Paper Titles

Self Diagnostic EB-PVD Thermal Barrier Coatings
p.65

A CFD Model of Erosion-Corrosion of Fe at Elevated Temperatures in Aqueous Environments
p.75

Effects of Firing Conditions on the Coal Ash Fusibility Test
p.87

Supported Oxygen Transport Membranes for Oxyfuel Power Plants
p.93

Water Gas Shift Reaction in Pd-Based Membrane Reactors
p.99

Ceramic Membranes in Carbon Dioxide Capture: Applications and Potentialities
p.105

Two-Step Thermochemical Cycles for High-Temperature Solar Hydrogen Production
p.119

Selection of Ceramics and Composites as Materials for a Supercritical Water Gasification (SCWG) Reactor
p.129

High Temperature Water Electrolysis Using Metal Supported Solid Oxide Electrolyser Cells (SOEC)
p.135

HomeAdvances in Science and TechnologyAdvances in Science and Technology Vol. 72Water Gas Shift Reaction in Pd-Based Membrane...

Water Gas Shift Reaction in Pd-Based Membrane Reactors

Article Preview

Abstract:

Water-gas shift reaction is an important industrial reaction, used for producing synthesis gas and ammonia as well as pure hydrogen for supplying at PEM fuel cells. In this work, an overview on water gas shift reaction performed in Pd-based membrane reactors is shown, paying particular attention to the influence on the performances of some operating variables such as reaction temperature, reaction pressure, H2O/CO molar ratio and sweep gas.

You might also be interested in these eBooks

5th FORUM ON NEW MATERIALS PART A

Info:

Periodical:

Advances in Science and Technology (Volume 72)

Pages:

99-104

DOI:

https://doi.org/10.4028/www.scientific.net/AST.72.99

Citation:

Cite this paper

Online since:

October 2010

Authors:

Angelo Basile, Pietro Pinacci, Silvano Tosti, Marcello De Falco, Claudio Evangelisti, Tiziana Longo, Simona Liguori, Adolfo Iulianelli

Keywords:

Hydrogen Production, Membrane Reactor, PEM Fuel Cell, Water Gas Shift Reaction

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2010 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] A. Basile, A. Criscuoli, F. Santella and E. Drioli: Gas Sep. Purif. Vol. 10 (1996), pp.243-254.

[2] C. Bosch and W. Wild, Canadian Patent 153, 379 (1914).

[3] J.H. Wee: Renew. Sustain. En. Reviews Vol. 11 (2007), pp.1720-1738.

[4] J.O.M. Bockris: Environment Vol. 13 (1971), p.51.

[5] B.C.H. Steele and A. Heinzel: Nature Vol. 414 (2001), pp.345-352.

[6] N. Patel, K. Ludwig and P. Morris in: Insert flexibility into your hydrogen network - Part 1. Hydrocarbon Process., Int. Ed., 84 (2005).

[7] S. Uemiya, N. Sato, H. Ando and E. Kikuchi: Ind. Eng. Chem. Res. Vol. 30 (1991), pp.585-589.

[8] A. Basile, G. Chiappetta, S. Tosti and V. Violante: Sep. Pur. Techn. Vol. 25 (2001), pp.549-571.

[9] A. Basile, E. Drioli, F. Santella, V. Violante and G. Capannelli: Gas Sep. Purif. Vol 10 (1996), pp.53-61.

[10] A. Basile, V. Violante, F. Santella and E. Drioli: Catal. Today Vol. 25 (1995), pp.321-326.

[11] E. Kikuchi, S. Uemiya, N. Sato, H. Inoue, H. Ando and T. Matsuda: Chem. Lett. Vol. 18 (1989), pp.489-492.

[12] A. Basile, A. Criscuoli, F. Santella and E. Drioli: Gas Sep. Purif. Vol. 10 (1996), pp.243-254.

[13] H. Yoshida, H. Takeshita, S. Konishi, H. Ohno, T. Kurasawa and H. Watanabe: Nucl. Tech. Fusion Vol 5 (1984), pp.178-188.

[14] C. Hsu and R.E. Buxbaum: J. Nucl. Mater. Vol. 141 (1986), pp.238-243.

[15] V. Violante, E. Drioli and A. Basile: Fusion Eng. Des. Vol. 22 (1993), pp.257-263.

[16] S. Tosti, V. Violante, A. Basile, G. Chiappetta, S. Castelli, M. De Francesco, S. Scaglione and F. Sarto: Fusion Eng. Des. Vol. 49-50 (2000), pp.953-958.

DOI: 10.1016/s0920-3796(00)00371-9

[17] A. Brunetti, G. Barbieri, E. Drioli, K.H. Lee, B. Sea and D.W. Lee: Chem. Eng. Proc. Vol. 46 (2007), pp.119-126.

[18] O. Iyoha, R. Enick, R. Killmeyer, B. Howard, B. Morreale and M. Ciocco: J. Membrane Sci. Vol. 298 (2007), pp.14-23.

DOI: 10.1016/j.memsci.2007.03.053

[19] E. Xue, M. O'Keeffe and J.R.H. Ross: Catal. Today Vol. 30 (1996), pp.107-118.

[20] L. Lloyd, D.E. Ridler and M.V. Twigg in: Catalyst Handbook, 2nd edition, edited by M.V. Twigg, Wolfe, London (1989), p.283.

[21] D. Mendes, A. Mendes, L.M. Madeira, A. Iulianelli, J.M. Sousa1 and A. Basile: Asia-Pac. J. Chem. Eng. (2009), in press, DOI: 10. 1002/apj. 364.

[22] J. Sun, J. DesJardins, J. Buglass, and K. Liu: Int. J. Hydrogen En. Vol. 30 (2005), pp.1259-1264.

[23] Y.S. Cheng, M.A. Pena, J.L. Fierro, D.C.W. Hui and K.L. Yeung: J. Membrane Sci. Vol. 204 (2002), pp.329-340.

[24] J.R. Ladebeck and J.P. Wang, in: Catalyst development for water-gas shift. Handbook of Fuel Cells, Fuel Cell Technology and Applications, edited by John Wiley & Sons, England (2003), Vol. 3, pp.190-201.

[25] S. Tosti, A. Basile, G. Chiappetta, C. Rizzello and V. Violante: Chem. Eng. J. Vol. 93 (2003), pp.23-30.

[26] C. Zerva and C.J. Philippopoulos: Appl. Catal. B: Env. Vol 67 (2006), pp.105-112.

[27] O. Goerke, P. Pfeifer and K. Schubert: Appl. Catal. A: Gen. Vol. 263 (2004), pp.11-18.

[28] H. Sakurai, T. Akita, S. Tsubota, M. Ciuchi and M. Haruta: Appl. Catal. A: Gen. Vol. 291 (2005), pp.179-187.

[29] A. Venugopal and M.S. Scurrell: Appl. Catal. A: Gen. Vol. 245 (2003), pp.137-147.

[30] S.T. Daniells, M. Makkee and J.A. Moulijn: Catal. Lett. Vol. 100 (2005), pp.39-47.

[31] T. Utaka, T. Okanishi, T. Takeguchi, R. Kikuchi and K. Eguchi: Appl. Catal. A. Vol 245 (2003), pp.343-351.

[32] S. Giessler, L. Jordan, J.C. Diniz da Costa and G.Q. Lu: Sep. Pur. Techn. Vol. 32 (2003), pp.255-264.

[33] S. Battersby, M.C. Duke, S. Liu, V. Rudolph and J.C. Diniz da Costa: J. Membrane Sci. Vol. 316 (2008), pp.46-52.

[34] M. Broglia. P. Pinacci, C. Valli in: Proc. of ICCMR9, Lyon (Fr) June 28-July 2, (2009).