1.The impact of NiO on microstructure and electrical property of solid oxide fuel cell anode.
Yan LI ; Zhong-yang LUO ; Chun-jiang YU ; Dan LUO ; Zhu-an XU ; Ke-fa CEN
Journal of Zhejiang University. Science. B 2005;6(11):1124-1129
Ni-Ce(0.8)Sm(0.2)O(1.9) (Ni-SDC) cermet was selected as anode material for reduced temperature (800 degrees C) solid oxide fuel cells in this study. The influence of NiO powder fabrication methods for Ni-SDC cermets on the electrode performance was investigated so that the result obtained can be applied to make high-quality anode. Three kinds of NiO powder were synthesized with a fourth kind being available in the market. Four types of anode precursors were fabricated with these NiO powders and Ce(0.8)Sm(0.2)O(1.9) (SDC), and then were reduced to anode wafers for sequencing measurement. The electrical conductivity of the anodes was measured and the effect of microstructure was investigated. It was found that the anode electrical conductivity depends strongly on the NiO powder morphologies, microstructure of the cermet anode and particle sizes, which are decided by NiO powder preparation technique. The highest electrical conductivity is obtained for anode cermets with NiO powder synthesized by NiCO(3).2Ni(OH)(2).4H(2)O or Ni(NO(3))(2).6H(2)O decomposition technique.
Electric Impedance
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Electric Power Supplies
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Electrochemistry
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instrumentation
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methods
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Electrodes
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Equipment Design
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Equipment Failure Analysis
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Nickel
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chemistry
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Powders
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Surface Properties
2.Experiment and mechanism investigation on advanced reburning for NO(x) reduction: influence of CO and temperature.
Zhi-Hua WANG ; Jun-Hu ZHOU ; Yan-Wei ZHANG ; Zhi-Min LU ; Jian-Ren FAN ; Ke-Fa CEN
Journal of Zhejiang University. Science. B 2005;6(3):187-194
Pulverized coal reburning, ammonia injection and advanced reburning in a pilot scale drop tube furnace were investigated. Premix of petroleum gas, air and NH3 were burned in a porous gas burner to generate the needed flue gas. Four kinds of pulverized coal were fed as reburning fuel at constant rate of 1g/min. The coal reburning process parameters including 15% approximately 25% reburn heat input, temperature range from 1100 degrees C to 1400 degrees C and also the carbon in fly ash, coal fineness, reburn zone stoichiometric ratio, etc. were investigated. On the condition of 25% reburn heat input, maximum of 47% NO reduction with Yanzhou coal was obtained by pure coal reburning. Optimal temperature for reburning is about 1300 degrees C and fuel-rich stoichiometric ratio is essential; coal fineness can slightly enhance the reburning ability. The temperature window for ammonia injection is about 700 degrees C approximately 1100 degrees C. CO can improve the NH3 ability at lower temperature. During advanced reburning, 72.9% NO reduction was measured. To achieve more than 70% NO reduction, Selective Non-catalytic NO(x) Reduction (SNCR) should need NH3/NO stoichiometric ratio larger than 5, while advanced reburning only uses common dose of ammonia as in conventional SNCR technology. Mechanism study shows the oxidization of CO can improve the decomposition of H2O, which will rich the radical pools igniting the whole reactions at lower temperatures.
Air Pollutants
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chemistry
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isolation & purification
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Carbon Monoxide
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chemistry
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Coal
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Computer Simulation
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Hot Temperature
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Models, Chemical
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Nitrogen Oxides
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chemistry
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isolation & purification
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Oxidation-Reduction
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Temperature