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On/Off Operation of Carbon Capture Systems in the Dynamic Electric Grid Rochelle Group Research Review January 11, 2

On/Off Operation of Carbon Capture Systems in the Dynamic Electric Grid Rochelle Group Research Review January 11, 2008. Stuart Cohen Graduate Research Assistant Department of Mechanical Engineering: Thermal Fluid Systems Division The University of Texas at Austin. Outline.

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On/Off Operation of Carbon Capture Systems in the Dynamic Electric Grid Rochelle Group Research Review January 11, 2

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  1. On/Off Operation of Carbon Capture Systemsin the Dynamic Electric Grid Rochelle Group Research ReviewJanuary 11, 2008 Stuart Cohen Graduate Research Assistant Department of Mechanical Engineering: Thermal Fluid Systems Division The University of Texas at Austin

  2. Outline • Background and limitations of current techno-economic analyses of CCS • My proposal to investigate CCS within the electric grid • Illustration of grid dynamics and implications of on/off operation of CO2 capture • Summary of Research Objectives

  3. Typical Techno-Economic Analyses take 2 forms: Bottom Up Approach: Plant Level Analysis • Static Plant Performance Specifications • CO2 Removal Efficiency, (%) • Plant Output (MW) • CO2 Capture Energy • (MWh/tCO2) • Economic Assumptions • Equipment Costs ($) • Fuel Costs ($) • Discounting Rate (%) • Economic Indicators • Cost of Electricity ($/MWh) • CO2 Removal Cost ($/tCO2) • Total Plant Cost ($/kW) • Local Environmental Effect • Plant CO2 Emissions (ton)

  4. Typical Techno-Economic Analyses take 2 forms: Top Down Approach: Macro-scale Energy Analysis • National Electricity Market Trends • Projected Population Growth • Consumer Energy Use • Behavior • Input Parameters of Interest • Cost of each Energy • Technology ($/MWh) • CO2 Market Value ($), Date • of Application, Growth Rate • Effects on Energy Use • US Energy Consumption • US Energy Mix • Market Penetration of CCS • Global Environmental Effect • US CO2 Emissions (ton)

  5. These Analyses have Several Strengths… • Macro-scale Energy Analyses • Demonstrate qualitative long term effects • Demonstrate macroeconomic tradeoffs • Consider interactions between energy sources • Consider regional variation in energy use • Single Plant Analyses • Detailed technology assessment • Demonstrate plant level tradeoffs

  6. But Also Several Limitations • Macro-scale Energy Analyses • Ignore dynamics of plant dispatch • Limited detail of plant performance • Single Plant Analyses • Use static plant performance parameters • Site and technology specific • Ignore varying electricity demand • Do not consider interactions between energy supply technologies

  7. Proposal • Take an intermediate approach between single plant and macro-scale energy analyses • Study the feasibility and effects of turning CO2 capture systems on and off in response to electric grid dynamics • Optimize the performance, economics, and environmental effects of turning CO2 capture on and off under a given electricity supply/demand scenario

  8. Grid Level Analysis • Market Based Economic Indicators • Cost of Electricity ($/MWh) • CO2 Removal Cost ($/tCO2 ) • Total Plant Cost, ($/kW) • Environmental Effect • CO2 Emissions – Plant and • Grid (ton) • Variable Performance Specifications • CO2 Removal Efficiency (%) • Plant Output (MW) • Economic Assumptions • Equipment Costs ($) • Fuel Costs ($) • Grid Parameters • Electricity Demand (MW vs. Time) • Dispatch Options and Costs ($/MWh) • Market Value of CO2 ($)

  9. My Hypotheses • Turning CO2 capture on and off in response to grid supply/demand can lessen the cost of implementing CCS • Optimal practices can be determined from grid supply/demand scenarios • The flexibility of Post-Combustion capture using chemical absorption favors such practice

  10. Electricity Demand throughout the Day Natural Gas Total Coal Capacity Nuclear Coal Source: ERCOT Reliability/Resource Update 2006

  11. Using On/Off CO2 Capture During Peak Load Capture Turned Off Natural Gas Total Coal Capacity Nuclear 30% Coal Capacity Coal

  12. Capture Turned Off August 17 January 2 Capture Turned Off Source: ERCOT

  13. August 17 January 2 Capture Off Capture On Source: ERCOT

  14. Hourly Variation in Wind and Load: 15000MW Wind in TX Scenario Total Load Load minus Wind Capture Turned Off 30% Coal Capacity Wind Generation Source: 2007 GE Wind Analysis for ERCOT

  15. 30% Coal Capacity Peak Load Capture Turned Off Source: ERCOT

  16. Source: ERCOT and ICE

  17. My Work Will • Analyze the effects of on/off CO2 capture operation under several electricity supply/demand scenarios • Incorporate knowledge of amine absorption systems into grid level analysis of CO2 capture • Investigate technical limitations of on/off operation at a system level

  18. Overall Research Goals • Determine performance, economic, and environmental tradeoffs of on/off CO2 capture • Determine optimal operation of CO2 capture for a given electricity supply/demand scenario • Provide industry with a tool to help guide the implementation and use of CO2 capture systems • Determine technical feasibility of on/off CO2 capture at the system level

  19. Bottom Line • CO2 Capture is expensive, BUT • Dynamic electricity supply/demand provides an opportunity for using on/off operation to lower CO2 capture costs

  20. Thank you. Questions? Comments?

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