04/01864 Intelligent decoupling control of power plant main steam pressure and power output: Liu, H. et al. International Journal of Electrical Power & Energy Systems, 2003, 25, (10), 809–819

HYSYS (a steady state simulator) and the material and energy flows for each stream are obtained. For the peak load of 50 kW, it is found that 14 1/h naphtha is needed, which means that a 70 1 fuel tank in the vehicle is sufficient for 5 h drive. The amount of water needed is not a critical factor, since it is generated in the fuel cell and quantities of water-makeup can be kept at the minimum level. Catalytic processes involved are briefly reviewed and commercial catalysts used are indicated. The amount of catalyst required in each reactive unit is computed by employing the design parameters (temperature, pressure, and space velocities) reported in the literature. In the desulfurization step, it is found that about 1.6 1 of a bed of ZnO is capable of handling a stream of naphtha with 1500 ppm of sulfur for 45 h of continuous operation before regeneration or replacement of the bed becomes necessary. This, however, is based on operation at 10 atm. Operation at lower pressure level will increase the desulfurization catalyst requirements, maybe to a prohibitive level. Over the reformer Liquid-Hourly Space-Velocity range of 1-4 h 1, the amount of the supported nickel catalyst varies from 14 to 4 1, respectively. For the LT shift reactor the amount of catalyst required ranges from 4 to 60 1 on going from 3x102 to 4x103 h -1 typical Gas-Hourly Space-Velocity. The catalyst here is CuO-ZnO supported on A1203. The last methanation step to remove traces of poisonous CO requires about 3.5 1 of nickel supported by various oxides. To selectively separate hydrogen, it is suggested to use a palladium-silver membrane, which is reported to give ultra-pure hydrogen.

04/01862 Improving the steady-state loading margin to voltage collapse in the North-West Control Area of the Mexican Power System