Commission (pERC) Form i data compiled by the Edison Electrc Institute (EEl). Gross propert is roughly $730 bilion, with about $290 billon already depreciated and/or amortized. Anual capital expenditue estimate is derived from a sample of 10K reports sureyed by EEL 3 Richard Stavros. "Power Plant Development: Raising the Stakes." Public Utilties Fortnightly, May 2007, pp. 36-42. Exhibit No. 11 Case Nos AVU-E-OB-Ol & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 8 of 33 5~ Projected Investment Needs and Recent Infrastructure Cost Increases projected growth in electrcity demand and to replace 01d, inefficient plants that wil be retired. EIA fuer projects that coal-based capacity, that is more capital intensive than natual gas-fired capacity which dominated new capacity additions over the last 15 years, wil account for about 54 percent of total capacity additions from 2006 to 2030. Natual gas-fired plants comprise 36 percent of the projected capacity additions in AEO 2007. EIA projects that the remainig 10 percent of capacity additions wil be provided by renewable generators (6 percent) and nuclear power plants (4 percent). Renewable generators and nuclear power plants, similar to coal-based plants, are capital-intensive technologies with relatively high constrction costs but low operating costs. High-Voltage Transmission The U.S. and Canadian electric transmission grid includes more than 200,000 miles of high voltage (230 kV and higher) transmission lines that ultimately serve more than 300 millon customers. Ths system was built over the past 100 years, primarly by vertically integrated utilities that generated and transmitted electricity locally for the benefit of their native load customers. Today, 134 control areas or balancing authorities manage electricity operations for 10cal areas and coordinate reliability through the eight regional reliability councils ofNERC. After a 10ng period of decline, transmission investment began a signficant upward trend staing in the year 2000. Since the beginning of 2000, the industr has invested more than $37.8 bilion in the nation's transmission system. In 2006 alone, investor-owned electrc utilities and stand-alone transmission companies invested an historic $6.9 bilion in the nation's grd, while the Edison Electrc Institute (EEl) estimates that utility transmission investments wil increase to $8.0 bilion during 2007. A recent EEl surey shows that its members pIan to invest $31.5 bilion in the transmission system from 2006 to 2009, a nearly 60-percent increase over the amount invested from 2002 to 2005. These increased investments in transmission are prompted in par by the larger scale of base 10ad generation additions that wil occur farer from 10ad centers, creating a need for larger and more costly transmission projects than those built over the past 20 years. In addition, new governent policies and industr strctues wil contrbute to greater transmission investment. In many pars of the countr, transmission plannng has been formally regionalized, and power markets create greater price transparency that highlights the value of transmission expansion in some instances. NERC projects that 12,873 miles of new transmission wil be added by 2015, an increase of 6.1 percent in the total miles of installed extra high-voltage (EHV) transmission lines (230 kV and above) in North America over the 2006 to 2015 period. NERC notes that ths expansion lags demand growth and expansion of generating resources in most areas. However, NERC's figures do not include several major new transmission projects proposed in the PlM Interconnection LLC, such as the major new lines proposed by American Electrc Power, Allegheny Power, and Pepco. Distribution While transmission systems move bulk power across wide areas, distrbution systems deliver lower-voltage power to retail customers. The distrbution system includes poles, as well as meterig, biling, and other related infrastrctue and softare associated with retail sales and customer care fuctions. Continual Exhibit No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 9 of 33 "'6 Rising Utility Construction Costs: Sources and Impacts investment in distrbution facilities is needed, first and foremost, to keep pace with growt in customer demand. In real terms, investment began to increase in the mid-1990s, preceding the corresponding boom in generation. This steady climb in investment in distrbution assets shows no sign of diminishing. The need to replace an aging infrastrctue, coupled with increased population growt and demand for power quality and customer service, is continuing to motivate utilties to improve their ultimate delivery system to customers. Continued customer load growt wil require continued expansion in distribution system capacity. In 2006, utilities invested about $17.3 bilion in upgrading and expandig distribution systems, a 32-percent increase over the investment levels incured in 2004. EEl projects that distrbution investment durg 2007 wil again exceed $17.0 billion. Whle much of the recent increase in distrbution investment reflects expanding physical infrastrctue, a substatial portion of the increased dollar investment reflects the increased input costs of materials and labor to meet curent distrbution inastrctue needs. Construction Costs for Recently Completed Generation The majority of recently constrcted plants have been either natual gas-fired or wind power plants. Both have displayed increasing real costs for several years. Since the 1990s, most of the new generating capacity built in the U.S. has been natual gas-fired capacity, either natual gas-fired combined-cycle unts or natual gas- fired combustion tubines. Combustion tubine prices recently rose sharly after years of real price decreases, while significant increases in the cost of installed natual gas combined-cycle combustion capacity have emerged during the past several years. Using commercially available databases and other sources, such as financial reports, press releases and governent documents, The Brattle Group collected data on the installation cost of natua 1 gas-fired combined-cycle generating plants built in the U.S. durng the last major constrction cycle, defined as generating plants brought into service between 2000 and 2006. We estimated that the average real constrction cost of all natual gas-fired combined-cycle units brought online between 2000 and 2006 was approximately $550/klowatt (kW) (in 2006 dollars), with a range of costs between $400/kW to approximately $L,OOO/kW. Statistical analysis confirmed that real installation cost was influenced by plant size, the tubine technology, the NERC region in which the plant was located, and the commercial online date. Notably, we found a positive and statistically signficant relationship between a plant's constrction cost and its online date, meang that, everying else equal, the later a plant was brought online, the higher its real installation cost. 4 Figue 1 shows the average yearly installation cost, in nominal dollars, as predicted by the regression analysis.5 This figue shows that the average installation cost of combined-cycle unts increased gradually from 2000 to 2003, followed by a fairly signficant increase in 2004 and a very significant escalation-more than $300/kW-in 2006. Ths provides vivid evidence of the recent shar increase in plant constrction costs. 4 To be precise, we used a "dumy" varable to represent each year in the analysis. The year-specific dumy variables were statistically significant and uniformly positive; i.e., they had an upward impact on installation cost. 5 The nominal form regression results are discussed here to facilitate comparson with the GDP deflator measure used to compare other price trends in other figues in this report. Exhibit No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 10 of 33 7~ Projected Investment Needs and Recent Infrastructure Cost Increases Figure 1 Multi-Variable Regrssion Estimation: Average Nominal Installation Costs Based on Online Year ($/kW) 1000 900 800 700 600 i 500 400 300 200 100 0 - --------------- --- --- ----------- -- - -------- ~~-- ------- - ---_.. ----- ------~""_.._--~+.._------- - - ~~ - - - - - ~~ - - - - - -~~ - - - - - ~,~ - - - - - - - - - - - - - - - - - - - - - - - - 2000 2001 2002 2003 Onlie Year 2004 2005 2006 Sour and Notes: . Data on summer capacity. tota insllatioo cost . tubine tehnology, commeral online date, and zip code for the perod 2000-2006 were collected frm commerially available databas and other source such as compay websites and 10k reort. Figue 2 compares the trend in plant installation costs to the GDP deflator, using 2000 as the base year. Over the period of 2000 to 2006, the cumulative increase in the general price level was 16 percent while the cumulative increase in the installation cost of new combined-cycle units was almost 95 percent, with much of this increase occurng in 2006, Figure 2 Multi-Variable Regression Estimation: Average Nominal Installation Costs Based on Online Year (Index Year 2000 = 100) 2S0 l..oDP Deflator I I.. Average Installation Costs I ,0," 200 ISO - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 5 - - - - - - -5 - - - - - - - - -,i; ,i;".. ,~ ",~~ - ' ,~.: ,i§,~""r§..~Io..,~~ --.... ;;,10 --100 SO - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - o 2000 2001 2002 2003 2004 200S 2006 OnUneYear ". 8 Sources and Notes: . Data on summer capacity. total instalation cost, turbine tehnology. commercial online date. and zip code for the perod 2000-2006 were collecte from commercially available databases and other sources such as company websiie and 10k reort. .. GDP Deflator data were collecte frm the U.S. Burau of Economic Analysis.Exhibi t No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 11 of 33 Rising Utility Construction Costs: Sources and Impacts Another major class of generation development durng ths decade has been wind generation, the costs of which have also increased in recent years. The Nortwest Power and Conservation Council (NCC), a regional plang council that prepares 10ng-term electric resource plans for the Pacific Nortwest, issued its most recent review of the cost of wind power in July 2006.6 The Council found that the cost of new wind projects rose substantially in real terms in the last two years, and was much higher than that assumed in its most recent resource pIan. Specifically, the Council found that the levelized lifecycle cost of power for new wind projects rose 50 to 70 percent, with higher constrction costs being the pricipal contrbutor to ths increased cost. According to the Council, the constrction cost of wind projects, in real dollars, has increased from about $1150/kW to $ 1300-$ 1700/kW in the past few years, with an unweighted average capital cost of wind projects in 2006 at $1,485/kW. Factors contrbuting to the increase in wind power costs include a weakening dollar, escalation of commodity and energy costs, and increased demand for wind power under renewable portfolio stadads established by a growing number of states. The Council notes that commodities used in the manufactue and installation of wind tubines and ancilar equipment, , including cement, copper, steel and resin have experienced significant cost increases in recent years. Figue 3 shows real constrction costs of wind projects by actual or projected in-service date. Figure 3 Wind Power Project Capital Costs l $2.000 CD....N $1,50 $1,00 $500 .. . Estimated overnight capital cost - Poly. (Estimated overnight capital cost) $0 200 2001 2002 20 20 2005 2006 2007 2008 2009 Service Year Source: The Nortwest Power and Conseration Council, "Bienial Revew of the Cost of Wind power" July 13, 2006. These observations were confirmed recently in a May 2007 report by the U.S. Deparent of Energy (DOE), which found that prices for wind tubines (the primary cost component of installed wind capacity) rose by more than $400/kW between 2002 and 2006, a nearly 60-percent increase. 7 Figure 4 is reproduced from the DOE report (Figue 21) and shows the signficant upward trend in tubine prices since 2001. 6 The NPCC planng studies and analyses cover the following four states: Washington, Oregon, Idaho, and Montaa. See "Biennal Review of the Cost of Wind power" July 13,2006, at ww.bpa.govÆnergylN/projects/post2006conservation/doc/Windpower_Cost_Review.doc.This study provides many reasons for windpower cost increases. 7 See U.S. Deparent of Energy, Annual Report on U.S. Wind Power Installation, Cost and Performance Trends: 2006 Figure 21, page 16. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 12 of 33 9~ Projected Investment Needs and Recent Infrastructure Cost Increases Figure 4 Wind Turbine Prices 1997 . 2007 $1.00 1$1'40 æ $1.200 !l "'1000.. 'l t i lrl ~ J~ $40~ ¡3 (¡00 ::~.::__d: .::. :... ..:. ...::::'..::':::.::::::::::::.:::::::: :::. .:::::::...:::.:..:.:::............. ::~: :~. ...::: :::.... . ... ........... ..... ..--.. ........ ..... ........ .,...... ..... ...........--.. ....... .:..... ......... .. ...A ~ . .. ........................ .......................... ,. . .......................................... ............................................................ " Orders ..1 00 MW . Orders from 1'00 - :lOll 'MW . Orders ;:300 MW - POl)'QmiiilTreoo Une fl JI-91 Ja-91 JI-£S 111-00 JI-01 111-02 JI-03 Ja-(\ Jm-Ii 111-06 JI-oi SWæ: ilyLstl i1tm. Mniiunaime DlI Rising Projected Construction Costs: Examples and Case Studies Although recently completed gas-fired and wind-powered capacity has shown steady real cost increases in recent years, the most dramatic cost escalation figures arse from proposed utilty investments, which fully reflect the recent, sharly rising prices of various components of constrction and installation costs. The most visible of these are generation proposals, although several transmission proposals also have undergone substantial upward cost revisions. Distrbution-Ievel investments are smaller and less discrete ("lumpy") and thus are not subject to similar ongoing public scrutiny on a project-by-project basis. Coal-Based Power Plants Evidence of the significant increase in the constrction cost of coal-based power plants can be found in recent applications fied by utilities, such as Duke Energy and Otter Tail Power Company, seekig regulatory approval to build such plants. Otter Tail Power Company leads a consortum of seven Midwestern utilties that are seeking to build a 630-MW coal-based generatig unt (Big Stone II) on the site of the existing Big Stone Plant near Milbank, South Dakota. In addition, the developers of Big Stone II seek to build a new high-voltage transmission line to deliver power from Big Stone II and from other sources, includig possibly wind and other renewable forms of energy. Intial cost estimates for the power plant were about $1 bilion, with an additional $200 millon for the transmission line project. However, these cost estimates increased dramatically, largely due to higher costs for constrction materials and labor.s Based on the most recent design refiements, the project, including transmission, is expected to cost $1.6 bilion. 8 Other factors contributing to the cost increase include design changes made by project parcipants to increase output and improve the unit's efficiency. For example, the voltage of the proposed transmission line was increased from 230 kV to 345 kV to accommodate more generation. "'10 Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 13 of 33 Rising Utility Construction Costs: Sources and Impacts In June 2006, Duke submitted a filing with the North Carolina Utilties Commssion (NCUC) seeking a certficate ofpublic convenience and necessity for the constrction of two 800 MW coal-based generating units at the site of the existing Cliffside Steam Station. In its intial application, Duke relied on a May 2005 prelimnary cost estimate showing that the two unts would cost approximately $2 bilion to build. Five months later, Duke submitted a second filing with a significantly revised cost estimate. In its second filing, Duke estimated that the two unts would cost approximately $3 bilion to build, a 50 percent cost increase. The North Carolina Utilities Commssion approved the constrction of one 800 MW unit at Cliffside but disapproved the other unit, priarly on the basis that Duke had not made a showing that it needed the capacity to serve projected native load demands. Duke's latest projected cost for building one 800 MW unt at Cliffside is approximately $1.8 bilion, or about $2,250/kW. When financing costs, or allowance for fuds used during constrction (AFUDC), are included, the total cost is estimated to be $2.4 bilion (or about $3,000/kW). Rising construction costs have also led utilties to reconsider expansion plans prior to regulatory actions. In December 2006, Westa Energy anounced that it was deferrg the consideration of a new 600 MW coal- based generation facility due to signficant increases in the estimated constrction costs, which increased from $1.0 bilion to about $1.4 bilion since the plant was first anounced in May 2005. Increased constrction costs are also affecting proposed demonstration projects. For example, DOE anounced earlier this year that the projected cost for one of its most prominent clean coal demonstration project, FutueGen, had nearly doubled.9 FutureGen is a clean coal demonstration project being pursued by a public-private parership involving DOE and an alliance of industral coal producers and electrc utilities. FutueGen is an experimental advanced Integrated Gasification Combined Cycle (IGCC) coal plant project that wil aim for near zero emissions of sulfu dioxide (S02), nitrogen oxides (NOx), mercur, parculates and carbon dioxide (C02), Its initial cost was estimated at $950 million. But after re-evaluating the price of constrction materials and labor and adjusting for infation over time, DOE's Office of Fossil Energy anounced that the project's price had increased to $1.7 bilion. Transmission Projects NST AR, the electric distrbution company that serves the Boston metropolitan area, recently built two 345 kV lines from a switchig station in Stoughton, Massachusetts, to substations in the Hyde Park section of Boston and to South Boston, respectively. In an August 2004 filing before ISO New England Inc. (lSO-NE), NSTAR indicated that the project would cost $234.2 million. In March 2007, NSTAR informed ISO-NE that estimated project costs had increased by $57.7 million, or almost 25 percent, for a revised total project cost of $292 millon. NST AR stated that the increase is drven by increases in both constrction and material costs, with constrction bids comig in 24 percent higher than intially estimated. NST AR fuer explained that there have been dramatic increases in material costs, with copper costs increasing by 160 percent, core steel by 70 percent, flow-fill concrete by 45 percent, and dielectrc fluid (used for cable cooling) by 66 percent. 9 U.S. Deparent of Energy, April 10, 2007, press release available at htt://ww .fossil.energy.gov Inews/techlines/2007 1070 19-DOE _Signs _ FutueGen _ Agreement.html Exhibit No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 14 of 33 11~ Projected Investment Needs and Recent Infrastructure Cost Increases Another aspect of transmission projects is land requirements, and in many areas of the countr land prices have increased substantially in the past few years. In March 2007, the Californa Public Utilities Commssion (CPUC) approved constrction of the Southern Californa Edison (SCE) Company's proposed 25.6-mile, 500 kV transmission line between SCE's existing Antelope and Pardee Substations. SCE initially estimated a cost of $80.3 millon for the Antelope-Pardee 500 kV line. However, the company subsequently revised its estimate by updating the anticipated cost of acquirig a right-of-way, reflecting a rise in California's real estate prices. The increased land acquisition costs increased the total estimate for the project to $92.5 millon, increasing the estimated costs to more than $3.5 million per mile. Distribution Equipment Although most individual distrbution projects are small relative to the more visible and public generation and transmission projects, costs have been rising in this sector as well. This is most readily seen in Handy- Whtman IndexlO price series relating to distribution equipment and components. Several important categories of distribution equipment have experienced shar price increases over the past three years. For example, the prices of line transformers and pad transformers have increased by 68 percent and 79 percent, respectively, between Januar 2004 and Janua 2007, with increases during 2006 alone of28 percent and 23 percent. io The cost of overhead conductors and devices increased over the past three years by 34 percent, and the cost of station equipment rose by 38 percent. These are in contrast to the overall price increases (measured by the GDP deflator) of roughly 8 percent over the past thee years. 10 Handy- WhitmaniC Bulletin No. i 65, average increase of six U.S. regions. Used with permssion. "-12 Exhibit No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 15 of 33 ~ Factors Spurring Rising Construction Costs Broadly speakg, there are four primar sources of the increase in constrction costs: (1) material input costs, including the cost of raw physical inputs, such as steel and cement as well as increased costs of components manufactued from these inputs (e.g., transformers, tubines, pumps); (2) shop and fabrication capacity for manufactured components (relative to curent demand); (3) the cost of constrction field labor, both unskilled and craft labor; and (4) the market for large constrction project management, i.e., the queuig and bidding for projects. Ths section wil discuss each of these factors. Material Input Costs Utility constrction projects involve large quantities of steel, alumum and copper (and components manufactued from these metals) as well as cement for foundations, footings and structues. All of these commodities have experienced substantial recent price increases, due to increased domestic and global demands as well as increased energy costs in mineral extraction, processing and transportation. In addition, since many of these materials are traded globally, the recent performance of the U.S. dollar will impact the domestic costs (see box on page 14). Metals After being relatively stable for many years (and even declining in real terms), the price of varous metals, including steel, copper and aluminum, has increased signficantly in the last few years. These increases are primarily the result of high global demand and increased production costs (includig the impact of high energy prices). A weakening U.S. dollar has also contrbuted to high domestic prices for imported metals and varous component products. Figue 5 shows price indices for primar inputs into steel production (iron and steel scrap, and iron ore) since 1997. The price of both inputs fell in real terms durng the late 1990s, but rose sharply after 2002. Compared to the 20-percent increase in the general inflation rate (GDP deflator) between 1997 and 2006, iron ore prices rose 75 percent and iron and steel scrap prices rose nearly 120 percent. The increase over the last few years was especially sharpbetween 2003 and 2006, prices for iron ore rose 60 percent and iron and scrap steel rose 150 percent. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 16 of 33 13~ Factors Spurring Rising Construction Costs Exchange Rates Many of the raw materials involved in utilty constrction projects (e.g., steel, copper, cement), as well as many major manufactued components of utility infrastrctue investments, are globally traded. Ths means that prices in the U.S. are also affected by exchange rate fluctuations, which have been adverse to the dollar in recent years. The chart below shows trade-weighted exchange rates from 1997. Although the dollar appreciated against other curencies between 1997 and 2001, the graph also clearly shows a substantial erosion of the dollar since the beginning of 2002, 10sing roughly 20 percent of its value against other major trading parers' curencies. Ths has had a substantial impact on U.S. material and manufactued component prices, as wil be reflected in many of the graphs that follow. Nominal Broad Dollar Index 135 130 US S=0..II uo..0\0\e..115..'C oS 110 105 100~~~~.~ ~~~ ~ ~ ~~ ~~## ""~ ",::' 4:~' ""~' ",~"i' 4.~ "".."'- ",;1- 4.","I :'.."I ",,,"I 4.",,, "".."I ",,,,, 4.~ ""'"..'t ",'i ~ 'i,' 4i ~ ..'t ",'i ~~ ..~ 4i ~~ ..'t 4i ~~ ..'t Source: U.S. Federal ReSOle Board. Stastical Release, Broad Index Date Foreign Exchange Value of the Dollar. "'14 Exhibi t No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 17 of 33 Rising Utility Construction Costs: Sources and Impacts Figure 5 Inputs to Iron and Steel Production Cost Indices 225 GDPDeßator wo - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 175 s.. i iso ~ ~ 125! 100 - 75 ---------- so 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 Year Sources: U.S. Gelogical Survey. Minerl Commodity Summes. and the U.S. Burau of Economic Analysis. The increase in input prices has been reflected in steel mill product prices. Figue 6 compares the trend in steel mill product prices to the general infation rate (using the GDP deflator) over the past lO years. Figue 6 shows that the price of steel has increased about 60 percent since 2003. Figure 6 Steel Mil Products Price Index 100 - 160 150 - - - - - - - - - - - - - - - - - - - - - - - - .- -- - - - - - - - - - - - - - - - - - - - - - - - - - 140 g 130 ~ lW ~ .s 110 90 80 1997 1998 1999 2000 2001 2002 2003 200 2005 2006 Year Sources: U.S. Geologica Surey, Miner Commodity Summares, and the U.S. Buru of Economic Analysis. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 18 of 33 15~ Factors Spurring Rising Construction Costs Various sources point to the rapid growt of steel production and demand in China as a primary cause of the increases in both steel prices and the prices of steelmakng inputs.!! China has become both the world's largest steelmaker and steel consumer. In addition, some analysts contend that steel companes have achieved greater pricing power, partly due to ongoing consolidation of the industry, and note that recently increased demand for steel has been driven largely by products used in energy and heavy industr, such as plate and strctual steels. From the perspective of the steel industr, the substantial and at least semi-permanent rise in the price of steel has been justified by the rapid rise in the price of many steelmakng inputs, such as steel scrap, iron ore, coking coal, and natual gas. Today's steel prices remain at historically elevated levels and, based on the underlying causes for high prices described, it appears that iron and steel costs are likely to remain at these high levels at least for the near futue. Other metals important for utilty infrastrctue display simlar price patterns: declining real prices over the first five years or so of the previous 10 years, followed by sharp increases in the last few years. Figue 7 shows that alumnum prices doubled between 2003 and 2006, while copper prices nearly quadrpled over the same period. Figure 7 Aluminum and Copper Price Indices 300 Copper 2~ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - s~ 200 ,!....e...~ i~ .5 GDPDeOator 100 ~ 1997 1998 1999 2000 2001 2002 2003 200 2005 2006 Year Sources: U.S. Geological Survey. Minerl Commodity Summaries. and the U.S. Bureau of Economic Analysis. 11 See, for example, Steel: Price and Policy Issues, CRS Report to Congress, Congressional Research Service, August 31, 2006. "'16 Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 19 of 33 Rising Utilty Construction Costs: Sources and Impacts These price increases were also evident in metals that contrbute to important steel alloys used broadly in electrical infrastrctue, such as nickel and tugsten. The prices of these display simlar patterns, as shown in Figue 8. FigureS Nickel and Tungsten Price Indices 350 3UO - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - ~O --------------------------------------------- ------ ~ J! ;. 200 ~ oS 150 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 100 - 50 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 Year Sources: U.S. Geological Surey, Minerl Commodity Summares, and the U.S. Bureau of Economic Analysis. Cement. Concrete. Stone and Gravel Large infrastrctue projects require huge amounts of cement as well as basic stone materials. The price of cement has also risen substantially in the past few years, for the same reasons cited above for metals. Cement is an energy-intensive commodity that is traded on international markets, and recent price patterns resemble those displayed for metals. In utilty constrction, cement is often combined with stone and other aggregates for concrete (often reinforced with steel), and there are other site uses for sand, gravel and stone. These materials have also undergone signficant price increases, priarily as a result of increased energy costs in extraction and transporttion. Figue 9 shows recent price increases for cement and crushed stone. Prices for these materials have increased about 30 percent between 2004 and 2006. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, AvistaSchedule i Page 20 of 33 17~ Factors Spurring Rising Construction Costs Figure 9 Cement and Crushed Stone Price Indices ISO i~ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - ~ ,!'" ê 120 ~.s 110 UO --------------------------------------------- - ---- 100 - - Crusbed Stone 90 1997 1998 1999 2OÐO 2001 2002 2003 2OÐ4 2005 2006 Year Sources: U.S. Geological Survey, Miner Commodity Summaries, and the U.S. Buru of Economic Analysis. Manufactured Products for Utility Infrastructure Although large utility constrction projects consume substantial amounts ofunassembled or semi-finished metal products (e.g., reinorcing bars for concrete, strctual steel), many of the components such as conductors, transformers and other equipment are manufactued elsewhere and shipped to the constrction site. Available price indices for these components.display similar patterns of recent shar price increases. Figue 10 shows the increased prices experienced in wire products compared to the inflation rate, according to the U.S. Bureau of Labor Statistics (BLS), highlghtig the impact of underlying metal price increases. Manufactued components of generating facilities-large pressure vessels, condensers, pumps, valves-have also increased sharly since 2004. Figue 11 shows the yearly increases experienced in key component prices since 2003. "'18 Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 21 of 33 Rising Utility Construction Costs: Sources and Impacts Figure 10 Electric Wire and Cable Price Indices 240 120 Nonferrous Wire 220 200 S 180;: ~; 160 _i:=~140 100 80 1997 1998 1999 2000 2001 2002 2003 2004 200S 2006 Year Sources: The U.S. Bureau of Labor Statistics and the U.S. Burau of Econmic Analysis. Figure 11 Equipment Price Increases 02003 ii2004 0200S 02006 0.4 0.8 0.7 0.6 O.S 0.3 0.2 0.1 ........ ...¡... ..~'"..-t ~I; .1;~., .#CJ~ Souce: YWha, What, Wher. How" presetaton by John Siegel, Bechtel Powe Co. Delivered at the coferenc entitled Next Generation of Generation (Dewey Ballantine LLP). May 4, 2006. 'l".,~~ø'C~" twOV"'~."~."i-" ..\-" tS.,,\~ v."w..'( rp" Exhibi t No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 22 of 33 19~ Factors Spurring Rising Construction Costs Labor Costs A signficant component of utility constrction costs is labor-both unskilled (common) labor as well as craft labor such as pipefitters and electricians. Labor costs have also increased at rates higher than the general inflation rate, although more steadily since 1997, and recent increases have been less dramatic than for commodities. Figure 12 shows a composite nationallabor cost index based on simple averages of the regional Handy-Whitman Index4; for common and craft labor. Between Januar 2001 and January 2007, the general inflation rate (measured by the GDP deflator) increased about 15 percent. During the same period, the cost of craft labor and heavy constrction labor increased about 26 percent, while common labor increased 27 percent, or almost twice the rate of general inflation.12 While less severe than commodity cost increases, increased labor costs contrbuted to the overall constrction cost increases because of their substantial share in overall utility infastrctue constrction costs. Figure 12 National Average Labor Costs Index 180 I - Labor for Hea Coston an Renforc Co -Commn La -Cr Labo -GOP Deflor I no - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 120 160 g 150 :E'"; 140 ti :š 130 110 100 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 Year Sourcs: The Handy.WhítmanO Bulletin, No. J65, and the U.S. Buru of Economic Anlysis. Simple average of all regional labor cost indice for the specified tys of labor. Although labor costs have not risen dramatically in recent years, there is growing concern about an emerging gap between demand and supply of skilled constrction labor-especially if the anticipated boom in utilty constrction materializes. In 2002, the Constrction Users Roundtable (CURT), sureyed its members and found that recruitment, education, and retention of craft workers continue to be critical issues for the industr.13 The average age ofthe curent constrction skilled workforce is rising rapidly, and high atttion rates in constrction are compounding the problem. The industr has always had high atttion at the entr- level positions, but now many workers in the 35-40 year-old age group are leaving the industr for a varety of reasons. The latest projections indicate that, because of atttion and anticipated growt, the constrction 12 These figues represent a simple average of six regional indices, however, local and regional labor markets can var substantially from these national averages. 13 Confonting the Skilled Constrction Workforce Shortage. The Constrction Users Roundtable, WP-401, June 2004, p. 1. Exhibit No. 11 Case Nos AVU-E-OB-Ol & AVU-G-OB-Ol D. DeFelice, Avista Schedule 1 Page 23 of 33 "'20 Rising Utility Construction Costs: Sources and Impacts industr must recruit 200,000 to 250,000 new craft workers per year to meet futue needs. However, both demographics and a poor industr image are working against the constrction industr as it tres to address this need. 14 There also could be a growing gap between the demand and supply of electrcallineworkers who maintain the electnc grid and who perform much of the labor for transmission and distrbution investments. These workers erect poles and transmission towers and install or repair cables or wires used to car electricity from power plants to customers. According to a DOE report, demand for such workers is expected to outpace supply over the next decade. is The DOE analysis indicates a significant forecasted shortage in the availability of qualified candidates by as many as 10,000 lineworkers, or nearly 20 percent of the curent workforce. As of 2005, lineworkers eared a mean hourly wage of $25/hour, or $52,300 per year. The forecast supply shortage wil place upward pressure on the wages earned by lineworkers. 16 Shop and Fabrication Capacity Many of the components of utilty projects-including large components like tubines, condensers, and transformers-are manufactued, often as special orders to coincide with paricular constrction projects. Because many of these components are not held in large inventones, the overall capacity of their manufactuers can influence the pnces obtained and the length of time between order and delivery. The pnce increases of major manufactued components were shown in Figue 11. Whle equipment and component pnces obviously reflect underlying matenal costs, some of the pnce increases of manufactued components and the delivery lags are due to maufactuing capacity constraints that are not readily overcome in the near term. As shown in Figue 13 and Figue 14, recent orders have largely elimnated spare shop capacity, and delivery times for major manufactued components have nsen. These constraints are adding to pnce increases and are diffcult to overcome with imported components because of the lower value of the dollar in recent years. The increased delivery times can affect utility constrction costs though completion delays that increase the cost of financing a project. In general, utilities commit substantial fuds during the constrction phase of a project that have to be financed either through debt or equity, called "allowance for fud used during constrction" (AFUDC). All else held equal, the longer the time from the initiation though completion of a project, the higher is the financing costs of the investment and the ultimate costs passed though to ratepayers. 14 Id., p. 1. 15 Worliorce Trends in the Electric Utilty Industr: A Report to the United States Congress Pursuant to Section 1101 of the Energy Policy Act of 2005. U.S. Departent of Energy, August 2006, p. xi. 16 Id., p. 5. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 24 of 33 21 ~ Factors Spurring Rising Construction Costs Figure 13 Shop Capacity 1.4 .2004 Shop Load . Current Shop Load . Anticipated 2006 Shop Load 1.2 0.8 0.6 0.4 0.2 ...,. 'i~V' ..,-rf!~.tI ,,0'co'~ Co" Source: "Who. What. Where, How" preentation by John Siegel, Behtel Power Corp. Deliver at the cofeence entitled Next Generation of Generation (Dew Ballantine LLP), May 4, 2006. coo'\e'Øto +0\0"",,,6' ~~~'o Figure 14 Delivery Schedules 120 .2004 .2005 .2006 80 100 ~ 60~ 40 20 if." ii~'to,C iI+0\0" V-~. Source: "Who, What. Where, How" presentation by John Siegel, Bechtel Powe Corp. Deliverd at the confeence entitled Nexi Generation of Generation (Dewey Ballantine LLP). May 4, 2006. .... ~'...'yio~~ ~..co'"....~..,,0" ~ co~'l' .,'I" .;(J .. ~~'"~~" ,,0'~.\.. Co. 'ftf "'22 Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 25 of 33 Rising Utilty Construction Costs: Sources and Impacts Engineering, Procurement and Construction (EPC) Market Conditions Increased worldwide demand for new generating and other electrc infastrctue projects, parcularly in China, has been cited as a signficant reason for the recent escalation in the constrction cost of new power plants. Ths suggests that major Engineerg, Procurement and Constrction (EPe) firms should have a growing backlog of utility infrastrctue projects in the pipeline. Whle we were unable to obtain specific information from the major EPC firms on their worldwide backlog of electrc utility infrastrctue projects (i.e., the number of electrc utility projects compared with other infrastrctue projects such as roads, port facilities and water infrastrctue, in their respective pipelines), we examined their financial statements, which specify the financial value associated with their backlog of infrastrctue projects. Figure 15 shows the cumulative anual financial value associated with the backlog of infrastrcture projects at the following four major EPC firms; Fluor Corporation, Bechtel Corporation, The Shaw Group Inc., and Tyco Intemational Ltd. Figue 15 shows that the anual backlog of infrastrctue projects rose sharly between 2005 and 2006, from $4.1 bilion to $5.6 billion, an increase of37 percent. This signficant increase in the anual backlog of infrastrctue projects at EPC firms is consistent with the data showing an increased worldwide demand for infrastrctue projects in general and also utility generation, transmission, and distribution projects. Figure 15 Annual Backiog at Major EPC Firms 65000 60000 ----------------------------------------------- ---- 55000 - .- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -i;.. ~ 50000= æ ~ 45000 .. is 40000e-0 35000 - - - - - - - - - - - - - .- - - - - - - - - - - - - - - - - - - - - - - - - - - 30000 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 25000 2002 2003 2004 2005 2006 Year Data are compiled from the Annual Repor of Fluor Corporation. Bechtel Corporion, The Shaw Grup Inc.. and Tyc Interational Ud. For Bechtel, the data represent new boked worl. as backlog i. not reorted. The growth in constrction project backlogs likely wil dapen the competitiveness of EPC bids for futue projects, at least until the EPC industr is able to expand capacity to manage and execute greater volumes of projects. This observation does not imply that ths market is generally uncompetitive-rather it reflects the limited ability of EPC firms with near-term capacity constraints to service an upswing in new project development associated with a boom period in infrastrctue constrction cycles. Such constraints, Exhibi t No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 26 of 33 23 'I Factors Spurring Rising Construction Costs combined with a rapidly fillng (or full) queue for project management services, lit incentives to bid aggressively on new projects. Although difficult to quatify, this lack of spare capacity in the EPC market wil undoubtedly have an upward price pressure on new bids for EPC services and contracts. A recent fiing by Oklahoma Gas & Electrc Company (OG&E) seeking approval of the Red Rock plant (a 950 MW coal unt) provides a demonstration of this effect. In Januar 2007, OG&E testimony indicated that their February 3, 2006, cost estimate of nearly $1,700/kW had been revised to more than $1,900/kW by September 29, 2006, a 12- percent increase in just nine months. More than half of the increase (6.6 percent) was ascribed to change in market conditions which "reflect higher materials costs (steel and concrete), escalation in major equipment costs, and a significant tightening of the market for EPC contractor services (as there are relatively few qualified firms that serve the power plant development market)."!? In the detailed cost table, OG&E indicated that the estimate for EPC services had increased by more than 50 percent durng the nine month period (from $223/kW to $340/kW). Summary Construction Cost Indices Several sources publish sumar constrction cost indices that reflect composite costs for varous constrction projects. Although changes in these indices depend on the actual cost weights assumed e.g., labor, materials, manufactued components, they provide useful sumar measures for large inastrctue project construction costs. The RSMeans Constrction Cost Index provides a general constrction cost index, which reflects primarly building constrction (as opposed to utility projects). This index also reflects many of the same cost drivers as large utility constrction projects such as steel, cement and labor. Figure 16 shows the changes in the RSMeans Constrction Cost index since 1990 relative to the general inflation rate. While the index rose slightly higher than the GDP deflator beginnng in the mid 1990s, it shows a pronounced increase between 2003 and 2006 when it rose by 18 percent compared to the 9 percent increase in general inflation. 17 Testimony of Jesse B. Langston before the Corporation Commssion of the State of Oklahoma, Cause No. PUD 200700012, January 17, 2007, page 27 and Exhibit JBL-9. Exhibi t No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 27 of 33 "'24 Rising Utility Construction Costs: Sources and Impacts Figure 16 RSMeans Historical Construction Cost Index IW - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 170 RSMeas Histoncal ISO - - - -- - - --- --- --- -- - - - ----- - - - - -Cõñšniõtr.ñC.stlna.i-- - - -- ---- ~ 140 II= ~ 130 e- II :š 120 110 100 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 90 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 200 Year Source: RSMeas, Heavy Constction Cost Data, 20th Annual Edition, 200. The Handy-Whtman Indexlt publishes detailed indices of utility construction costs for six regions, broken down by detailed component costs in many cases. Figures 17 through 19 show the evolution of several of the broad aggregate indices since 1991 compared with the general inflation index (GDP deflator). 18 The index numbers displayed on the graphs are for Janua 1 of each year displayed. Figue 17 displays two indices for generation costs: a weighted average of coal steam plant constrction costs (boilers, generators, piping, etc.) and a stad-alone cost index for gas combustion tubines. As seen on Figue 17, steam generation constrction costs tracked the general inflation rate fairly well though the 1990s, began to rise modestly in 2001, and increased signficantly since 2004. Between Janua 1,2004, and Januar 1,2007, the cost of constrcting steam generating units increased by 25 percent-more than trple the rate of inflation over the same time period. The cost of gas tubo generators (combustion turbines), on the other hand, actually fell between 2003 and 2005. However, during 2006, the cost of a new combustion tubine increased by nearly 18 percent-roughly 10 times the rate of general inflation. 18 Used with permission. See Handy-WhitmanO Bulletin, No. 165 for detailed data breakouts and regional values for six regions: Pacific, Plateau, South Central, Nort Central, South Atlantic and Nort Atlantic. The Figues shown reflect simple averages of the six regions. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, AvistaSchedule i Page 28 of 33 25~ Factors Spurring Rising Construction Costs Figure 17 National Average Generation Cost Index -Totl Plant-All Stem Genetion -Gas Turgcertol1 -GDP Deflato 180 no ------------------------------------------------- - 1~ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - S 158'" Jt 140'"'"e 130 :l'C ,! 120 110 100 90 1991 1992 1993 1994 1995 19% 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 Year Sources: The Hidy-WhitmCl Bullet, No. 165 an the U.S. Buru of Eeonomie Analysis. Simple average of all regional constcton and equipment cost indices for the specfied components. Figue 18 displays the increased cost of transmission investment, which reflects such items as towers, poles, station equipment, conductors and conduit. The cost of transmission plant investments rose at about the rate of inflation between 1991 and 2000, increased in 2001, and then showed an especially shar increase between 2004 and 2007, rising almost 30 percent or nearly four times the anual inflation rate over that period. Figure 18 National Average Transmission Cost Index 190 ~o - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 120 1~ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -- 160s ~ 150 .! ; 140 " ~ 130.s 110 100 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 90 1991 1992 1993 1994 1995 19% 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 Year Sources: The Handy-WhitmanCl Bulletn, No. 165, and th U.S. Bur of Ecnomie Analysis. Simple average of all regiona trission cost indice. "-26 Exhibi t No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 29 of 33 Rising Utilty Construction Costs: Sources and Impacts Figue 19 shows distribution plant costs, which include poles, conductors, conduit, transformers and meters. Overall distrbution plant costs tracked the general inflation rate very closely between i 99 i and 2003. However, it then increased 34 percent between Januar 2004 and Janua 2007, a rate that exceeded four times the rate of general infation. Agure 19 National Average Distribution Cost Index ISO i~ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - MO - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - BO ------~-------~------------------------------- ---- ~ .! 140; ;; 130.. :š 120 110 100 90 1991 1992 1993 1994 1995 1996 1991 1998 1999 2000 2001 2002 2003 2004 200 200 2001 Year Sources: The Handy-WbitanlO Bulletn, No. 165, and the U.S. Bureu of Ecomic Analysis. Simple averge of all regional distbution cos indices. Comparison with Energ Information Administration Power Plant Cost Estimates Every year, EIA prepares a long-term forecast of energy prices, production, and consumption (for electrcity and the other major energy sectors), which is documented in the Annual Energy Outlook (ABO). A companon publication, Assumptions to the Annual Energy Outlook, itemizes the assumptions (e.g., fuel prices, economic growt, environmental regulation) underlying EIA's anual long-term forecast. Included in the latter document are estimates of the "overnight" capital cost of new generating unts (i.e., the capital cost exclusive of financing costs). These cost estimates influence the tye of new generating capacity projected to be built durg the 25-year time horizon modeled in the ABO. The EIA capital cost assumptions are generic estimates that do not take into account the site-specific characteristics that can affect constrction costs signficantly.I9 Whle EIA's estimates do not necessarly provide an accurate estimate of the cost ofbuilding a power plant at a specific location, they should, in theory, provide a good "ballpark" estiate of the relative constrction cost of different generation 19 EIA does incorporate regional multipliers to reflect minor variations in constrction costs based on labor conditions. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 30 of 33 27~ Factors Spurring Rising Construction Costs technologies at any given time. In addition, since they are prepared anually, these estimates also should provide insight into constrction cost trends over time. The EIA plant cost estimates are widely used by industr analysts, consultants, academics, and policymakers. These numbers frequently are cited in regulatory proceedigs, sometimes as a yardstick by which to measure a utility's projected or incured capita costs for a generatig plant. Given this, it is importt that EIA's numbers provide a reasonable estimate of pi ant costs and incorporate both technological and other market trends that signficantly affect these costs. We reviewed EIA's estimate of overnght plant costs for the six-year period 2001 to 2006. Figure 20 shows EIA's estimates of the constrction cost of six generation technologies--ombined-cycle gas-fired plants, combustion tubines (CTs), pulverized coal, nuclear, IGCC, and wind-over the period 2001 to 2006 and compares these projections to the general inflation rate (GDP deflator). These six technologies, generally speaking, have been the ones most commonly built or given serious consideration in utility resource plans over the last few years. Thus, we can compare the data and case studies discussed above to EIA's cost estimates. Figure 20 EIA Generation Construction Cost Estimates -Convenion Col -ConntionalCC -CovcntionlCT -Wind -Advanc Nuclea -lGce -Wind -Advanc:Nuclea -ConvenlionlCT -ODPDeRllor 135 100 -GDP Deflator 130 125 120s ;; 115,! l. 110..~ 105 .s 90 --------------------- 85 2001 2002 2003 2004 2005 2006 Year Sources: Data collected from the Enegy Inormation Admnistration, Assumptions to the Annual Energ Outlook 2002 to 2007 and from the U.S. Bureau of Economic Analysis. The general pattern in Figure 20 shows a dramatic change in several technology costs between 2001 and 2004 followed by a stable period of growt until 2006. The two exceptions to this are conventional coal and IGCC, which increase by a near constant rate each year close to the rate of inflation thoughout the period. The data show conventional CC and conventional CT experiencing a shar increase between 2001 and 2002. After ths increase, conventional CC 1evels off and proceeds to increase at a pace near inflation, while conventional CT actually drops significantly before 2004 when it too levels near the rate of inflation. The Exhibit No. 11 Case Nos AVU-E-08-0l & AVU-G-08-0l D. DeFelice, Avista Schedule 1 Page 31 of 33 ~28 Rising Utilty Construction Costs: Sources and Impacts pattern seen with nuclear technology is near to the opposite. It falls dramatically until about 2003 and then increases at the same rate as the GDP deflator. Lastly, wind moves close to inflation until 2004 when it experiences a one-time jump and then flattens off through 2006. These patterns of cost estimates over time contradict the data and findings of this report. Almost every other generation constrction cost element has shown price changes at or near the rate of infation thoughout the early par of ths decade with a dramatic change in only the last few years. EIA appears to have reconsidered several technology cost estimates (or revised the benchmark technology tye) in isolation between 2001 and 2004, without a systematic update of others. Meanwhile, durg the period that overall constrction costs were rising well above the general inflation rate, EIA has not revised its estimated capital cost figues to reflect ths trend. EIA's estimates of plant costs do not adequately reflect the recent increase in plant constrction costs that has occured in the last few years. Indeed, EIA itself acknowledges that its estimated constrction costs do not reflect short-term changes in the price of commodities such as steel, cement and concrete.20 Whle one would expect some lag in the EIA data, it is troubling that its most recent estimates continue to show the constrction cost of conventional power plants increasing only at the general rate of inflation. Empirical evidence shows that the constrction cost of generating plants-both fossil-fired and renewable-is escalating at a rate well above the GDP deflator. Even the most recent EIA data fail to reflect importt market impacts that are driving plant constrction costs, and. thus do not provide a reliable measure of curent or expected constrction costs. 20 Annual Energy Outlook 2007, U.S. Energy Information Administration, p. 36. Exhibit No. 11 Case Nos AVU-E-08-01 & AVU-G-08-01 D. DeFelice, Avista Schedule 1 Page 32 of 33 29~ ~ Conclusion Constrction costs for electric utility investments have risen sharly over the past several years, due to factors beyond the industr's control. Increased prices for material and manufactued components, rising wages, and a tighter market for constrction project management services have contrbuted to an across-the- board increase in the costs of investig in utility infrastrctue. These higher costs show no immediate signs of abating. Despite these higher costs, utilities wil contiue to invest in baseload generation, environmental controls, transmission projects and distrbution system expansion. However, rising constrction costs wil put additional upward pressure on retail rates over time, and may alter the pace and composition of investments going forward. The overall impact on the industr and on customers, however, wil be borne out in varous ways, dependig on how utilities, markets and regulators respond to these cost increases. In the long ru, customers ultiately wil pay for higher constrction costs--ither directly in rates for completed assets of regulated companies, less directly in the form of higher energy prices needed to attact new generating capacity in organzed markets and in higher transmission tarffs, or indirectly when rising constrction costs defer investments and delay expected benefits such as enhanced reliability and lower, more stable long-term electricity prices. Exhibit No. 11 Case Nos AVU-E-OB-Ol & AVU-G-OB-Ol D. DeFelice, Avista Schedule 1 Page 33 of 33 31~ Ca p i t a l E x p e n d i t u r e s $2 5 0 $2 0 0 ~ $1 5 0 ::~E: $1 0 0 .S~ $5 0 $1 9 8 $2 0 0 $0 20 0 5 * * 20 0 2 0 0 7 20 0 8 Bu d g e t .G a s . Ot e r 20 0 9 Bu d g e t . G e n e r a t i o n . E l e c t r i c T & D .2 3 0 k V P r o j e c t . Gr o w t h . E n v i r o n m e n t a l .I S / I T ** 2 0 0 5 e x c l u d e s $ 5 7 . 5 f o r t h e p u r c h a s e o f t h e s e c o n d h a l f o f Co y o t e S p n n g s 2 a n d $ 1 7 . 8 f o r t h e o f f i c e b u i l d i n g p u r c h a s e . Ei l b l N o . 1 1 ca N o A v u . e - Q 1 & AV l - Q 1 D. D e . A v i SC u l e 2 . p . 1 o f 1 Av i s t a 2 0 0 8 C a p i t a l A d d i t i o n s D e t a i l ( S y s t e m ) ~ $ ( 0 0 0 ' 5 ) Ge n e r a t i o n : Ge n e r a l : Th e r m a l - C o l s t n p C a p i t a l A d d i t i o n s 3, 4 2 4 Co m p u t e r l N e t w o r k H a r d w a r e 5, 1 7 6 Th e r m l - K e t t l e F a l l s C a p i t a l P r o j e c t s 1, 1 3 1 Co m p u t e r S o f t w a r e 4, 0 4 9 Th e r m l - O t e r s m a l l p r o j e c t s 13 0 HV A C S y s t e m s I m p r o v e m e n t P r o j e c t 4, 9 9 0 Hy d r o - C a b i n e t G o r g e B y p a s s T u n n e l S t u d y 5, 3 5 3 Ba c k u p C o n i r l C e n t e r 1, 9 1 i Hy d r - C l a k F o r k I m p l e m e n t P M E A g r e e m e n t 2, 2 4 3 To o l s L a b & S h o p E q u i p m e n t 1, 2 0 0 Hy d r - N o x o n C a p i t a l P r o j e c t s 1, 6 2 8 St r u c t u r e s & I m p r o v e m e n t 1, 1 7 4 Hy d r - O t h e r s m a l l p r o j e c t s 1,4 6 1 Ot h e r s m a l l p r o j e c t s 4, 2 0 5 CS 2 J o i n t S h a r e P r o j e c t s 2, 2 0 0 22 , 7 0 5 CS 2 C a p i t a l P r o j e c t s 1, 4 0 0 Tr a n s p o r t a t i o n : Ot h e r s m a l l p r o j e c t s 80 7 Tr a s p o r t t i o n E q u i p m e n t 5, 9 8 5 19 , 7 7 8 El e c t r i c T r a n s D U s s i o n : Ga s U i s t r i b u t i o n : We s t P l a n s T r a n s m i s s i o n R e i n f o r c e 1,9 9 3 Ga s D i s t n b u t i o n N o n - R e v e n u e B l a e t 2, 2 9 7 Po w e r X f m . T r a m i s s i o n - B e n e w a h 1, 5 9 5 Ga R e p l a c e - S t & H w y 2, 0 6 0 Sp o k a e - C D A 1 1 5 k V L i n e R e l a y U p g r d e s 1, 2 4 7 Re p l a c e D e t e r i o r a t i n g G a s S y s t e m 1, 3 3 9 Ne z P e r e i 1 5 S u b - I n s t C a p a c i t o r B a n 75 1 Re i n f o r c e G a t e S t a t i o n P o s t F a l l s I d a h o 1, 5 0 0 Be a c o n 2 3 0 B u s C o n v e r t t o D B - D B 75 0 Ea t M e d f o r d R e i n f o r c e m e n t 7, 5 2 0 Lo l o 2 3 0 - R e b u i l d 2 3 0 k V Y a r d 73 7 Ro s e b u r g R e i n f o r c e m e n t 1, 7 0 0 Xs i n A i S w i t c h G r u n d M a t 69 7 Su t h e r l i n H P R e i n f o r c e m e n t 80 0 Ot h e r s m a l l p r o j e c t s 4, 3 1 6 Re - R t e K e t l e F a l l s F d r & G a t e S t a t i o n 1, 3 0 0 12 , 0 8 6 Qu a l c h a R e i n f o r c e m e n t , S p o k a e W A 1,2 0 0 El e c t r i c D i s t r i b u t i o n : Ot e r s m a l l p r o j e c t s 4, 9 8 1 El e c t n c D i s t n b u t i o n M i n o r B l a n k e t 5, 8 0 0 24 , 6 9 9 Wo o d P o l e M g m t 4, 9 2 3 Ga s S t o r a g e : El e c t n c U n d e r r o u n d R e p l a c e m e n t 3, 0 0 0 Ja c k s o n P r a r i e S t o r a g e 18 , 0 5 6 T & D L i n e R e l o c a t i o n 2, 2 5 0 Po w e r X f i n r - D i s t n b u t i o n 1, 7 5 5 To t a l N o n - R e v e n u e C a p i t a l 13 9 , 6 3 2 Fa i l e d E l e c t r i c P l a n t - U n k o w n 1, 7 5 0 DR E E P : D i s t R e l i a b i l t y & E n e r g y E f f c i e n c y P r o j e c t 1,5 0 0 Gr o w t R e v e n u e - P r o d u c i n g 43 , 2 6 2 Pl u m m e r - I n c r e a e C a p a c i t y / R e b u i l d 1, 4 2 5 C& W K e n d a l l P r o j e c t 3, 0 5 0 In d i a n T r a l i 1 5 - 1 3 k V S u b - C n s t r c t N e w S u b 2, 2 7 5 Cr i t c h f e l d i i 5 S u b - C o n s t r u c t 1, 6 1 4 Sp o k a e E l e c t n c N e t w o r k I n c r C a p a c i t y 1, 4 4 5 WS D O T H i g h w a y F r a c h i s e C o n s o l i d a t i o n 80 0 Ot h e r s m a l l p r o j e c t s 4, 7 3 7 36 , 3 2 3 To t a l C a p i t a l A d d i t i o n s i n 2 0 0 8 18 2 , 8 9 4 Ex h i b i t N o . 1 1 Ca s e N o s . A V U - E - 0 8 - 0 1 a n d A V U - G - 0 8 - 0 1 D. D e F e 1 i c e , A v i s t a Sc h e d u l e 3 , p . 1 o f 1