SELECTIVE EXHAUST GAS RECIRCULATION IN COMBINED CYCLE GAS TURBINE POWER PLANTS WITH POST-COMBUSTION CARBON CAPTURE Laura Herraiz Palomino Ph. D. Thesis School of Engineering University of Edinburgh 2016 Lay Summary Gas-fired power plants with Carbon Capture and Storage (CCS) are expected to play a significant role to reduce carbon dioxide (CO ) emissions from the power generation sector. 2 They can provide dispatchable low-carbon electricity to maintain the flexibility required in an electricity system with high penetration of renewables. The low CO concentration and large volumes of flue gas generated in natural gas-fired 2 power plants make CO separation with post-combustion capture technologies more 2 challenging, compared to coal-fired power plants. This thesis investigates options for increasing CO concentration upstream of the capture 2 system by selectively transferring CO from a flue gas stream into an air stream used for 2 natural gas combustion. Other components in the flue gas are not recirculated back to the inlet of the gas turbine system and a large excess of air is maintained. Strategies to enhance capture should aim to introduce minimal modification in the gas turbine engine, as current gas turbine technology presents high efficiency and plays an important role in achieving high combined cycle net power output. Process simulations in a linked model of a natural gas combined cycle plant with a carbon capture and compression system conducted in this thesis show that high CO levels at the 2 exhaust of the gas turbine can be achieved maintaining levels of oxygen for efficient combustion, and that existing class of gas turbine engines can be operated with Selective Exhaust Gas Recirculation (S-EGR). For capture technologies using amine solvents, a reduction in equipment size and energy requirements are achieved. A novel system for selective CO transfer between a flue gas stream and an air stream is 2 proposed consisting on rotary physical adsorption. A conceptual design assessment shows that a step change in the performance of adsorbent materials is necessary before this novel system can be commercially deployed. Finally, a novel contribution is made to show that the availability of cooling might not necessarily constitute a limitation for the full scale deployment of CCS, particularly in regions with increasingly restricted access to cooling water and limited availability of fresh or sea water abstraction licences. Process simulations showed that cooling and process water demand can be drastically reduced in natural gas-fired power plants with carbon capture by using dry cooling systems consisting of rotary gas/gas heat exchangers with ambient air as the cooling fluid. i Abstract Selective Exhaust Gas Recirculation (S-EGR) consists of selectively transferring CO from 2 the exhaust gas stream of a gas-fired power plant into the air stream entering the gas turbine compressor. Unlike in “non-selective” Exhaust Gas Recirculation (EGR) technology, recirculation of, principally, nitrogen does not occur, and the gas turbine still operates with a large excess of air. Two configurations are proposed: one with the CO transfer system operating in parallel to 2 the post-combustion carbon capture (PCC) unit; the other with the CO transfer system 2 operating downstream of, and in series to, the PCC unit. S-EGR allows for higher CO 2 concentrations in the flue gas of approximately 13-14 vol%, compared to 6.6 vol% with EGR at 35% recirculation ratio. The oxygen levels in the combustor are approximately 19 vol%, well above the minimum limit of 16 vol% with 35% EGR reported in literature. At these operating conditions, process model simulations show that the current class of gas turbine engines can operate without a significant deviation in the compressor and the turbine performance from the design conditions. Compressor inlet temperature and CO 2 concentration in the working fluid are critical parameters in the assessment of the effect on the gas turbine net power output and efficiency. A higher turbine exhaust temperature allows the generation of additional steam which results in a marginal increase in the combined cycle net power output of 5% and 2% in the investigated configurations with S-EGR in parallel and S-EGR in series, respectively. With aqueous monoethanolamine scrubbing technology, S-EGR leads to operation and cost benefits. S-EGR in parallel operating at 70% recirculation, 97% selective CO transfer efficiency and 96% PCC efficiency results in a 2 reduction of 46% in packing volume and 5% in specific reboiler duty, compared to air-based combustion CCGT with PCC, and of 10% in packing volume and 2% in specific reboiler duty, compared to 35% EGR. S-EGR in series operating at 95% selective CO transfer 2 efficiency and 32% PCC efficiency results in a reduction of 64% in packing volume and 7% in specific reboiler duty, compared to air-based, and of 40% in packing volume and 4% in specific reboiler duty, compared to 35% EGR. An analysis of key performance indicators for selective CO transfer proposes physical 2 adsorption in rotary wheel systems as an alternative to selective CO membrane systems. A 2 conceptual design assessment with two commercially available adsorbent materials, activated carbon and Zeolite X13, shows that it is possible to regenerate the adsorbent with air at near ambient temperature and pressure. Yet, a significant step change in adsorbent materials is necessary to design rotary adsorption systems with dimensions comparable to the largest rotary gas/gas heat exchanger used in coal-fired power plants, i.e. approximately 24 m diameter and 2 m height. An optimisation study provides guidelines on the equilibrium parameters for the development of materials. Finally, a technical feasibility study of configuration options with rotary gas/gas heat exchangers shows that cooling water demand around the post-combustion CO capture 2 system can be drastically reduced using dry cooling systems where gas/gas heat exchangers use ambient air as the cooling fluid. Hybrid cooling configurations reduce cooling and process water demand in the direct contact cooler of a wet cooling system by 67% and 35% respectively, and dry cooling configurations eliminate the use of process and cooling water and achieve adequate gas temperature entering the absorber. ii Acknowledgment This thesis is the result of work done after generous opportunity given by Dr. Mathieu Lucquiaud, Prof. Jon Gibbins and Dr. Hannah Chalmers. Thanks to my supervisor Dr. Mathieu Lucquiaud for his essential support to get this Ph.D. completed and for keeping me interested in the “broader picture” of CCS and in the essential role of collaboration between academy and industry for CCS to happen. Special tanks to Dr. Eva Sánchez Fernández for her guidance and advice, stimulating discussions and fruitful exchange of ideas. Thanks to Dr. María Sanchez del Río Sáez and Ms. Olivia Errey. This Ph.D. would not have been possible without their help. I also thank my colleagues in the Power Plant Engineering & CCS group at the University of Edinburgh. In particular, I would like to thank Dr. Bill Bulchle, Dr. Ignacio Trabadela, Dr. Abigail Gonzalez, Dr. Alasdair Bruce, Dr. Juan Riaza, Mr. Paul Tait, Ms. Erika Palfi, Mr. Thomas Spitz and Mr. Gordon Paterson for their support and unforgettable time spent together. Special thanks to Dr. Atul Agarwal and Dr. Siraj Sabihuddin for their support, encouragement and friendship. This project has also given me the opportunity to work with excellent people outside of academia. I would like to thank Mr. Dougal Hogg, Mr. Jim Cooper and Mr. Richard Smith from Howden UK, Glasgow, for their extremely valuable input and technical advice on rotary heat exchangers. I would also like to thanks Ms. Meron Reid for giving me the opportunity to attend the Howden Academy. Financial support for this research was provided by the Doctoral Training Account of School of Engineering of the School of Engineering at the University of Edinburgh, funded by the UK Engineering and Physical Science Research Council (EPSRC) and Howden Group (Glasgow, Scotland). Support from the GAS-FACTS project funded by the EPSRC (EP/J020788/1) is gratefully acknowledged. Thanks to the UK Carbon Capture and Storage Research Centre (UKCCSRC) I sincerely appreciate the time and efforts of my examination committee members, Dr. Hannah Chalmers and Dr. Richard Marsh. Thank you for sharing your experience and advice with me as well as being kind in your assessment of this work. Finally, I am grateful to my family because they have always encouraged me to pursue this project and follow my dreams, helping me along the way. iii 1. Declaration of originality The work included in this Ph.D. thesis, except when referenced, is the results of the effort of years that has been done by the author alone under the guidance of her supervisor Dr. Mathieu Lucquiaud. The author acknowledges essential contributions by others in the acknowledgment section of this thesis and in further sections of the work where required. This Ph.D. thesis has not been submitted for any other degree or professional qualifications in the UK or elsewhere. The author recommends referencing this thesis as follows: Herraiz, L. (2016), Selective Exhaust Gas Recirculation in Combined Cycle Gas Turbine Power Plants with Post-combustion Carbon Capture, Ph.D. Thesis, School of Engineering, University of Edinburgh, United Kingdom of Great Britain and Northern Ireland (UK). Laura Herraiz Palomino iv