Alternative Transportation Energy

Transportation energy issues are moving to the forefront of the public consciousness in the U.S. and particularly California, and gaining increasing attention from legislators and regulators. The three principal concerns motivating interest in transportation energy are urban air quality, oil dependence, and the threat of global warming. Transportation fuels are a principal contributor to each of these. The transportation sector, mostly motor vehicles, contributes roughly half the urban air pollutants, almost one-third of the carbon dioxide, and consumes over 60% of all petroleum

THE ECONOMICS OF ALTERNATIVE FUEL USE: SUBSTITUTING METHANOL FOR GASOLINE

Alternative fuel advocates recommend substituting methanol for gasoline since methanol cars potentially pollute less. However, because the substitution is costly and the reduction of ozone precursor emissions is relatively small, using methanol raises questions about cost effectiveness. Copyright 1990 Western Economic Association International.

Design, construction, and operation of a 150 kW solar-powered irrigation facility : phase II, final report, September 30, 1977-September 30, 1979 /

Acurex Corporation was contracted to design, construct and startup a solar powered experimental facility to provide 150 kW of electric power for the operation of deep-well irrigation pumps. Acurex also supplied its Model 3001 Solar Collector. This facility is located on the Dalton Cole Farm near Coolidge, Arizona. The facility is presently the largest operating solar thermal powerplant in the world. Experience gained on this plant will pave the way for many future power generation facilities. The present International Energy Agency (IEA) project in Spain is utilizing technology learned on the 150 kW project. The project was operated and completed by September 30, 1979 and was turned over to the DOE technical advisor, Sandia Laboratories, and the University of Arizona on October 1, 1979. The dedication of the project occurred on November 9, 1979. The solar collectors were tracking on full automatic, and the power conversion system started up and operated on automatic control for full demonstration to the public and many honored guests."May 1980."Acurex Corporation was contracted to design, construct and startup a solar powered experimental facility to provide 150 kW of electric power for the operation of deep-well irrigation pumps. Acurex also supplied its Model 3001 Solar Collector. This facility is located on the Dalton Cole Farm near Coolidge, Arizona. The facility is presently the largest operating solar thermal powerplant in the world. Experience gained on this plant will pave the way for many future power generation facilities. The present International Energy Agency (IEA) project in Spain is utilizing technology learned on the 150 kW project. The project was operated and completed by September 30, 1979 and was turned over to the DOE technical advisor, Sandia Laboratories, and the University of Arizona on October 1, 1979. The dedication of the project occurred on November 9, 1979. The solar collectors were tracking on full automatic, and the power conversion system started up and operated on automatic control for full demonstration to the public and many honored guests.Work performed under contract no. ;Mode of access: Internet

La Región: La Región - Epoca 2ª Año XII Número 4238 - 1935 julio 27 (27/07/1935)

Removal of sulfur dioxide (SO{sub 2}) from the flue gas of coal- burning power plants can be achieved by duct spray drying using calcium hydroxide (Ca(OH){sub 2}) slurries. A primary objective of this research was to discover the aspects of mass transfer into Ca(OH){sub 2} slurries which limit SO{sub 2} absorption. A bench- scale stirred tank reactor with a flat gas/liquid interface was used to simulate SO{sub 2} absorption in a slurry droplet. The absorption rate of SO{sub 2} from gas concentrations of 500 to 5000 ppm was measured at 55{degrees}C in clear solutions and slurries of Ca(OH){sub 2} up to 1.0 M (7 wt percent). Results are reported in terms of the enhancement factor, {O}. This research will allow prediction of conditions where the absorption of SO{sub 2} in Ca(OH){sub 2} slurries can be enhanced by changes to liquid phase constituents (under which SO{sub 2} absorption is controlled by liquid film mass transfer). Experiments in the stirred tank have shown that SO{sub 2} absorption in a 1.0 M Ca(OH){sub 2} slurry was completely dominated by gas film mass transfer with a large excess of Ca(OH){sub 2} but becomes controlled by liquid film resistance at greater than 50 percent Ca(OH){sub 2} utilization. (VC

Cordierite silicon nitride filters

The objective of this project was to develop a silicon nitride based crossflow filter. This report summarizes the findings and results of the project. The project was phased with Phase I consisting of filter material development and crossflow filter design. Phase II involved filter manufacturing, filter testing under simulated conditions and reporting the results. In Phase I, Cordierite Silicon Nitride (CSN) was developed and tested for permeability and strength. Target values for each of these parameters were established early in the program. The values were met by the material development effort in Phase I. The crossflow filter design effort proceeded by developing a macroscopic design based on required surface area and estimated stresses. Then the thermal and pressure stresses were estimated using finite element analysis. In Phase II of this program, the filter manufacturing technique was developed, and the manufactured filters were tested. The technique developed involved press-bonding extruded tiles to form a filter, producing a monolithic filter after sintering. Filters manufactured using this technique were tested at Acurex and at the Westinghouse Science and Technology Center. The filters did not delaminate during testing and operated and high collection efficiency and good cleanability. Further development in areas of sintering and filter design is recommended