Preparation and Characterization of Mixed-conducting Supported Hollow Fiber Membrane

doi:10.15541/jim20140645

Abstract

Abstract:

Sr_0.7Ba_0.3Fe_0.9Mo_0.1O_3-_δ (SBFM) hollow fiber supports were prepared by dry-wet spinning technology. SrCo_0.8Fe_0.2O_3-_δ doped Nb₂O₅(SCFNb) was selected as membrane material, SCFNb/SBFM supported hollow fiber membranes were successfully prepared by a combined spin-spraying and co-sintering method. XRD, SEM, thermal expansion technique, oxygen permeability and membrane reaction tests were utilized to characterize the crystal phase structures, microstructure, sintering behavior, oxygen permeation flux, and reaction performance of membranes and/or supports, respectively. XRD patterns show that the membranes and supports are composed of perovskite main phase. SEM images indicate that the support has an asymmetric structure with a sponge-like microporous/finger-like porous structure. The membrane surface is dense and crack-free, and the membrane layer with a thickness of about 5 μm is well bonded with the support. At 900℃, the oxygen permeation flux of the membrane is 0.74 mL/(cm²·min). No degradation of performance is observed in the membrane reactor under partial oxidation of methane during continuously operating for 200 h at 850℃, and the oxygen permeation flux can reach 4.5 mL/(cm²·min). It is demonstrated that the SCFNb/SBFM supported hollow fiber membrane exhibits high oxygen permeation flux and good stability of the membrane reactor.

Key words: supported hollow fiber, mixed-conducting membrane, oxygen permeation, membrane reaction

CLC Number:

TQ174

LIU Zheng-Kun, ZHU Jia-Wei, JIN Wan-Qin. Preparation and Characterization of Mixed-conducting Supported Hollow Fiber Membrane[J]. Journal of Inorganic Materials, 2015, 30(6): 621-626.

Figures/Tables 7

Fig. 1 Schematic diagram of membrane module and membrane reactor

Fig. 2 XRD patterns of SCFNb membrane and SBFM support

Fig. 3 Shrinkage curves (a) and shrinkage rate curves (b) of SCFNb membrane layer and SBFM support layer

Fig. 4 SEM images of SCFNb/SBFM supported hollow fiber membrane (a) Cross section; (b) EDX analysis of cross section; (c) Outside surface of membrane; (d) Hollow fiber support

Fig. 5 Temperature dependence of oxygen fluxes through SCFNb/SBFM supported hollow fiber

Fig. 6 CO selectivity, CH4 conversion, H2 /CO and O2 permeation flux as a function of temperature Reaction side: He = 20 mL/min, CH4 =3 mL/min; Air side: air = 150 mL/min

Fig. 7 Long-term performance of reaction in the SCFNb/ SBFM supported hollow fiber membrane reactor at 850℃

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