Engineering benefits of Mass recirculation in novel energy technologies with CO2 capture

Rynek Energii

Volumn 88, Issue 3, 2010, Pages 151-158

  Budzianowski, Wojciech M ^a  

^a WROCLAW UNIVERSITY OF TECHNOLOGY   (Poland)

Author keywords

CO2 capture; Mass recirculation; Membrane separation; Oxy fuel combustion

Indexed keywords

EID: 77954267427     PISSN: 14255960     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Article

References (39)

1. 2 capture using OMCM technology. Energy Procedia 1 (2009) 335-342.
2. Anderson R. E., Brandt H., Viteri F.: US20050126156A1.
3. Anderson R. E., Viteri R: WO2001090548.
4. Asen K. I., Sandvold E.: US20016298664.
5. Bebar L., Stehlik P., Havlen L., Oral J.: Analysis of using gasification and incineration for thermal processing of wastes. Applied Thermal Engineering 25 (2005) 1045-1055.
6. Blomen E., Hendriks C, Neele F.: Capture technologies: improvements and promising developments. Energy Procedia 1 (2009) 1505-1512.
7. Budzianowski W. M.: A rate-based method for design of reactive gas-liquid systems, Rynek Energii (4) (2009) 21-26.
8. Budzianowski W., Koziol A.: Stripping of ammonia from aqueous solutions in the presence of carbon dioxide: Effect of negative enhancement of mass transfer. Chemical Engineering Research and Design 83 (2005) 196-204.
9. Budzianowski W. M., Miller R.: Auto-thermal combustion of lean gaseous fuels utilizing a recuperative annular double-layer catalytic converter. Canadian Journal of Chemical Engineering 86 (2008) 778-790.
10. Budzianowski W. M., Miller R.: Superadiabatic lean catalytic combustion in a high-pressure reactor. International Journal of Chemical Reactor Engineering 7 (2009) A20.
11. Buecker D., Griffin T., Winkler D.: WO2005064232.
12. 2 enhanced gasification of biomass fuels. Environmental Engineering Science 26 (2009) 703-713.
13. Chen W.-H., Chiu T.-W., Hung H.-I.: Hysteresis loops of methane catalytic partial oxidation for hydrogen production under the effects of varied Reynolds number and Damköhler number. International Journal of Hydrogen Energy 35 (2010) 6291-6302.
14. 2 capture by limestone and dolomite. Energy and Fuel 23 (2009) 1437-1444.
15. Christou C, Hadjipaschalis I., Poullikkas A.: Assessment of integrated gasification combined cycle technology competitiveness. Renewable and Sustainable Energy Reviews 12 (2008) 2459-2471.
16. 2 absorption with polyacrylamide buffering bead capture. International Journal of Greenhouse Gas Control 3 (2009) 401-410.
17. x combustors utilizing exhaust gas recirculation for post-combustion carbon capture. Energy Procedia 1 (2009) 3809-3816.
18. 2 capture technology - The US Department of Energy's Carbon Sequestration Program. International Journal of Greenhouse Gas Control 2 (2008) 9-20.
19. 2 concentration in oxy-fuel combustion of methane. Energy and Fuel 22 (2008) 291-296.
20. 2 sorbents under realistic calcination condition. Energy and Fuel 21 (2007) 3560-3562.
21. Holladay J. D., Hu J., King D. L., Wang Y.: An overview of hydrogen production technologies. Catalysis Today 139 (2009) 244-260.
22. 2 capture. Industrial Engineering Chemistry Research 44 (2005) 8084-8094.
23. Koh D.: US20080272340Al.
24. 2 separation on the efficiency of a coal-fired power plant. Energy 35 (2010) 841-850.
25. Kotowicz J., Janusz-Szymańska K.: Integration of the coal-fired power plant thermal circuit with the membrane CCS installation. Rynek Energii (6) (2009) 123-128.
26. Lee H. J., Lee J. D., Linga P., Englezos P., Kim Y. S., Lee M. S., Kim Y. D.: Gas hydrate formation process for pre-combustion capture of carbon dioxide. Energy 35 (2010) 2729-2733.
27. Leo A, Liu S, Diniz da Costa JC. Development of mixed conducting membranes for clean coal energy delivery. Int J Greenhouse Gas Control 3 (2009) 357-367.
28. 2 capture and storage system. Applied Energy 86 (2009) 202-213.
29. 2 coal combustion with heat recirculation. Fuel 82 (2003) 1427-1436.
30. Muradov N., Choi P., Smith F., Bokerman G.: Integration of direct carbon and hydrogen fuel cells for highly efficient power generation from hydrocarbon fuels. Journal of Power Sources 195 (2010) 1112-1121.
31. Normann F., Andersson K., Leckner B., Johnsson F.: Emission control of nitrogen oxides in the oxy-fuel process. Progress in Energy and Combustion Science 35 (2009) 385-397.
32. 2 purification. International Journal of Greenhouse Gas Control 3 (2009) 528-534.
33. 2 gas separation membranes for the capture of carbon dioxide from power plant flue gases. Journal of Membrane Science 279 (2006) 1-49.
34. Rohde A., Bergins C, Klauke F., Ehmann M., Buddenberg T., Vollmer B., Krause T., Gwosdz A.: WO2009100881A2.
35. Scholes C. A., Kentish S. E., Stevens G. W.: Carbon dioxide separation through polymeric membrane systems for flue gas applications. Recent Patents on Chemical Engineering 1 (2008) 52-66.
36. 2 capture and storage: Closing the knowing-doing gap. Chemical Engineering Research and Design 84 (2006) 739-763.
37. 2 capture process. Energy Procedia 1 (2009) 1443-1450.
38. 2 capture by carbon fibre monolithic adsorbents. Progress in Energy and Combustion Science 35 (2009) 438-455.
39. Wall T., Liu Y., Spero C, Elliott L., Khare S., Rathnam R., Zeenathal F., Moghtaderi B., Buhre B., Sheng C, Gupta R., Yamada T., Makino K., Yu J.: An overview on oxyfuel coal combustion-State of the art research and technology development. Chemical Engineering Research and Design 87 (2009) 1003-1016.