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Distributed Generation Projections for High DG Case

Distributed Generation Projections for High DG Case. October 10, 2014. Arne Olson, Partner Nick Schlag, Sr. Consultant. Background. In a number of past efforts, E3 has worked with LBNL and WECC to establish input assumptions regarding distributed generation in study cycles:

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Distributed Generation Projections for High DG Case

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  1. Distributed Generation Projections for High DG Case October 10, 2014 Arne Olson, Partner Nick Schlag, Sr. Consultant

  2. Background • In a number of past efforts, E3 has worked with LBNL and WECC to establish input assumptions regarding distributed generation in study cycles: • In 2011-12, E3 worked with LBNL and WECC to develop estimates of DG potential for the SPSC’s 2022 and 2032 High DG/DSM cases • In 2014, E3 & LBNL developed an approach to project “market-driven” distributed generation in the WECC, which was used to inform the 2024 Common Case • WECC has requested projections of distributed generation consistent with High DG futures for the Western Interconnection to use in the SPSC’s 2024 and 2034 High DG/DSM cases • To develop these projections, E3 has used logic from both prior efforts to assess future DG installations

  3. Defining “Distributed Generation” • “Distributed” generation means different things to different people: • Behind-the-meter, e.g., customer-owned resource • Small utility or IPP owned resource that is connected at the distribution system and serves load downstream • Small resource that is connected at the distribution system and does not serve load downstream • Small resource that is connected to the sub-transmission system (i.e., low-voltage transmission) near load • Small resource that is located remote from load • Large resource that is located in load pocket and helps defer or avoid transmission investments • This analysis focuses on small scale solar PV installations that individual retail customers would install to avoid purchasing electricity from an electric utility • Does not include “wholesale DG” that a utility might procure to meet state DG targets

  4. Approaches to Developing High DG Assumptions • 2022/2032 High DG Case assumptions developed in two steps: • Estimate interconnection potential for each state • Make state-specific adjustments to interconnection potential to reflect differences in economic drivers of DG • 2024/2034 High DG Case assumptions derived by modeling customer decisions under a scenario favorable to distributed generation adoption • Use E3’s Market Driven DG Model to develop projections of adoption • Rely on estimates of interconnection potential as an upper bound

  5. Modeling Market-Driven DG

  6. Background • In prior transmission planning study cycles, WECC has incorporated distributed solar PV assumptions consistent with state policy goals • This framework ignores the potential for market-driven DG • With low PV costs, this could become a large amount of capacity • E3 and LBNL have developed a framework to incorporate market-driven DG into transmission planning studies Channels for Distributed Solar PV Adoption Program Goals (e.g. California Solar Initiative) Policy-driven DG, modeled in past WECC studies RPS Set-Asides (e.g. 30% DG set-aside in Arizona) New to WECC studies Market-Driven Adoption

  7. E3’s Market Driven DG Model • To provide inputs for WECC’s transmission planning studies, E3 has developed a model of DG deployment throughout the WECC footprint between present day and 2040 • Joint funding from WECC and LBNL through DOE’s ARRA grants • Input assumptions capture geographic variations in PV cost-effectiveness and state policy • State-specific PV costs • State-specific net metering policy • Capacity factors at a BA level • Utility-specific retail rates (and incentives where applicable) • The model also captures the changing cost-effectiveness of PV: • Continued declines in PV capital costs • Expiration of incentives & tax credits (e.g. ITC in 2017) • Escalation of retail rates • Expected changes to state net metering policies (e.g. California AB 327)

  8. 2024 Common Case Recommendations • The Market-Driven DG Model used to develop preliminary recommendations for customer-sited solar for the 2024 Common Case For the 2024 Common Case, TAS adjusted the recommended values (shown at left) downward by 20%

  9. High DG Case Recommendations

  10. Key Drivers of Market Driven DG Model • The main drivers of the modeled customer adoption of solar PV are: • Solar PV capital cost • Customer bill savings • Federal investment tax credit • State-specific incentive programs • State net energy metering caps • Utility system interconnection potential • Changing the assumptions for each of these parameters provides the basis for exploring alternative projections Affect customer decision to invest in solar PV Limit total penetration on a utility’s system

  11. Overview of Assumptions • High DG projections are developed by relaxing existing NEM caps and assuming achievement of aspirational solar PV cost reductions Assumption Reference Case High DG Case Net Metering Caps • Current Policy • Current NEM caps remain in place • California cap lifted after 2016 • NEM Caps Removed • All NEM caps lifted • Limits associated with interconnection potential enforced Solar PV Cost Trends • Moderate Reductions • Cost trajectory derived by E3 for TEPPC planning studies • Aspirational Reductions • Sunshot goals achieved by 2020

  12. Treatment of NEM Caps • In the Reference Case, each state’s NEM cap was enforced according to current policy • High DG case assumes current NEM caps are removed, allowing installations of DG in each utility’s service territory up to its ‘Interconnection Potential’

  13. Interconnection Potential Background • To estimate interconnection potential across the WECC, E3 leveraged results from a 2012 analysis, Technical Potential for Local Distributed Photovoltaics in California • Study produced estimates of the amount of “local” distributed PV (LDPV) potential under different interconnection standards in California: • Rule 21 (Current Policy):sum of rated capacity of interconnections on a feeder may not exceed 15% of the feeder’s peak load • 30% Rule:same as (1), but with constraint relaxed to 30% • Max w/o Curtailment:the maximum capacity that can be installed on a feeder for which all generation will serve load on that feeder (e.g. no required backflow or curtailment) • In 2012 study cycle, E3 generalized these results to the WECC BAs; the same method is used to determine limits in this study cycle • 30% Rule for 2024 High DG projections • Max w/o Curtailment for 2034 High DG projections

  14. Capital Cost Trajectories • Reference case cost reduction trajectory derived through application of learning curve approach • 20% learning rate on modules; 15% on BOS • IEA medium-term renewable energy outlook • Adopted by TEPPC • Aspirational case cost reduction trajectory assumes achievement of Sunshot goals by 2020 • $1.50/W residential • $1.25/W commercial

  15. Other Key Assumptions • No changes in retail rate design • Surplus NEM generation is compensated at full retail rate • EXCEPTION: in California, after 2017, exports are assumed to be compensated at avoided cost (see Slide 30) • Retail rates escalate at 0.5% per year in real terms • Federal ITC sunsets in 2017 • Credit reduces to 10% of capital costs thereafter • Current state incentive programs sunset after current NEM cap is exceeded • e.g. Washington & Oregon (see Slide 31)

  16. 2024 Projections • Reference Case projections Incremental Additions • High DG Case projections Incremental Additions

  17. Comparison to 2022 High DG Recommendations • 2022 and 2024 High DG projections have similar quantities of distributed generation capacity, but show a regional shift • Relative increases in California, Colorado • Slight decreases in states in the Pacific Northwest Notable increases from 2022 Notable decreases from 2022

  18. 2034 Projections • Reference Case projections • High DG Case projections

  19. Detailed Projections by Load Area

  20. 2024 High DG Projections • Total capacity: 22,648 MW

  21. 2034 High DG Projections • Total capacity: 31,650 MW

  22. Thank You! Energy and Environmental Economics, Inc. (E3)101 Montgomery Street, Suite 1600San Francisco, CA 94104Tel 415-391-5100Web http://www.ethree.com

  23. Market-Driven DG: Methodology and Assumptions

  24. General Model Logic • E3’s Market-Driven DG model combines a customer decision model with policy targets and NEM caps to provide a comprehensive assessment of behind-the-meter solar PV in the Western Interconnect • Modeling steps: • Assess potential size of distributed solar PV market based on economics • Adjust forecast upward to meet any policy targets • Limit total installations based on state net metering caps

  25. Step 1: Market-Driven Adoption • Determine max market share • Determine payback period • Fit logistic curve • Apply to technical potential

  26. Calculating the Payback Period • The payback period is the first year in which a customer who choose to install solar PV will have a net positive cash flow • To determine the payback period, E3 considers: • System capital costs: costs of purchasing & installing a PV system • Operating & maintenance costs: costs of year-to-year maintenance, including inverter replacement • Federal tax credits: investment tax credit (30% until 2017; 10% thereafter) • State & local incentives: up-front & performance-based incentives, vary by utility & state • Bill savings: reductions monthly energy bills, vary by utility • Green premium: a non-financial value that a customer derives from having invested in solar PV (assumed to be 1 cent/kWh)

  27. Solar PV Capital Costs by Installation Vintage • Installed PV cost assumptions based on draft recommendations for PV capital costs developed by E3 • Presented to TAS on December 19 • Future cost reductions primarily reflect lower balance-of-systems costs

  28. Solar PV Costs by State • System average costs are adjusted for each state to capture regional variations in costs • Regional adjustments based on LBNL’s Tracking the Sun VI Where Tracking the Sun VI did not report PV costs, costs were interpolated based on the Army Corps of Engineer’s Construction Works Cost Index

  29. Avoided Energy Cost • All WECC states currently allow net metering, under which a customer is compensated for PV output based on its retail rate • This is the primary economic benefit to a customer who chooses to install distributed PV • Market adoption model includes utility-specific rate information for 30 large utilities in the West (a subset are shown below) • For other smaller utilities, a state-specific average retail rate is used California: IOUs’ high tiered rates provide strong incentive to customers Southwest Rocky Mountains Northwest: Low-cost hydropower keeps rates low General trend in retail rates

  30. Changes to Avoided Energy Cost over Time • E3 assumes that utilities continue to compensate customers at their full retail rate throughout the analysis horizon with one exception • Real escalation of 0.5% per year is assumed • California’s AB 327 directs the CPUC to implement a standard NEM tariff beginning in July 2017 • As this tariff has not yet been defined, E3 has chosen to model it in the following manner: • All generation consumed on-site is compensated at the customer’s retail rate • 50% for residential systems, 70% for commercial systems (based on CPUC NEM study) • All generation exported to the grid is compensated at the utility’s long-run avoided cost (based on a CCGT)

  31. State-Specific Incentives • Payback period is also heavily influenced by state incentive programs • E3’s model captures the impact of two large incentive programs: • Renewable Energy Cost Recovery Program (WA) • Performance-based incentive capped at $5,000 per year • Program ends in 2020 • Residential Energy Tax Credit (OR) • Incentive of $2.1/W-dc, capped at $6,000 • Program ends in 2018 • Note: incentives linked to specific policy targets (e.g. set-asides, program goals) are not modeled explicitly and are instead accounted for by adjusting market-driven forecast upward to meet policy goals

  32. Sample Payback Period Results, 2013 Residential Systems • Payback periods vary widely across the WECC geography as a function of: • System costs • Incentives • Retail rates • Capacity factors

  33. Modeling Solar PV Adoption • NREL’s Solar Deployment System (SolarDS) model provides one of the more transparent forecasts of PV adoption: • “…a geospatially rich, bottom-up, market-penetration model that simulates the potential adoption of photovoltaics (PV) on residential and commercial rooftops in the continental United States through 2030” • Much of the logic used in the Adoption Module has been adapted from SolarDS: • Maximum market share as a function of payback period • Logistic curves for adoption Documentation for SolarDS model: http://www.nrel.gov/docs/fy10osti/45832.pdf (Figures taken from this document)

  34. Assumed Payback Curves • Payback curves are based on functional forms documented in SolarDS model

  35. Assumed Technical Potential • E3 calculates technical potential by specifying: • The percentage of total customers that could feasibly install solar PV (50% for residential and commercial) • The representative system size for a typical install (4 kW for residential; 50 kW for commercial) • Resulting assumed technical potential aligns well with NREL’s assessment of rooftop PV technical potential on a state level: • Total technical potential is approximately 150 GW in 2010 Source: U.S. Renewable Energy Technical Potentials: A GIS-Based Analysis (NREL)

  36. Step 2: Policy Adjustments • A large number of states have enacted policies to encourage the deployment of distributed solar PV • In cases where the market-based adoption forecast falls short of state policy targets, upward adjustments are made to reflect achievement of current policy • Assumes utilities will fund programs to reach targets

  37. Policy Adjustments • For each utility, initial market-driven DG forecast is adjusted upward in each year it is short of policy targets • Illustrative example shown for APS

  38. Step 3: Adjust for Net Metering Policy • Common Case projections assume all current NEM caps remain in place • Arizona, Colorado, Montana, New Mexico, Wyoming: no cap • Oregon & Washington: 0.5% of utility peak • Idaho: 0.1% of utility peak • Nevada: 3% of utility peak • California: 5% of noncoincidentpeak (currently) • Common Case projections assume these caps remain in place throughout the analysis • Exception: California’s AB 327 lifts the existing NEM cap beginning in 2017 with the implementation of a standard NEM tariff

  39. NEM Adjustments • For each utility whose installed capacity would be constrained by a NEM cap, installation forecast is adjusted downward to the limit • Illustrative example shown for Puget Sound

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