Oxygen separation through U-shaped hollow fiber membrane using pure CO 2 as sweep gas

AIChE Journal

Volumn 58, Issue 9, 2012, Pages 2856-2864

  Wei, Yanying ^a   Tang, Jun ^a   Zhou, Lingyi ^a   Xue, Jian ^a   Li, Zhong ^a   Wang, Haihui ^a  

^a SOUTH CHINA UNIVERSITY OF TECHNOLOGY   (China)

Author keywords

CO 2; Hollow fiber; Membrane; Mixed conductor; Oxygen permeation

Indexed keywords

EFFECT OF CO; HOLLOW FIBER; HOLLOW FIBER MEMBRANES; MIXED CONDUCTORS; OXY-FUELS; OXYGEN PERMEATION; OXYGEN SEPARATION; OXYGEN-PERMEATION FLUX; PHASE INVERSION SPINNING PROCESS; STABLE MEMBRANES; SWEEP GAS; U-SHAPED; XRD;

FIBERS; MEMBRANES; OXYGEN PERMEABLE MEMBRANES; PHASE STRUCTURE;

CARBON DIOXIDE;

EID: 84862159130     PISSN: 00011541     EISSN: 15475905     Source Type: Journal    
DOI: 10.1002/aic.12802     Document Type: Article

References (53)

1. 2 in the past two centuries. Nature. 1985; 315: 45-47.
2. Tans P. NOAA/ESRL. Trends in Carbon Dioxide. Available at http:// www.esrl.noaa.gov/gmd/ccgg/trends/.
3. 2 records from sites in the sio sampling network. In: Trends. A Compendium of Data on Global Change. Carbon Dioxide Information Analyses Center, Oak Ridge National Laboratory, US Dept. of Energy, Oak Ridge, TN; 2009. doi:10.3334/CDIAC/atg.035.
4. International Energy Agency. Key World Energy Statistics; 2008. Available at http://www.iea.org/textbase/nppdf/free/2008/key_stats_2008.pdf.
5. 2 capture technology. The US Dept. of Energy's Carbon Sequestration Program. Int J Greenh Gas Con. 2008; 2: 9-20.
6. Gough C. State of the art in carbon dioxide capture and storage in the UK: An experts' review. Int J Greenh Gas Con. 2008; 2: 155-168.
7. Kneer R, Toporov D, Forster M, Christ D, Broeckmann C, Pfaff E, Zwick M, Engels S, Modigell M. OXYCOAL-AC: towards an integrated coal-fired power plant process with ion transport membrane-based oxygen supply. Energy Environ Sci. 2010; 3: 198-207.
8. Ren JY, Fan YQ, Egolfopoulos FN, Tsotsis TT. Membrane-based reactive separations for power generation applications: oxygen lancing. Chem Eng Sci. 2003; 58: 1043-1052.
9. 2 decomposition-based power generation cycle, utilizing a high-temperature membrane reactor. Ind Eng Chem Res. 2003; 42: 2618-2626.
10. 2O diluted oxy-fuel combustion for zero-emission power. Proc IMechE Part A. 2005; 219: 121-126.
11. 2 capture using physical absorption, membrane reactors and chemical looping. Fuel. 2009; 88: 2463-2472.
12. Buhre BJP, Elliott LK, Sheng CD, Gupta RP, Wall TF. Oxy-fuel combustion technology for coal-fired power generation. Prog Energy Combust Sci. 2005; 31: 283-307.
13. Tan XY, Li K, Thursfield A, Metcalfe IS. Oxyfuel combustion using a catalytic ceramic membrane reactor. Catal Today. 2008; 131: 292-304.
14. 3-δ. Chem Lett. 1985; 9: 1367-1370.
15. 3-δ (M = Cu or Cr) perovskite membranes. J Electrochem Soc. 1998; 145: 1363-1373.
16. 3-δ -based mixed conductors. Solid State Ionics. 2007; 177: 3433-3444.
17. 3-δ. Solid State Ionics. 1995; 76: 321-329.
18. 3-δ membranes. 1. Permeation in air/He gradients. Solid State Ionics. 1995; 81: 97-109.
19. 3-δ (A' = Ba, Sr, Ca), membrane synthesis, applications and characterization. J Am Ceram Soc. 1998; 81: 1437-1444.
20. Teraoka Y, Zhang HM, Furukawa S, Yamazoe N. Oxygen permeation through perovksite-type oxides. Chem Lett. 1985; 11: 1743-1748.
21. 3-δ oxygen membrane. J Membr Sci. 2000; 172: 177-188.
22. Li QM, Zhu XF, Yang WS. Investigation of structure and oxygen permeability of Ba-Ce-Co-Fe-O system. Mater Res Bull. 2010; 45: 1112-1117.
23. Yin QH, Lin YS. Effect of dopant addition on oxygen sorption properties of La-Sr-Co-Fe-O perovskite type oxide. Adsorption. 2006; 12: 329-338.
24. Yin QH, Yang ZH, Lin YS. Effects of microstructure on oxygen transport in perovskite-type oxides. J Mater Sci. 2006; 41: 4865-4870.
25. Qi XW, Lin YS, Holt CT, Swartz SL. Electric conductivity and oxygen permeability of modified cerium oxides. J Mater Sci. 2003; 38: 1073-1079.
26. 3-δ membranes. J Membr Sci. 2007; 293: 44-52.
27. 2-containing atmospheres: degradation mechanism and materials design. Chem Mater. 2010; 22: 6246-6253.
28. 3-δ at elevated temperatures. Script Mater. 2009; 61: 1083-1086.
29. 3-δhollow fiber membranes. J Membr Sci. 2010; 364: 132-137.
30. Martynczuk J, Efimov K, Robben L, Feldhoff A. Performance of zinc-doped perovskite-type membranes at intermediate temperatures for long-term oxygen permeation and under a carbon dioxide atmosphere. J Membr Sci. 2009; 344: 62-70.
31. 2 stream. AIChE J. 2006; 52: 574-581.
32. Tong JH, Yang WS, Zhu BC, Cai R. Investigation of ideal zirconium-doped perovskite-type ceramic membrane materials for oxygen separation. J Membr Sci. 2002; 203: 175-189.
33. 2O-containing atmosphere. Chem Mater. 2005; 17: 5856-5861.
34. 3-δ membrane according to trace elements and oxygen partial pressure in synthetic air. Energy Procedia. 2009; 1: 369-374.
35. Jin WQ, Zhang C, Zhang P, Fan YQ, Xu NP. Thermal decomposition of carbon dioxide coupled with POM in a membrane reactor. AIChE J. 2006; 52: 2545-2550.
36. 2 over Pd/mixed-conducting oxide catalyst in an oxygen-permeable membrane reactor. Environ Sci Technol. 2008; 42: 3064-3068.
37. 3-δ mixed protonic-electronic conductor. Chem Mater. 2006; 18: 4647-4650.
38. 2 capture application. J Membr Sci. 2009; 335: 140-144.
39. Carolan MF, Motika SA, Dyer PN, Alba PB. Novel compositions capable of operating under high carbon dioxide partial pressures for use in solid-state oxygen producing devices. EP Patent 0732306. 1996.
40. 2-tolerant mixed conducting oxide for catalytic membrane reactor. J Membr Sci. 2009; 340: 141-147.
41. 2-stable and cobalt-free dual-phase membrane for oxygen separation. Angew Chem Int Ed. 2011; 50: 759-763.
42. Caro J, Wang HH, Tablet C, Kleinert A, Feldhoff A, Schiestel T, Kilgus M, Kolsch P, Werth S. Evaluation of perovskites in hollow fibre and disk geometry in catalytic membrane reactors and in oxygen separators. Catal Today. 2006; 118: 128-135.
43. 4+δ prepared by sol-gel method. Sep Purif Technol. 2003; 32: 335-339.
44. 4+δ. J Am Chem Soc. 2010; 132: 2385-2392.
45. Liu SM, Gavalas GR. Preparation of oxygen ion conducting ceramic hollow-fiber membranes. Ind Eng Chem Res. 2005; 44: 7633-7637.
46. Tan XY, Liu Y, Li K. Mixed conducting ceramic hollow-fiber membranes for air separation. AIChE J. 2005; 51: 1991-2000.
47. Tan XY, Li K. Oxygen production using dense ceramic hollow fiber membrane modules with different operating modes. AIChE J. 2007; 53: 838-845.
48. 2.975 hollow fiber membranes. J Membr. Sci. 2001; 193: 249-260.
49. 3-δ. ceramic hollow-fiber membranes for oxygen permeation. AIChE J. 2006; 52: 3452-3461.
50. Schiestel T, Kilgus M, Peter S, Caspary KJ, Wang HH, Caro J. Hollow fibre perovskite membranes for oxygen separation. J Membr Sci. 2005: 258: 1-4.
51. Trunec M. Fabrication of zirconia- and ceria-based thin-wall tubes by thermoplastic extrusion. J Euro Ceram Soc. 2004; 24: 645-651.
52. 3-δ membranes. Solid State Ionics. 2000; 135: 637-642.
53. Wei YY, Liu HF, Xue J, Li Z, Wang HH. Preparation and oxygen permeation of U-shaped perovskite hollow fiber membranes. AIChE J. 2011; 57: 975-984.