Production of pure hydrogen and synthesis gas with Cu-Fe oxygen carriers using combined processes of chemical looping combustion and methane decomposition/reforming

International Journal of Hydrogen Energy

Volumn 40, Issue 4, 2015, Pages 1698-1708

  Siriwardane, Ranjani ^a   Tian, Hanjing ^a,b   Fisher, James ^a  

^a NATIONAL ENERGY TECHNOLOGY LABORATORY   (United States)

^b West Virginia University   (United States)

Author keywords

Chemical looping; CuO Fe2O3 oxides; Hydrogen production; Methane reforming; Synthesis gas production

Indexed keywords

ALUMINA; ALUMINUM OXIDE; BINARY ALLOYS; CARBON; CATALYSTS; COMBUSTION; COPPER ALLOYS; COPPER OXIDES; DECOMPOSITION; HEMATITE; HYDROGEN PRODUCTION; IRON ALLOYS; METHANE; OXYGEN; STEAM; SYNTHESIS GAS;

CHEMICAL LOOPING; CHEMICAL LOOPING COMBUSTION; DECOMPOSITION OF METHANE; HYDROGEN AND SYNTHESIS GAS; METHANE DECOMPOSITION; METHANE REFORMING; METHANE STEAM REFORMING; SYNTHESIS GAS PRODUCTION;

STEAM REFORMING;

EID: 84920675363     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2014.11.090     Document Type: Review

References (31)

1. M. Ishida, D. Zheng, and T. Akehata Evaluation of a chemical-looping-combustion power-generation system by graphic exergy analysis Energy 12 1987 147 154
2. T. Hatanaka, S. Matsuda, and H. Hatano IECEC-97: proceedings of the thirty-second intersociety energy conversion engineering conference; Honolulu, Hawaii vol. 1 1997 944 948
3. J. Adanez, A. Abad, F. Garcia-Labiano, P. Gayan, and L. Diego Progress in chemicals-looping combustion and reforming technologies Prog Energy Combust Sci 38 2012 215 282
4. R. Siriwardane, E. Ksepko, H. Tian, J. Poston, T. Simonyi, and M. Sciazko Interaction of iron-copper mixed metal oxide oxygen carriers with simulated synthesis gas derived from steam gasification of coal Appl Energy 107 2013 111 123
5. R. Siriwardane, H. Tian, T. Simonyi, and J. Poston Synergetic effects of mixed copper-iron oxides oxygen carriers in chemical looping combustion Fuel 108 2013 319 333
6. Johansson M, Mattisson T, Ryden M, Lyngfelt A. Carbon capture via CLC and reforming: international seminar on carbon sequestration and climate change; Rio de Janeiro 24-27, Oct. 2006.
7. White J, Schutte E, Rolfe S. Cyclic catalytic upgrading of chemical species using metal oxide materials. US 2008/0164443 A1.
8. Zeng Y, Tamhankar S, Limbach K, Krishnan S. Hydrocarbon partial oxidation process. US 2000/6143203.
9. 3 perovskite-type oxides as oxygen carriers in chemical-looping reforming of methane Fuel 108 2013 465 473
10. 3 J Catal 293 2012 175 185
11. 2 as the oxygen carrier for partial oxidation of methane to synthesis gas in molten salts: thermodynamic analysis and experimental investigation J Nat Gas Chem 16 2007 6 11
12. 2 as oxygen carrier for chemical looping combustion and reforming Energy Environ Sci 2 2009 970 981
13. M. Ortiz, L. de Diego, A. Abad, F. Garcia-Labiano, P. Gayan, and J. Adanez Catalytic activity of Ni-based oxygen carriers for methane steam reforming in CLC processes Energy Fuels 26 2012 791 800
14. 2 capture Ind Eng Chem Res 49 2010 1018 1028
15. Thomas TJ, Fan LS, Gupta P,Velazquez V, Gilberto L. Combustion looping using composite oxygen carriers. US 7, 767,19.
16. D. Sridhar, A. Tong, H. Kim, L. Zeng, F. Li, and L.S. Fan Syngas chemical looping process: design and construction of a 25 kWth subpilot unit Energy Fuels 26 2012 2292 2302
17. A. Tong, D. Siridhar, Z. Sun, H.R. Kim, L. Zeng, and F. Wang Continuous high purity hydrogen generation from a syngas chemical looping 25 kWth sub-pilot unit with 100% carbon capture Fuel 103 2013 495 505
18. F. Li, H.R. Kim, D. Siridhar, F. Wang, L. Zeng, and J. Chen Syngas chemical looping gasification process: oxygen carrier particle selection and performance Energy Fuels 23 2009 4182 4189
19. F.X. Chiron, and G.S. Patience Kinetics of mixed copper-iron based oxygen carriers for hydrogen production by chemical looping water splitting Int J Hydrogen Energy 37 2012 10526 10538
20. W.C. Cho, D.Y. Lee, and M.W. Seo Continuous operation characteristics of chemical looping hydrogen production system Appl Energy 113 2014 1667 1674
21. S.G. Kang, R. Sung, D.K. Sang, K.S. Kang, and C.S. Park Hydrogen production from two-step steam methane reforming in a fluidized bed reactor Int J Hydrogen Energy 34 2009 1301 1309
22. 2 medium for syngas and hydrogen production from two-step thermochemical methane reforming Int J Energy Res 34 2010 422 430
23. M. Behdad Hydrogen enrichment of fuels using a novel miniaturized chemical looping steam reformer Chem Eng Res Des 9 2012 19 25
24. 4 as an oxidant for two-step thermochemical methane reforming Int J Hydrogen Energy 33 2008 4560 4568
25. 2 medium Int J Hydrogen Energy 34 2009 1801 1808
26. M. Ryden, and A. Lyngfelt Using steam reforming to produce hydrogen with carbon dioxide capture by CLC Int J Hydrogen Energy 31 2006 1271 1283
27. 2 capture by steam reforming of methane integrated with a chemical-looping combustion system Int J Hydrogen Energy 38 2013 11878 11892
28. Rifflart S, Patience G, Chiron F. Method for producing synthesis gas. US 2012/0319051 A1.
29. H.F. Abbas, and W.M.A. Wan Duad Hydrogen production by methane decomposition: a review Int J Hydrogen Energy 35 2010 1160 1190
30. J.M. Lane, and P.L. Spath Technoeconomic analysis of the thermocatalytic decomposition of natural gas 2001 Department of Energy U.S. Colorado USA NREL/TP-S10-31351
31. M. Steinburg Fossil fuel decarbonation technology for mitigating global warming Int J Hydrogen Energy 24 8 1999 771 777