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A pilot-scale study of dynamic response scenarios for the flexible operation of post-combustion CO2 capture

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Original languageEnglish
JournalInternational Journal of Greenhouse Gas Control
Early online date7 Jan 2016
DOIs
Publication statusPublished - 2016

Abstract

The ability to operate flexibly is critical for the future implementation of carbon capture and storage (CCS) in thermal power plants. A dynamic test campaign examines the response of a CO2 absorption/desorption pilot-scale plant to realistic changes in flue gas flow rates and steam supply, representative of the operation of an Natural gas combined cycle (NGCC) plant fitted with post-combustion capture. Five scenarios, demonstrating the operational flexibility that is likely to be encountered in an energy market with significant penetration from intermittent renewables, are presented, with 30% monoethanolamine (MEA) as the absorbing solvent. It complements a wider effort on dynamic modelling of these systems where a lack of dynamic plant has been reported.
The campaign focuses on analysing critical plant parameters of the response of the pilot plant to a gas turbine shutdown, a gas turbine startup and three enhanced operational flexibility scenarios, including two for power output maximisation and one for frequency response with a rapid increase of steam supply to the reboiler. The campaign also demonstrates the use of continuous in-situ solvent lean loading measurement with the use of a novel online continuous liquid sensor.
It confirms that there are no significant barriers to flexible operation of amine post-combustion capture are found, although there remains scope for the improvement of plant response. Solvent inventory and circulation times are found to have a significant effect on capture rate during certain dynamic operations and after the plant returns to steady-state baseload operation. A large solvent inventory increases circulation times, over 20min in this case between the reboiler and the absorber inlet, which results in a delayed drop in capture rate when the plant returns to steady-state baseload operation.
Use of interim solvent storage and continuous online measurement of solvent CO2 loading, combined with comprehensive knowledge of liquid circulation times and potential mixing effects, are suggested as methods of improving plant response to dynamic operation, thereby increasing CCS plant flexibility.

    Research areas

  • CO2 capture; Post-combustion; Natural GasCcombined Cycle; Flexibility; Dynamic operation; Pilot plant

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