화학공학소재연구정보센터
Solid State Ionics, Vol.180, No.17-19, 1091-1099, 2009
Characterization of NiO-yttria stabilised zirconia (YSZ) hollow fibres for use as SOFC anodes
NiO-yttria stabilised zirconia (YSZ) hollow fibres with varying NiO content and a desired microstructure were prepared using a phase inversion technique and sintering. By controlling the fabrication parameters, microstructures with predominately finger-like pores near the inner and outer surfaces and a denser central layer with sponge-like pores were produced, for use as substrates for anode-supported hollow fibre solid oxide fuel cells (HF-SOFC). The NiO-YSZ fibres were reduced to Ni-YSZ at 250-700 degrees C in hydrogen flowing at 20 cm(3) min(-1) to produce Ni-YSZ hollow fibres, the mechanical and electrical properties of which were determined subsequently, reduction to Ni being verified by X-ray diffraction. The effects of NiO concentration and sintering temperature of the fibre precursors on the conductivity, strength and porosity of the reduced hollow fibres were investigated to assess their suitability for use as anode substrates. As expected, increasing Ni concentration increased electrical conductivities and decreased mechanical strength. Sintering temperature had a critical effect in producing axially conductive hollow fibres of sufficient mechanical strength for use as SOFC anodes. The hollow fibres retained their initial microstructure through the reduction process, though ca. 41% volume contraction is predicted on reduction of NiO to Ni, producing increased porosity in the reduced fibres. The mean porosity of the Ni-YSZ hollow fibres was ca. 60% and ca. 40% after sintered at 1250 degrees C and 1400 degrees C, respectively. The mean pore sizes for all the fibres after reduction varied between ca. 0.3 and 1 mu m. The hollow fibres produced with 60% NiO, of length ca. 300 mm, electrical conductivities of ca. (1-2.25) x 10(5) S m(-1) and a porosity of ca. 43% are being used currently to construct and test the electrical behaviour of an anode-supported HF-SOFC. (c) 2009 Elsevier B.V. All rights reserved.