High Efficiency Thermal Integration of Supercritical CO2 Brayton Power Cycles for Oxy-Fired Heaters Email Page
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Performer: Electric Power Research Institute, Inc.
Summary of Test Cases to Be Studied
Summary of Test Cases to Be Studied
Website: Electric Power Research Institute
Award Number: FE0025959
Project Duration: 10/01/2015 – 03/31/2018
Total Award Value: $2,297,578
DOE Share: $1,838,062
Performer Share: $459,516
Technology Area: Advanced Combustion Systems
Key Technology: Enabling Technologies/Innovative Concepts
Location: Palo Alto, California

Project Description

The Electric Power Research Institute (EPRI) and a team of five subcontractors (Alstom Power Inc., Babcock & Wilcox Power Generation Group, Inc., Doosan America ATS, Echogen Power Systems, LLC, and Howden Group Ltd.) will develop process designs for test cases that optimally integrate candidate closed Brayton power cycles using supercritical carbon dioxide (SCO2) as the working fluid with oxy/coal-fired SCO2 heaters for comparison with relevant DOE/NETL baseline cases employing steam-Rankine power cycles, and identify technology gaps in the SCO2 Brayton power cycle plants. The team will also develop cost estimates for the SCO2 Brayton cycle power plants coupled with oxy/coal-fired systems for comparison with relevant baseline-case capital costs and associated cost of electricity and identify components whose cost might be reduced by focused R&D.

Project Benefits

The EPRI team will develop the first reported design of oxy/coal-fired SCO2 Brayton cycle power plants with the potential to increase efficiency by 3 to 5 percentage points. Furthermore, the work will result in the development of oxy/coal-fired SCO2 heater designs that will be extensions of state-of-the-art steam generator designs. In particular, two different combustion concepts (first-generation atmospheric-pressure oxy-combustion and “transformational” chemical looping combustion) will be integrated with SCO2 power cycles. The work will be of sufficient scope and quality to allow meaningful comparisons of performance and costs with benchmark DOE/NETL baseline cases of coal-fired technologies (with and without CO2 capture) employing the steam-Rankine power cycle. The work will also be used to identify technology and cost gaps that might be reduced by focused R&D and provide the background to assess the value of closing the cost gaps.

Contact Information

Federal Project Manager Robin Ames: robin.ames@netl.doe.gov
Technology Manager John Rockey: john.rockey@netl.doe.gov
Principal Investigator Andrew Maxson: amaxson@epri.com


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