H 2 Coal Natural Gas Chemical conversion C x H y H 2 + CO 2 Integration? Thermal conversion C x H y Power + CO 2 Electricity Dynamis SP2: CO 2 capture Power plant & capture technologies Castor-Encap-Cachet-Dynamis workshop Lyon, 22 nd -23 rd January 2008 Dr. Petter E. Røkke, SP2 leader
Layout Objective Partners work structure Evaluation of concepts Recommendation
Objectives Dynamis overall objective; Investigate viable routes for large-scale cost-effective combined H 2 and electricity production with integrated CO 2 capture and storage, probably combined with EOR SP2 objective; Determine the overall configuration of plants that employ 1. gasification technologies for the decarbonisation of coal and lignite (via a synthesis gas), and 2. reforming technologies for natural gas, to be used for a combined production of hydrogen and electric power generation.
SP2: Work breakdown structure WP2.1 WP2.2 Natural gas based hydrogen and electricity production systems Integration aspects No flexibility Lignite and coal based hydrogen and electricity production Systems Gasification process Flexibility SP2 New technologies for clean fossil hydrogen and power production Exhaust gas recirculation SCWG + antisublimation WP2.3 WP2.4 Technology bench-marking, qualification and recommendations Short-list of recommended concepts
SP2: Layout of working plan M1 WP2.4: Guidelines for concept evaluation D2.4.1 WP2.1 Natural gas 6 cases WP2.2 Coal & Lignite 6 + 6 cases Time? M18 WP2.4: MCA screening; 3 concepts/fuel D2.4.2 WP2.1 Natural gas 3 cases WP2.2 Coal & Lignite 3 + 3 cases D2.1.5 D2.2.6 WP2.4: Recommendation D2.4.3
Guidelines for concept evaluation Specifications on: Gas turbines to be used in the simulations, Ambient conditions, Fuels (Bit. coal, lignite and natural gas), Emission limits, Oxygen purity, Hydrogen composition, CO 2 composition, Economic assumptions
Important issues in SP2 Capture technology Dynamis a pre-combustion project? For coal/lignite yes! For natural gas no! NGCC with post-combustion capture of CO 2 CAN and WILL be evaluated Gas turbine Commercial technology in 2010 Agreed in the project: Use E-class GT with H 2 rich fuel used for integrated cases For NGCC with post-combustion CO 2 capture and parallel production of H 2 Use F-class GT fuelled with NG Difference in efficiency due to GT
Multicriteria Assessment (MCA) Evaluation of; 6 coal-based concepts 3 gasifiers 3 AGR processes 2 GTs 6 natural gas-based concepts Degree of integration Parallel option GT; E or F-class Recommendation 3 concepts for coal, lignite and natural gas Criteria; efficiency, reliability, availability, planned maintenance, cost, operability, output ratio flexibility, safety, environment, carbon capture efficiency, CO 2 product quality, H 2 product quality, bankability, technical risk
Description of concepts Natural gas 1. Parallell SMR, Post- and Pre-C capture, NGCC with F- class GT 2. Integrated O 2 -blown ATR, Pre-C capture, IRCC with E-class GT 3. Integrated Air-blown ATR, Pre-C capture, IRCC with E-class GT
Capital Fuel Fixed O&M Variable O&M SP2 Main results 80.0 70.0 0.97 6.51 0.98 6.06 NG costs Case 1, Parallel production of H 2 and electricity, is the least expensive option Cost of Electricity ( /MWh) 60.0 50.0 40.0 30.0 20.0 10.0 0.0 0.88 5.47 37.53 17.22 Case 1: SMR + NGCC 61.1115 44.88 21.03 Case 2: O2 ATR + H2 CC 73.3884 47.21 19.51 Case 3: Air ATR + H2 CC 73.7679 Capital Fuel Fixed O&M Variable O&M Case 1: 1 F-class GT Case 2 and 3: 2 E-class GTs Cost of Hydrogen ( /MWh) 50.0 45.0 40.0 35.0 30.0 25.0 20.0 15.0 10.0 5.0 1.06 6.55 19.72 12.02 0.42 2.81 31.90 9.55 0.42 2.58 34.28 8.69 0.0 Case 1: SMR + NGCC 39.3368 Case 2: O2 ATR + H2 CC 44.6791 Case 3: Air ATR + H2 CC 45.9665
Natural gas - recommendation Higher efficiency (F-class GT, SMR, MEA for CO 2 capture) A thought H 2 -fired F-class GT would not close the gap in efficiency Less integration lower complexity
Description of concepts Coal 1. Shell gasifier 2. Siemens gasifier 3. GE gasifier Sulphur Air AIR SEPARATION UNIT N 2 CLAUS PLANT & TAIL GAS TREATMENT O 2 Coal / Lignite (pre-dried) GASIFICATION SYNGAS QUENCH & CONDITIONING WATER GAS SHIFT CONVERSION H 2 S & CO 2 SEPARATION PRESSURE SWING ADSORPTION Steam / Water Slag Steam (No steam for water quench configurations) CO 2 DRYING & CO COMPRESSION 2 All: Entrained flow gasifiers Selexol AGR process E-class GT Power COMBINED CYCLE GAS TURBINE Hydrogen
Coal concepts comparison Cost of Electricity ( /MWh) 80.0 70.0 60.0 50.0 40.0 30.0 20.0 1.91 12.06 21.39 36.03 Capital Fuel Fixed O&M Variable O&M 2.44 2.50 11.46 11.49 21.81 22.89 34.10 34.17 10.0 0.0 Case 1: Shell Gasifier 71.3913 Case 2: Siemens Gasifier 69.8017 Case 3: GE Texaco Gasifier 71.0408 Gasification Technology Unit Shell Siemens General Electric Power plant config. GT/HRSG/ST 2/2/1 2/2/1 2/2/1 (GT/HRSG/ST) Coal flow (a.r.) t/h 199.7 202.3 220.24 Gross power output MW e 594.91 592.27 630.38 Ancillary power demand MW e 132.69 134.19 155.53 Cooling water t/h 48826 49840 60873 consumption Net power output MW e 462.22 458.08 474.85 Gross efficiency % 42.6 41.86 40.93 Net efficiency % 33.1 32.38 30.83 Carbon capture rate % 90.26 90.02 90.28 CO 2 specific emissions kg/mwh 102.93 107.83 110.27 Cost of Hydrogen ( /MWh) 100.0 90.0 80.0 70.0 60.0 50.0 40.0 30.0 20.0 2.18 13.73 33.93 42.49 Capital Fuel Fixed O&M Variable O&M 2.91 2.75 13.41 12.93 34.37 37.42 39.45 40.46 10.0 0.0 Case 1: Shell Gasifier 92.3316 Case 2: Siemens Gasifier 89.4889 Case 3: GE Texaco Gasifier 94.1978
Coal - recommendation Shell gasifier concept Entrained flow High efficiency, but drawback in costs, complexity and reliability GE gasifier concept Good reliability, low CAPEX and technical risk Drawback in efficiency
Description of concepts Lignite 1. Siemens entrained flow gasifier 2. HTW fluidized bed gasifier 3. BGL moving bed gasifier Sulphur Power Air AIR SEPARATION UNIT N 2 CLAUS PLANT & TAIL GAS TREATMENT COMBINED CYCLE GAS TURBINE O 2 Coal / Lignite (pre-dried) GASIFICATION SYNGAS QUENCH & CONDITIONING WATER GAS SHIFT CONVERSION H 2 S & CO 2 SEPARATION PRESSURE SWING ADSORPTION Hydrogen Steam / Water Slag Steam (No steam for water quench configurations) CO 2 DRYING & CO COMPRESSION 2 All: Selexol AGR process E-class GT
Lignite concepts 70.0 1.91 13.07 60.0 50.0 9.94 40.0 30.0 comparison 41.76 Cost of Electricity ( /MWh) 20.0 Capital Fuel Fixed O&M Variable O&M 1.38 14.19 1.34 12.31 9.92 9.22 42.33 37.90 10.0 0.0 Case 4: Siemens Gasifier 66.6757 Case 5: HTW Gasifier 67.8248 Case 6: BGL Gasifier 60.7680 Gasification Technology Unit Siemens High Temperature Winkler * British Gas Lurgi Power plant config. GT/HRSG/ST 2/2/1 2/2/1 2/2/1 (GT/HRSG/ST) Lignite flow (a.r.) t/h 510.2 484 446 Gross power output MW e 596.62 560.94 543.94 Ancillary power demand MW e 161.5 144.15 131.63 Cooling water t/h 52516 42842 38615 consumption Net power output MW e 435.12 416.79 412.31 Gross efficiency % 48.11 47.68 50.17 Net efficiency % 35.08 35.42 38.03 Carbon capture rate % 90.41 83.00 80.3 CO 2 specific emissions Kg/MWh 111.47 186.88 211.6 Cost of Hydrogen ( /MWh) 90.0 80.0 70.0 60.0 50.0 40.0 30.0 20.0 2.24 15.38 16.26 51.46 Capital Fuel Fixed O&M Variable O&M 1.56 16.09 1.44 13.21 15.43 14.22 50.47 42.78 10.0 0.0 Case 4: Siemens Gasifier 85.3519 Case 5: HTW Gasifier 83.5463 Case 6: BGL Gasifier 71.6399
Lignite - recommendation Siemens gasifier concept Entrained flow CO 2 capture rate Better techno-economic performance
Life Cycle Analysis (LCA) GHG assessments of 12 pathways of electricity + H 2 production Base Scenario : Reference for fuel supply / 300km pipeline transportation / Onshore storage (aquifer, depth : 2500m) Fuel Supply Power plant operation Power plant construction CO2 pipeline transportation + injection CO2 storage (wells construction) including CO2 capture, drying and compression L 3 - British Gas Lurgi L 2 - High Temperature Winkler L 1 - Siemens 82 % 73 % 70 % GHG emissions reduction compared to the correspo reference pathway without CCS Lignite Reference plant Bit. Coal 3 - General Electric 74 % Bit. Coal 2 - Siemens 75 % 70 % < GHG emissions reduction < 82 % Bit. Coal 1 - Shell 76 % Bit. Coal Reference plant NG 3 - Air ATR - Integrated NG 2 - O2 ATR - Integrated NG 1 - SMR - Parallel 73 % 74 % 72 % NG Reference plant 0 25 50 75 100 125 150 175 200 225 250 275 300 325 350 375 400 425 450 475 500 525 550 575 600 625 650 675 700 725 750 775 800 825 850 875 900 gco 2eq / kwh (electricity + H 2 ) produced
Life Cycle Analysis (LCA) Non renewable energy consumption assessments of 12 pathways of electricity + H 2 production Base Scenario : Reference for fuel supply / 300km pipeline transportation / Onshore storage (aquifer, depth : 2500m) Fuel Supply Power plant operation Power plant construction CO2 pipeline transportation + injection CO2 storage (wells construction) L 3 - British Gas Lurgi L 2 - High Temperature Winkler L 1 - Siemens including CO2 capture, drying and compression 34 % 51 % 52 % Lignite Reference plant Bit. Coal 3 - General Electric Non renewable expended energy increase com to the corresponding reference pathway witho 59 % Bit. Coal 2 - Siemens Bit. Coal 1 - Shell 43 % Bit. Coal Reference plant NG 3 - Air ATR - Integrated 34 % < increase of NR expended energy < 105 % 105 % NG 2 - O2 ATR - Integrated NG 1 - SMR - Parallel NG Reference plant 47 % 91 % 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 7 7.5 8 8.5 MJ expended / kwh (electricity + H 2 ) produced
SP2 WP2.3 New technologies Exhaust gas recirculation with post-combustion capture of CO 2 Process simulations promising results Supercritical Water Gasification + antisublimation process for H 2 /CO 2 separation Experiments @ TNO: SWG viable option but more on a long-term perspective Experiments @ Armines (subcontract of APE-FR): Antisublimation Feasible option for CO 2 capture from a precombustion process with SWG
Summary of results and recommendations in SP2 A number of concepts have been studied for natural gas, coal and lignite within SP2 and a recommendation has been given with respect to further studies in SP5. Basis for recommendation; Technical evaluation WP2.1 and WP2.2 Economical evaluation LCA MCA
That s all from Dynamis SP2 Contact information; E-mail: petter.e.rokke@sintef.no Phone: +47 73593069/+47 90120221