Exergy and economic analysis of a CaO-looping gasifier for IGFC-CCS and IGCC-CCS

Applied Energy

Volumn 128, Issue , 2014, Pages 230-245

  Siefert, Nicholas S ^a,b   Chang, Brian Y ^a,b   Litster, Shawn ^b  

^a NATIONAL ENERGY TECHNOLOGY LABORATORY   (United States)

^b CARNEGIE MELLON UNIVERSITY   (United States)

Author keywords

Coal gasification; Exergy; Levelized cost of electricity; Solid oxide fuel cell; Thermo economic analysis

Indexed keywords

ATMOSPHERIC PRESSURE; CARBON CAPTURE; CARBON DIOXIDE; CATALYSTS; COAL GASIFICATION; COSTS; DEGRADATION; EARNINGS; EXERGY; POWER PLANTS; SENSITIVITY ANALYSIS; SOLID OXIDE FUEL CELLS (SOFC);

COAL BASED POWER PLANTS; EXERGETIC EFFICIENCY; GASIFICATION KINETICS; GASIFICATION PROCESS; INTERNAL RATE OF RETURN; LEVELIZED COST OF ELECTRICITIES; STOICHIOMETRIC RATIO; THERMO-ECONOMIC;

ECONOMIC ANALYSIS;

CARBON SEQUESTRATION; COAL-FIRED POWER PLANT; COST-BENEFIT ANALYSIS; ECONOMIC ANALYSIS; ENERGY EFFICIENCY; EXERGY; INVESTMENT; SENSITIVITY ANALYSIS;

EID: 84900828701     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2014.04.065     Document Type: Article

References (67)

1. Susan S. Climate change 2007-the physical science basis: working group I contribution to the fourth assessment report of the IPCC 2007, Cambridge University Press.
2. EPA-HQ-OAR-2011-0660; FRL-RIN 2060-AQ91. Standards of performance for greenhouse gas emissions for new stationary sources.
3. 2 sequestration in geologic formations--United States department of energy R & D. Energy Convers Manage 2003, 44:2699-2712.
4. 2 capture. Greenh Gas Control Technol 1999, 101-106.
5. 2 emissions. Energ Policy 2004, 32:367-382.
6. 2 capture and storage. Energ Policy 2007, 35:4444-4454.
7. Rubin E.S., Mantripragada H., Marks A., Versteeg P., Kitchin J. The outlook for improved carbon capture technology. Prog Energy Combust 2012, 38:630-671.
8. 2. Energy 2007, 32:1163-1176.
9. Kunze C., Spliethoff H. Modelling of an IGCC plant with carbon capture for 2020. Fuel Process Technol 2010, 91:934-941.
10. Hammond G.P., Akwe S.S.O., Williams S. Techno-economic appraisal of fossil-fuelled power generation systems with carbon dioxide capture and storage. Energy 2011, 36:975-984.
11. Connell D.P., Lewandowski D.A., Ramkumar S., Phalak N., Statnick R.M., Fan L.-S. Process simulation and economic analysis of the calcium looping process (CLP) for hydrogen and electricity production from coal and natural gas. Fuel 2013, 105:383-396.
12. 2 co-production. Appl Energy 2012, 91:43-50.
13. Siefert N.S., Litster S. Exergy and economic analyses of advanced IGCC-CCS and IGFC-CCS power plants. Appl Energy 2013, 107:315-328.
14. Grol E, Wimer J. Systems analysis of an integrated gasification fuel cell combined cycle: DOE/NETL-40/080609; 2009.
15. Gerdes K, Grol E, Keairns D, Newby R. Integrated gasification fuel cell performance and cost assessment: DOE/NETL-2009/1361; 2009.
16. Gerdes K. Current and future technologies for gasification-based power generation. A pathway study focused on carbon capture advanced power systems R&D using bituminous coal, vol. 2; 2010 [DOE/NETL-2009/1389].
17. Shelton W. Analysis of integrated gasification fuel cell plant configurations; 2011 [DOE/NETL - 2011-1482].
18. 2 capture and carbonaceous fuel conversion - prospect and opportunity. Energy Environ Sci 2012, 5:7254-7280.
19. Siefert N.S., Shekhawat D., Litster S., Berry D.A. Steam-coal gasification using CaO and KOH for in situ carbon and sulfur capture. Energy Fuel 2013, 27:4278-4289.
20. 2 capture performance and cost analysis. Energy Procedia 2013, 37:618.
21. Siefert N., Shekhawat D., Litster S., Berry D. Molten catalytic coal gasification with in situ carbon and sulphur capture. Energy Environ Sci 2012, 5:8660-8672.
22. Hirsch R.L., Gallagher J.E., Lessard R.R., Wesselhoft R.D. Catalytic coal-gasification - an emerging technology. Science 1982, 215:121-127.
23. Yeboah Y.D., Xu Y., Sheth A., Godavarty A., Agrawal P.K. Catalytic gasification of coal using eutectic salts: identification of eutectics. Carbon 2003, 41:203-214.
24. Lanzini A., Leone P., Guerra C., Smeacetto F., Brandon N.P., Santarelli M. Durability of anode supported solid oxides fuel cells (SOFC) under direct dry-reforming of methane. Chem Eng J 2013, 220:254-263.
25. Nikooyeh K., Clemmer R., Alzate-Restrepo V., Hill J.M. Effect of hydrogen on carbon formation on Ni/YSZ composites exposed to methane. Appl Catal a - Gen 2008, 347:106-111.
26. Finnerty C.M., Coe N.J., Cunningham R.H., Ormerod R.M. Carbon formation on and deactivation of nickel-based/zirconia anodes in solid oxide fuel cells running on methane. Catal Today 1998, 46:137-145.
27. Lanzini A., Leone P., Pieroni M., Santarelli M., Beretta D., Ginocchio S. Experimental investigations and modeling of direct internal reforming of biogases in tubular solid oxide fuel cells. Fuel Cells 2011, 11:697-710.
28. Shiratori Y., Ijichi T., Oshima T., Sasaki K. Internal reforming SOFC running on biogas. Int J Hydrogen Energy 2010, 35:7905-7912.
29. 2 acceptor gasification process - studies of acceptor properties. Adv Chem Ser 1967, 141-165.
30. Simbeck D.R., Dickenson R.L., Oliver E.D., Associates S.F. Coal gasification systems: a guide to status, applications, and economics 1983, Electric Power Research Institute.
31. Green D., Perry R. Perry's chemical engineers' handbook 2007, McGraw-Hill Companies Incorporated. 8th ed.
32. Martinez A., Gerdes K., Gemmen R., Poston J. Thermodynamic analysis of interactions between Ni-based solid oxide fuel cells (SOFC) anodes and trace species in a survey of coal syngas. J Power Sources 2010, 195:5206-5212.
33. Cayan F.N., Pakalapati S.R., Celik I., Xu C., Zondlo J. A degradation model for solid oxide fuel cell anodes due to impurities in coal syngas: Part I theory and validation. Fuel Cells 2012, 12:464-473.
34. Haga K., Shiratori Y., Nojiri Y., Ito K., Sasaki K. Phosphorus poisoning of Ni-cermet anodes in solid oxide fuel cells. J Electrochem Soc 2010, 157:B1693-B1700.
35. Zhi M., Cayan F.N., Celik I., Gemmen R., Pakalapati S.R., Wu N.Q. Temperature and impurity concentration effects on degradation of Nickel/Yttria-stabilised Zirconia anode in PH3-containing coal syngas. Fuel Cells 2010, 10:174-180.
36. Couling D.J., Nguyen H.V., Green W.H. Screening of metal oxides and metal sulfides as sorbents for elemental mercury at elevated temperatures. Fuel 2012, 97:783-795.
37. Rupp E.C., Granite E.J., Stanko D.C. Method for detection of trace metal and metalloid contaminants in coal-generated fuel gas using gas chromatography/ion trap mass spectrometry. Anal Chem 2010, 82:6315-6317.
38. Jain A., Seyed-Reihani S.A., Fischer C.C., Couling D.J., Ceder G., Green W.H. Ab initio screening of metal sorbents for elemental mercury capture in syngas streams. Chem Eng Sci 2010, 65:3025-3033.
39. Alptekin G, Lind J, Amalfitano R, Copeland R. Sorbents for mercury removal from coal-derived synthesis gas. TDA Asso. document, on December 18, 2013. http://www.tda.com/Library/docs/Alptekin_NETL_Mercury%20Removal.pdf.
40. Schlather J, Turk B. Comparison of a new warm-gas desulfurization process versus traditional scrubbers for a commercial IGCC power plant. In: Gasification technologies conference, 2007, San Francisco, CA; 2007.
41. Kim K., Park N. Removal of hydrogen sulfide from a steam-hydrogasifier product gas by zinc oxide sorbent: effect of non-steam gas components. J Ind Eng Chem 2010, 16:967-972.
42. Cheah S., Carpenter D.L., Magrini-Bair K.A. Review of mid- to high-temperature sulfur sorbents for desulfurization of biomass- and coal-derived syngas. Energy Fuel 2009, 23:5291-5307.
43. Wang X.H., Jia J.P., Zhao L., Sun T.H. Chemisorption of hydrogen sulphide on zinc oxide modified aluminum-substituted SBA-15. Appl Surf Sci 2008, 254:5445-5451.
44. Kim K., Jeon S.K., Vo C., Park C.S., Norbeck J.M. Removal of hydrogen sulfide from a steam-hydrogasifier product gas by zinc oxide sorbent. Ind Eng Chem Res 2007, 46:5848-5854.
45. 2S removal from steam-containing gas mixtures with ZnO for fuel cell application. 1. ZnO particles and extrudates. Energy Fuel 2004, 18:576-583.
46. 2S removal from simulated ELCOGAS IGCC syngas. Chem Eng Sci 2005, 60:2977-2989.
47. Jung S.Y., Park J.J., Lee S.J., Jun H.K., Lee S.C., Kim J.C. A study of the sulfidation and regeneration reaction cycles of Zn-Ti-based sorbents with different crystal structures. Korean J Chem Eng 2010, 27:1428-1434.
48. Sakurai T., Okamoto M., Miyazaki H. Structural property changes of fine zinc ferrite sorbent during sulfidation and regeneration. Kagaku Kogaku Ronbun 1994, 20:268-274.
49. Christoforou S.C., Efthimiadis E.A., Vasalos I.A. Sulfidation - regeneration cycles of ZnO-containing and CaO-containing sorbents. Environ Sci Technol 1995, 29:372-383.
50. Huang J.J., Zhao J.T., Wei X.F., Wang Y., Bu X.P. Kinetic studies on the sulfidation and regeneration of zinc titanate desulfurization sorbent. Powder Technol 2008, 180:196-202.
51. Turk BS, Merkel T, Lopez-Ortiz A, Gupta RP, Portzer JW, Krishnan GN, et al. Novel technologies for gaseous contaminants control, DOE Final report, September 2001. http://www.netl.doe.gov/technologies/coalpower/gasification/projects/gas-clean/docs/Novel-2-7.pdf.
52. Richards A.E., McNeeley M.G., Kee R.J., Sullivan N.P. Gas transport and internal-reforming chemistry in Ni-YSZ and ferritic-steel supports for solid-oxide fuel cells. J Power Sources 2011, 196:10010-10018.
53. Yang Y.P., Du X.Z., Yang L.J., Huang Y., Xian H.Z. Investigation of methane steam reforming in planar porous support of solid oxide fuel cell. Appl Therm Eng 2009, 29:1106-1113.
54. Ohrn TaL Z. Rolls-Royce coal-based SECA program Update, 12th Annual SECA Conference, Pittsburgh, PA, July 2011.
55. Ding D., Liu M., Liu Z., Li X., Blinn K., Zhu X., et al. Efficient electro-catalysts for enhancing surface activity and stability of SOFC cathodes. Adv Energy Mater 2013.
56. Williams M.C., Strakey J.P., Surdoval W.A., Wilson L.C. Solid oxide fuel cell technology development in the U.S. Solid State Ionics 2006, 177:2039-2044.
57. Piroonlerkgul P., Kiatkittipong W., Arpornwichanop A., Soottitantawat A., Wiyaratn W., Laosiripojana N., et al. Integration of solid oxide fuel cell and palladium membrane reactor: technical and economic analysis. Int J Hydrogen Energy 2009, 34:3894-3907.
58. Williams M.C., Gemmen R., Richards G. Optimal operational performance of fuel cells. ECS Trans 2013, 51:175-182.
59. Silla H. Chemical process engineering: design and economics 2003, M. Dekker.
60. Mankins JC. Technology readiness levels. White Paper, April 6, 1995.
61. Sunarso J., Baumann S., Serra J.M., Meulenberg W.A., Liu S., Lin Y.S., et al. Mixed ionic-electronic conducting (MIEC) ceramic-based membranes for oxygen separation. J Membrane Sci 2008, 320:13-41.
62. Elsayed Y.M., Evans R.B. Thermoeconomics and design of heat systems. J Eng Power 1970, 92:27-35.
63. El-Sayed Y. The thermoeconomics of energy conversions 2003, Elsevier.
64. Bejan A. Entropy generation minimization: the method of thermodynamic optimization of finite-size systems and finite-time processes 1996, CRC Press.
65. 2 with application to carbon capture and storage. Int J Greenh Gas Con 2008, 2:219-229.
66. U.S. Energy Information Administration. Electric Sales, Revenue, and Average Price, November 13, 2012. http://www.eia.gov/electricity/sales_revenue_price/.
67. Donald G., Newnan P.D., Lavelle J.P., Eschenbach T.G. Essentials of engineering economic analysis 2002, Oxford University Press.