1 / 24

Transform PV to Load Capacity Status by Coupling PV Plants to CAES Plants

Transform PV to Load Capacity Status by Coupling PV Plants to CAES Plants. James Mason Renewable Energy Research Institute ASES Forum on Solar and the Grid Buffalo, NY – 13 May 2009. Problem: PV Electricity Supply Is Intermittent. * PV Electricity Supply Is Intermittent

ebowers
Télécharger la présentation

Transform PV to Load Capacity Status by Coupling PV Plants to CAES Plants

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Transform PV to Load Capacity Status by Coupling PV Plants to CAES Plants James Mason Renewable Energy Research Institute ASES Forum on Solar and the Grid Buffalo, NY – 13 May 2009

  2. Problem: PV Electricity Supply Is Intermittent * PV Electricity Supply Is Intermittent - Does Do Not Meet Load Capacity Requirements * Load Capacity = Dispatchable Power ¤ Dispatchable = Available on Demand - PV Cannot Replace Load Capacity Plants * PV Is Only Supplemental Electricity * A Large Increase in PV Capacity Without Energy Storage Increases System Variability, the Need for Additional Reserve Capacity, and System Costs, which Translate Into Higher Electric Bills

  3. Insolation Variability: Diurnal and Annual Average Southwest US Insolation

  4. The Solution to PV’s Intermittency: Compressed Air Energy Storage (CAES) Alabama Electric Cooperative’s McIntosh, Alabama 110 MW CAES Power Plant in Operation Since 1991

  5. CAES Power Plants CAES Power Plants HVDC Power Lines DC-AC Converter Stations PV Power Plants CAES Power Plants

  6. Underground Natural Gas Storage Sites

  7. CAES Power Plant

  8. Supply of PV and CAES Electricity to Local Grid in a Coupled PV-CAES Plant Design for Load Capacity

  9. Next CAES Plant Will Be Similar In Design to the Schematic • Adiabatic CAES (No NG) Will Not Be Available Until Post-2020 • * PV Electricity for Air Compression • Conventional CAES = 0.8 kWh In / kWh Out • Adiabatic CAES = 1.43 kWh In / kWh Out • * CAES Plant Natural Gas Consumption • Conventional CAES = 4,800 Btu (HHV) / kWh Out • * Fuel Efficiency of a Coupled PV-CAES “Peak” Power Plant • CAES Only Fuel Efficiency = 71% (3412/4800) • Aggregate Electricity Supplied to Grid = 64% PV and 36% CAES • Aggregate PV-CAES Fuel Efficiency = 191% (3412/1786) • * Conclusion: Coupled PV-CAES Provides Load Capacity, and • Significantly Reduces Fuel Consumption and CO2 Emissions

  10. NG Cost for PV-CAES to Achieve Breakeven Peak Electricity Price • 1. PV-CAES = Natural Gas Combined-Cycle with CCS • A. $2/W Installed PV Cost • Natural Gas Electric Utility Price = $15.17/MMBtu • * 117% higher than current natural gas price. • B. $1.50/W Installed PV Cost • Natural Gas Electric Utility Price = $11.63/MMBtu • * 66% higher than current natural gas price. • 2. PV-Adiabatic CAES = Natural Gas Combined-Cycle with CCS • A. $2/W Installed PV Cost • Natural Gas Electric Utility Price = $15.83/MMBtu • * 126% higher than current natural gas price. • B. $1.50/W Installed PV Cost • -Natural Gas Electric Utility Price = $12.34/MMBtu • * 76% higher than current natural gas price.

  11. Cost of CAES Power Plant The levelized cost estimates are calculated by the net present value cash flow method. Financial assumptions: capital structure 80% debt – 20% equity; cost of debt 6.5%; cost of equity 10%; ; 30-year capital recovery period; 38.2% tax rate, MACRS depreciation; 2% annual inflation rate.

  12. Underground Natural Gas Storage Sites

  13. Sizing PV and Air Storage Capacity • Size of Air Storage Reservoir Must Account for Solar Variability to Insure Sufficient Air Supply • The Optimized Peak PV-CAES Plant Model Indicates That Air Storage Capacity Must Be Sufficient to Enable 110 hours of CAES Operation Independent of Air Storage Recharging (40-60 million cubic feet) • Our Optimization Is Based on Insuring Peak Load Capacity Electricity Supply 99.5% of the Planned Operation of the CAES Plant • The Optimized Ratio of PV Capacity to CAES Peak Load Capacity Is 1.45:1

  14. Sizing of Air Storage Reservoir and PV Capacity Assigned to Air Compression Has to Account for Insolation Variability

  15. Number of Days per Year Air Storage Reservoir Is Depleted An Important Factor in Selecting the Size of Storage Reservoir

  16. Air Storage Balances of the CAES Underground Reservoir To Insure CAES Plant Availability 99.5% of Planned Operation

  17. Effect of Distributed PV Plants Coupled to Distributed CAES Plants on Levelized Electricity Price Compared to SW PV

  18. Immediate Needs • Define CAES in Renewable Energy Incentives - Legislatures and Regulatory Agencies • Federal Plan for a HVDC Grid from Southwest to Electricity Markets in Southeast and Along Eastern Seaboard • Federal Adiabatic-CAES R&D Program

  19. Acknowledgements • Ken Zweibel – George Washington University • Vasilis Fthenakis – Columbia University and Brookhaven Nat’l Lab • Tom Hansen – Tucson Electric Power • Thomas Nikolakakis – Engineering Grad

More Related