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Agenda. Introduction, scope, context Terminology, high-level approach Methodology, Inputs, Assumptions Portfolio development Discounted core Environmental scoring PV assessment Transmission sizing Timing assessment Results Next steps for analysis Schedule, Summary.
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Agenda • Introduction, scope, context • Terminology, high-level approach • Methodology, Inputs, Assumptions • Portfolio development • Discounted core • Environmental scoring • PV assessment • Transmission sizing • Timing assessment • Results • Next steps for analysis • Schedule, Summary
Transmission Bundles (review) • Resources in CREZs are aggregated into transmission bundles in the following order: • Existing transmission bundle • Minor upgrade bundle • New transmission bundle • Discounted core projects given first priority to fill each transmission bundle • Non-core Commercial projects given next priority to fill the New Transmission bundle • Any remaining transmission capacity in the bundle is allocated to the lowest-scoring generic projects • Up to 3000 MW of new transmission allowed for each CREZ
Transmission sizing and cost • Weakness of previous study: assumed no capacity on existing transmission system; upgrades essentially all single or double circuit 500kV lines “trunklines” • Updates: • ISO high-level assessment of capacity from various CREZs 1.) over existing system; 2.) over relatively minor new upgrades • Additional lines on case-by-case basis: 500kV for large and out-of-state zones, smaller lines for smaller zones close to loads. Cost = function of length and capacity • Incorporation of RETI work has been difficult – many CREZs tied to single line segments; many line segments tied to single CREZs; but additional detail would help in cost and timing review
Transmission sizing and cost • See: • California ISO assessment of capacity over existing system and minor upgrades • Zaininger Engineering assessment of capacity over RETI lines • Available here: http://www.cpuc.ca.gov/PUC/energy/Procurement/LTPP/ltpp_history.htm
Agenda • Introduction, scope, context • Terminology, high-level approach • Methodology, Inputs, Assumptions • Portfolio development • Discounted core • Environmental scoring • PV assessment • Transmission sizing • Timing assessment • Results • Next steps for analysis • Schedule, Summary
33% RPS Implementation Analysis • Timelines created for the 33% Reference Case – not for any of other 3 cases • Timeline 1: Historical experience, reforms/risk • Timeline 2: Reforms, no risks • Timeline 3: Reforms + external risks • Goal: Better understand the tradeoffs between cost, risk, and time associated with particular procurement strategies • Identify market and regulatory barriers to renewable development • Identify solutions and their impacts on achievement of a 33% RPS
Example – Aspen Environmental Group research into generation timelines
Timeline Tool • Black & Veatch tool under development to automate timing considerations, create scenario timelines and supply curves • Generic generation scheduling factors according to: • Technology • Project size • Land type • Location • Generic transmission schedules for several types of lines • User has ability to change/define inputs and timing assumptions; change default schedules and MW counts based on technology and other factors, etc.
Timeline Tool • Data already incorporated • Contracts approved and pending approval – basic project information • Proxy projects – RETI, others to be added • ED staff updating tool for consistency with new scenarios still being added • See mock-up of tool here: http://www.cpuc.ca.gov/PUC/energy/Procurement/LTPP/ltpp_history.htm
Generic generation timing assumptions • Little change from Implementation Analysis:
Building scenario timelines • Each zone and transmission bundle/increment is assigned to a transmission schedule • no generation in that bundle is available before transmission • Non-CREZ, distributed resources, and resources accessing existing capacity not reliant on transmission • available per contract or generic generation schedule • Each scenario is assigned an “online date” according to the availability of the last generation resource chosen for that scenario • No “bottlenecks” considered now; what assumptions are appropriate?
Timeline Tool – Features to Come • Aggregated portfolios for alternative cases presented with summary timelines and yearly generation charts • Timelines for individual projects available for review • Project development phases are broken out Example Only
Timeline Tool – Features to come (cont’d) • Yearly generation charts can be broken out by viability class – high, medium, and low viability Example Only
Agenda • Introduction, scope, context • Terminology, high-level approach • Methodology, Inputs, Assumptions • Portfolio development • Discounted core • Environmental scoring • PV assessment • Transmission sizing • Timing assessment • Results • Next steps for analysis • Schedule, Summary
Total Net Cost* by Scenario * Sum of each resource’s net cost, not the same as the portfolio cost calculated in 2009
Cost-Constrained Case: Resources by Location • Key Indicators: • Total Solar MW: 5,800 • Out-of-State RECs: 25% • Earliest compliance year: 2021 • Much less solar than other cases
Environmentally-Constrained Case: Resources by Type • Key Indicators: • Total Solar MW: 19,500 (16,800 PV) • Out-of-State RECs: 10% • Earliest compliance year: 2020 • Large-scale remote solar requires new transmission corridors • Remote small-scale PV is the marginal resource – not all is picked
Time-Constrained Case: Resources by Type • Key Indicators: • Total Solar MW: 8,600 MW • Out-of-State RECs: 33% • Earliest compliance year: 2015 • Largest proportion of out-of-state resources • Out-of-state wind is a good resource if time is the only driver
Trajectory Case: Resources by Type • Key Indicators: • Total Solar MW: 6,800 MW • Out-of-State RECs: 20% • Earliest compliance year: 2019 • Most balanced scenario • Very few generic projects
Agenda • Introduction, scope, context • Terminology, high-level approach • Methodology, Inputs, Assumptions • Portfolio development • Discounted core • Environmental scoring • PV assessment • Transmission sizing • Timing assessment • Results • Next steps for analysis • Schedule, Summary
IOU-specific allocations • To provide direct input into 2010 LTPP, statewide portfolios will need to be “allocated” each IOU. • Proposed approach: • Remove any POU resources from each portfolio; • Allocate public ED database projects to the IOUs with which those projects have signed contracts (PUBLIC); • Allocate confidential ED database projects to the IOUs with which those projects are negotiating contracts (CONF.); • Allocate generic projects to load on a pro-rata basis for each resource type in each zone (PUBLIC); • Aggregate each IOU’s contracted, short-listed and generic project allocations to generate IOU-specific RPS portfolios (PUBLIC, provided the aggregation sufficiently masks the confidential data).
Integration assessment • California ISO developing model that estimates integration needs and costs associated with 33% Reference Case from 2009 Implementation Analysis • PG%E has developed Renewable Integration Model (RIM) tool – not as analytically comprehensive, but simpler and spreadsheet-based. • Tools may be introduced into LTPP proceeding later this year. Possible next steps: • Parties vet methodologies and results • Models are re-run to estimate integration needs of final RPS scenarios adopted in Scoping Memo • Results inform Commission consideration of the amount and types of resources to authorize in 2010 LTPP
Overview • PG&E and CAISO integration studies are considering capital costs of resources needed for intermittent renewable resource integration in addition to variable costs of increased operating reserves • Capital costs driven by assumptions about how much capacity would already have been online during the planning year • Online capacity is a function of Planning Reserve Margin • For intermittent renewables, Net Qualifying Capacity (NQC) is used to estimate contribution toward meeting peak demand • Issue: Capacity credit of intermittent renewables, particularly solar, depends on how much is online
CAISO Load June 20, 2008 Load (MW) Hour Ending (HE) California Peak Load Hours • In California, peak loads occur during summer days when there are high air conditioning loads • Solar has been considered to have a high capacity credit because maximum output occurs during the hot day-time hours when load is highest The figure above shows the CAISO load profile on June 20, 2008 which includes the annual system peak hour, 3-4 PM
Load (MW) Load (MW) HE HE Peak Load Day (June 20, 2008) with High Solar Penetration • “Must Run Gen” is an approximation of nuclear, coal, and minimum hydro • Solar resources are simulated fixed-tilt utility-scale PV and solar through with no storage at high penetration for June 20, 2008 • High penetration of solar generation moves the “net peak” load hour, when load must be met from dispatchable generation, into the nighttime
Top 500 Net Load Hours under high PV Penetration Levels • As PV penetration increases, the net load hours are re-sorted from highest to lowest and more nighttime hours are among the top 500 net load hours Net Load (MW) Average PV Output in Top 100 Hours (MW) Ranked Net Load Hour
Capacity Credit by Renewable Penetration Capacity Credit • E3 calculated a capacity credit for the first 1000 MW of resource equal to the average production during top 100 load hours • Added 1000 MW of resource, re-sorted hours from highest to lowest net load, and re-calculated average production during top 100 net load hours • Capacity credit declines rapidly for solar resources as more high net load hours occur at night • Marginal Capacity Credit can be negative when high renewable generation hours are displaced from the top 100 net load hours Penetration (MW)
Capacity Credit Depends on the Resource Mix Capacity Credit • The previous slides assumed penetration of only one technology • The figures above assume a diversified portfolio with 8 MW Wind to every 3 MW PV and 3 MW CSP • Combined portfolio receives average capacity credit of 31% at 10,000 MW of penetration, higher than any of the three individual technologies Penetration (MW)
Transmission Assessment • CPUC and California ISO signed MOU on May 13, 2010 (http://www.caiso.com/2799/2799bf542ee60.pdf) • Agrees on certain elements of the ISO’s new proposed annual Transmission Planning Process • Commits to closer coordination between resource and transmission planning – ISO planning process considers scenarios provided by CPUC, CPUC gives substantial weight in the permitting process to projects consistent with ISO plan • Umbrella LTPP proceeding considers EE, demand response, distributed generation, utility-scale renewables, fossil retirements, when determining overall system need • CPUC must consider these same things when assessing the need for individual transmission projects, pursuant to statute 44
Transmission assessment (cont’d) “The CPUC and the ISO will review the results of the California Transmission Planning Group modeling phases and evaluate their implications for the transmission needs of the CPUC's Long Term Procurement Plan renewable resource scenarios. The ISO will subsequently seek, within the time and human resource constraints of Phase 2 of the transmission planning process, to provide the CPUC and other stakeholders with a formal assessment of the transmission planning needs within the ISO balancing authority area for the Long Term Procurement Plan renewable resource scenarios.” - May 13, 2020 MOU between California ISO and CPUC
Agenda • Introduction, scope, context • Terminology, high-level approach • Methodology, Inputs, Assumptions • Portfolio development • Discounted core • Environmental scoring • PV assessment • Transmission sizing • Timing assessment • Results • Next steps for analysis • Schedule, Summary
Schedule • Comments due July 9 • Reply comments due July 16 • Ruling next week will request feedback on specific questions – please attempt to address these, in addition to your general comments