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Membrane microporous ceramic

Membrane materials have to withstand a pressure difference and relatively high temperatures (500 °C and up). Microporous ceramic membranes have been... [Pg.307]

Bhavc, R. R., J. Gillot and P. K. T. Liu. 1989. High temperature gas separations for coal offgas cleanup with microporous ceramic membranes. Paper 124f read at AIChE Annual Meeting, 5-10 November 1989, San Francisco. [Pg.113]

Uhlhom, R. J. R., M. H. B. J. Huis in t Veld, K. Keizer and A. J. Burggraaf. 1989a. Theory and experiments on transport of condensable gases in microporous ceramic membrane systems. Proc. 1st Inti Cong, Inorganic Membrane, 3-6 July, 323-328, Montpellier. [Pg.147]

V. Schroder, O. Behrend, and H. Schubert Effect of Dynamic Interfacial Tension on the Emulsification Process Using Microporous Ceramic Membranes. J. Colloid Interface Sci. 202, 334 (1998). [Pg.43]

V. Schroder and H. Schubert Emulsification Using Microporous Ceramic Membranes. In Proceedings of the First European Congress on Chemical Engineering (ECCE 1) 2491, Florence Italy (1997). [Pg.43]

Schroder, V., Behrend, O., and Schubert, H. (1998a). Effect of dynamic interfacial tension on the emulsification process using microporous, ceramic membranes. J. Coll. Interf. Sci. 202, 334-340. [Pg.338]

L.V.C. Rees and L. Song in Recent Advances in Gas Separationby Microporous Ceramic Membranes p. 139-186, N.K. Kanellopoulos ed., Elsevier, Amsterdam (2000). [Pg.23]

T. liyama, T. Ohkubo, K. Kaneko, In Recent Advances in Gas Separation by Microporous Ceramic Membranes, Ed. N.K. Kanellopouos, Elsevier, pp.35-66 (2000). [Pg.42]

While dip coating and spin coating are used most often for making microporous ceramic membranes, the filtration technique for forming dynamic membranes can also be used [Okubo et al., 1991]. The filtration method is particularly suitable when the support does not have enough pore volume to supply sufficient slip particles at the support surface to form a layer of membrane. [Pg.49]

FIGURE 6.14 Different mechanisms involved in gas and vapor transport through meso- and microporous ceramic membranes. [Pg.151]

Guizard C and Julbe A. Nanophase ceramic ion transport membranes for oxygen separation and gas stream enrichment. In Kanello-poulos NK (ed.). Recent Advances in Gas Separation by Microporous Ceramic Membranes. Amsterdam Elsevier 2000 435 71. [Pg.178]

Tsuru T, Tomoya H, Tomohisa Y, and Masashi A. Permporometry characterization of microporous ceramic membranes. J Membr Sci 2001 186 257-265. [Pg.313]

R.S.A. de Lange, J.H.A. Hekkink, K. Keizer and A.J. Burggraaf, Formation and characterisation of supported microporous ceramic membranes prepared by sol-gel modification techniques. /. Membr. Sci., 99 (1995) 57-75. [Pg.34]

M. Chai, K. Sekizawa, M. Machida, K. Eguchi and H. Arai, Preparation of heat resistant microporous ceramic membranes for selective gas separation. Ceram. Lett., 99 (1991) 530. C. Guizard, N. Idrissi, A. Larbot and L. Cot, An electronic conductive membrane from a sol-gel process. Br. Ceram. Proc., 38 (1986) 263. [Pg.256]

Inorganic membrane development is still in progress [57] (see also Section 14.2.2). Microporous silica membranes have been developed at several universities and research institutes. Membrane selectivities of 15 and 20 for the separation of H2 from CO2 have been reported. Even higher selectivities for H2 arid CO, CH4 and N2 have been measured [20,57]. Most measurements reported in the literature have been performed on a laboratory scale. However, it has been shown that it is possible to upscale these microporous ceramic membranes to, at least, bench scale [31,57]. With other membranes such as noble (Pd) metal membranes and dense ceramic membranes very high and almost infinite selectivities for hydrogen are possible [58]. The permeation of these membranes is generally smaller than the permeation of microporous membranes. [Pg.669]

Q. Xu and M. A. Anderson, Sol-Gel Route to Synthesis of Microporous Ceramic Membranes Thermal Stability of Ti02-Zr02 Mixed Oxides, J. Am. Ceram. Soc., 76[8], 2093-97 (1993). [Pg.34]

Matsumoto, K., Kawahara, M., and Ohya, H., Cross-Flow Filtration of Yeast by Microporous Ceramic Membrane with Backwashing, J. Ferment. Technol., 66(2) 199-205 (1988)... [Pg.344]

Lin J, Kumakiri 1, Nair BN, Alsyouri H. Microporous ceramic membranes review. Sep Purif Methods. 2002 31(2) 229. [Pg.296]

Jobic H (2000) In Kanellopoulos NK (ed) Recent advances in gas separation by microporous ceramic membranes. Elsevier, Amsterdam, p 109... [Pg.43]

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See also in sourсe #XX -- [ Pg.669 ]



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