Model Conservation Standards

1. Model Conservation Standards Economic Analysis for New Single Family and Manufactured Home Construction May 5, 2009

2. What Are the “Model Conservation Standards”? • Act requires that Council’s Plan set forth model conservation standards (MCS) for: • New and existing buildings • Utility and government conservation programs • Other consumer actions slide 3

3. Model Conservation Standards – Decision Criteria • The Act requires that the MCS be set at levels that: • achieve all regionally cost-effective power savings (i.e., cost less than new generation ); and, • that are economically feasible for consumers, taking into account financial assistance that may be made available through Bonneville slide 4

4. Where Are We?(Thermal Shell Only)

5. Where Are We?Other Measures • Oregon Code • Requires ~50% of lamps be “CFL” equivalent • Requires use of PTCS duct sealing or higher efficiency Heat Pump (HSPF 8.5) • Washington Code • Will require (July 2010) “duct sealing” or interior ducts • Montana & Idaho • “Scheduled” to adopt 2009 IECC which requires better insulated above grade and below grade walls, duct tightening (0.08 cfm/sq.ft) and limits some “loophole” equipment tradeoffs.

6. Analytical Approach – Regional Cost Effectiveness • Use forecast of future market prices and load shape of savings to establish “energy value” • Include T&D Benefits to establish “capacity value” • Incorporate “risk” by adjusting future market value (+/-) based on portfolio analysis modeling results slide 9

7. Analytical Approach –Economic Feasibility • Use “lowest life cycle cost” code compliant home for each heating zone as “base case,” independent of space conditioning system type and including lighting and water heating. • Compute life cycle ownership cost of new home with increased levels of efficiency, including HVAC, DHW & lighting • Use “Monte Carlo” model to identify lowest average “life-cycle” cost package for each climate zone by testing multiple (1500+) combinations of values for major input assumptions, e.g. mortgage rates, retail electric rates, marginal tax rates, thermal shell efficiency, HVAC equipment efficiency, lighting efficiency, etc.

8. Scope of Analysis • New Single Family Construction • Analysis covers thermal shell, HVAC, Hot Water Heating & Lighting improvements to homes with: • Zonal Electric Heat • Air Source heat pumps • Electric Force-air furnaces with and without central air conditioning • Tested: • Eleven shell improvement measures • Three HVAC equipment efficiency levels • Three HVAC duct efficiency levels • Four Water Heating Efficiency Levels • Four lighting efficiency improvement levels

9. Efficiency Packages – Site Built Homes

10. Efficiency Packages – Manufactured Homes

11. Life Cycle Cost – Input Assumptions • Mortgage Rate and Term (Based on 1985 – 2007 data) • Consumer Discount Rate • Downpayment (Based on 1985 -2005 data) • Private Mortgage Insurance (for less than 20% down) • Retail Electricity Price (2007 utility specific average revenue/kWh) • Retail Electricity Escalation Rate (6th Plan/Global Insights) • State and Federal Income Tax Rate (2009 Rates) • State Property Tax Rate (2008-09 rates) • Homeowner’s Insurance Rate • Measure Incremental Cost • Measure Incremental Savings slide 10

12. Life Cycle Cost – “Uncertainty” Model • Problem • All of the major input assumptions are known to vary over a range, yet each new homebuyer will face unique combination of financial conditions • “Point estimates” for each assumption result in “Yes/No” answers, when the real conclusion is “sometimes OK, sometimes not so OK” • Solution • Use distributions of input assumptions that represent the “probability” that a specific value for each input will occur to compute the likelihood that a specific level of efficiency is economically feasible slide 11

13. Consumer Life Cycle Cost Model Considers Uncertainty

14. Life Cycle Cost (NPV 2006 000$) Cost for Input Set 2 Cost for Input Set 1 240 241 243 244 245 246 247 248 249 250 Distribution of Life Cycle Cost for A Single Upgrade Package Mean LCC Number of Observations

15. Zone 1 – Life Cycle Cost Distribution for “Best Package”

16. Base Case Life Cycle Cost – Single Family

17. Base Case Life Cycle Cost – Manufactured Home

18. Base Case Annual Energy Use* – Single Family *Includes space conditioning, water heating & lighting

19. Base Case Energy Use* – Manufactured Home *Includes space conditioning, water heating & lighting

20. Base vs Lowest Life Cycle Cost – Single Family

21. Base vs Lowest Life Cycle Cost – Manufactured Home

22. Single Family – Zone 1Energy Use

23. Single Family – Zone 2Energy Use *Zone 2 HP higher than zonal due to addition of air conditioning

24. Single Family – Zone 3Energy Use

25. Manufactured Home – Zone 1Energy Use

26. Manufactured Home – Zone 2Energy Use

27. Manufactured Home – Zone 3Energy Use

28. Base vs Lowest Life Cycle Cost – First Cost: Single Family

29. Base vs Lowest Life Cycle Cost – First Cost: Manufactured Home

30. Zone 1: Life Cycle Cost Minimum & Regional Cost-Effective Thermal Shell Packages

31. Zone 1: Life Cycle Cost MinimumHVAC, Lighting & DHW • HSPF 7.7 /SEER 13 Heat Pump w/ Interior Ducts & PTCS System Commissioning & Controls • Lighting Power Density = 0.6 Watts/sq.ft. • Heat Pump Water Heater • Average Use = 7,600 kWh/yr • LCC = $307,500 • LCC Savings = $6,748 ($6870 over HP Base) • First Cost Increase = $8,602 ($3,655 over HP Base) • Energy Savings = 8,310 kWh/yr (4,120 kWh/yr over HP Base)

32. Zone 2: Life Cycle Cost Minimum & Regional Cost-Effective Thermal Shell Packages

33. Zone 2: Life Cycle Cost MinimumHVAC, Lighting & DHW • HSPF 7.7 /SEER 13 Heat Pump w/ Interior Ducts & PTCS System Commissioning & Controls • Lighting Power Density = 0.6 Watts/sq.ft. • Heat Pump Water Heater • Average Use = 10,460 kWh/yr • LCC = $315,460 • LCC Savings = $9,150 ($10,380 over HP Base) • First Cost Increase = $8,600 ($3,655 over HP Base) • Energy Savings = 9,090 kWh/yr (10,040 over HP Base)

34. Zone 3: Life Cycle Cost Minimum & Regional Cost-Effective Thermal Shell Packages

35. Zone 3: Life Cycle Cost MinimumHVAC, Lighting & DHW • HSPF 7.7 /SEER 13 Heat Pump w/ Interior Ducts & PTCS System Commissioning & Controls • Lighting Power Density = 0.6 Watts/sq.ft. • Heat Pump Water Heater • Average Use = 12,455 kWh/yr • LCC = $242,300 • LCC Savings = $13,070 ($14,640 over HP Base) • First Cost Increase = $8,600 ($3655 over HP Base) • Energy Savings = 12,300 kWh/yr (12,425 kWh/yr over HP Base)

36. Zone 1 – Manufactured Home Base CaseLowest Life Cycle Cost Code Compliant Package • HVAC System – Heat Pump HSPF 7.7/SEER 13 • DHW – EF90 • Average Use (kWh) = 10,130 • First Cost = $8,730 • Minimum LCC = $99,750

37. Zone 1: Life Cycle Cost Minimum & Regional Cost-Effective Thermal Shell Packages

38. Zone 1: Manufactured Home Life Cycle Cost MinimumHVAC, Lighting & DHW • HSPF 7.7 /SEER 13 Heat Pump w/ Interior Ducts & PTCS System Commissioning & Controls • Lighting Power Density = 0.6 Watts/sq.ft. • Heat Pump Water Heater • Average Use = 5,430 kWh/yr • LCC = $93,705 • LCC Savings = $6,045 • First Cost Increase = $2,175 • Energy Savings = 4,700 kWh/yr

39. Zone 2 – Manufactured Home Base CaseLowest Life Cycle Cost Code Compliant Package • HVAC System – Heat Pump HSPF 7.7/SEER 13 • DHW – EF90 • Average Use (kWh) = 14,530 • First Cost = $8,730 • Minimum LCC = $104,170

40. Zone 2: Life Cycle Cost Minimum & Regional Cost-Effective Thermal Shell Packages

41. Zone 2: Manufactured Home Life Cycle Cost MinimumHVAC, Lighting & DHW • HSPF 7.7 /SEER 13 Heat Pump w/ Interior Ducts & PTCS System Commissioning & Controls • Lighting Power Density = 0.6 Watts/sq.ft. • Heat Pump Water Heater • Average Use = 7,165 kWh/yr • LCC = $95,625 • LCC Savings = $8,545 • First Cost Increase = $2,175 • Energy Savings = 7,360 kWh/yr

42. Zone 3 – Manufactured Home Base CaseLowest Life Cycle Cost Code Compliant Package • HVAC System – Heat Pump HSPF 7.7/SEER 13 • DHW – EF90 • Average Use (kWh) = 17,160 • First Cost = $8,730 • Minimum LCC = $103,075

43. Zone 3: Life Cycle Cost Minimum & Regional Cost-Effective Thermal Shell Packages

44. Zone 3: Manufactured Home Life Cycle Cost MinimumHVAC, Lighting & DHW • HSPF 7.7 /SEER 13 Heat Pump w/ Interior Ducts & PTCS System Commissioning & Controls • Lighting Power Density = 0.6 Watts/sq.ft. • Heat Pump Water Heater • Average Use = 8,175 kWh/yr • LCC = $91,230 • LCC Savings = $11,845 • First Cost Increase = $2,375 • Energy Savings = 8,985 kWh/yr

45. Background Slides

46. What is the “Surcharge Policy”? • The Council’s Plan must contain a recommendation to the Administrator regarding whether the a utility’s failure to achieve MCS savings should be subject to a surcharge on all of a its power purchases from Bonneville • Surcharges may not be less than 10%, nor greater than 50% of Bonneville’s rate. slide 2

47. The MCS - A Short History:Chapter 1 • Council adopted first MCS April 27, 1983 • Established space heating performance targets for new electrically heated residences for three Northwest Climate Zones • Less than 6,000 Heating Degree Day (HDD) • 6000 – 8000 HDD* • More than 8000 HDD* • MCS requirements were 40% better than toughest existing energy codes in region • Recommended that MCS be adopted by January 1, 1986 or BPA impose 10% surcharge on utilities serving non-complying areas slide 5 *Now Zone 2 = 6000 – 7499 HDD, Zone 3 = 7500 HDD and greater

48. The MCS – A Short History: Chapter 2 • 1983 – 1991 • Council sued by Seattle Master Builders contesting legality and level of the MCS • Conclusion – Ninth Circuit Rules for Council • Utilities demand that Bonneville sponsor “R&D” project (RSPD) to test “cost-effectiveness” of MCS • Conclusion – Bonneville finds MCS cost-effective • Bonneville, following Council’s Plan, sponsors “early code” adoption and “energy efficient” new homes marketing program (Super Good Cents) • Conclusion – Tacoma adopts MCS, the Region follows . . . slide 6

49. The MCS – A Short History: Chapter 3 • Current Status • Oregon and Washington have energy codes that meet or exceed the original MCS • Montana has adopted the 2003 International Energy Conservation Code (IECC) • Idaho jurisdictions commenced enforcement of 2006 the International Energy Conservation Code (IECC) on January 1, 2008 • The IECC codes require efficiency levels that are within 15% of the original MCS, meeting Council’s 85% “achievability” target. slide 7

50. The MCS – A Short History: Chapter 4 • It’s Time for Another Cost-Effectiveness Review • Issues: • Are there additional thermal shell measures that are “regionally cost-effective” and “economically feasible”? (5th Plan did not identify any) • Are there non-thermal shell measures (e.g. HVAC equipment, lighting, water heating, appliances) that should be considered for inclusion? • Should the MCS consider carbon mitigation cost risk independent of the incorporating future energy cost into the economic analysis? slide 8