Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Electric power plant with

In addition to carbon sequestration, technologies that would provide economic benefits include those that enhance oil recovery, produce coalbed methane, and maintain pressures in depleted gas reservoirs to avoid surface subsidence. Currently, companies in the United States sell one billion standard cubic feet of C02 each day, or approximately the C02 output from one conventional coal-fired electric power plant with a power capacity of 2300 MW. This C02 is used economically and with little or no environmental impact for approximately 70 enhanced oil recovery projects and for other industrial applications. Pipeline specifications for C02 quality, pipeline safety issues, and custody of the C02 have a base of industrial experience that goes back to the 1970s. Today, there are operating C02 pipelines of up to 760 mm (30 inches) in diameter and 640 km (400 miles) in length (Fig. 6-6). [Pg.102]

By mixing a large amount of fly-ash from coal fire electric power plants with a small quantity of Portland cement and water, Yamamoto et al. developed artificial aggregates (coal-ash sand) [1], [2], Various types of coal-ash sand can be made by changing the mix proportion, turning speed of the mixer and also adding some fibers. Lightweight... [Pg.194]

Retrofitting oil- or gas-fired electric power plants with coal gas (30)... [Pg.174]

The former Soviet Union constmcted a 262-km, 508-mm dia experimental coal slurry line between the Belovo open-pit coal mine in Siberia s Kuznets basin to an electric power plant at Novosibirsk, using technology developed by Snamprogetti. Testing began in late 1989 and tentative plans call for constmction of two much larger slurry pipelines, each 3000-km long, with capacity to move a total of 33 x 10 t/yr to industrialized areas near the Ural Mountains (27,33). [Pg.48]

Electric power generation using biomass as a fuel is economic in situations where the cost of the fuel is competitive with that of fossil fuels. The cost of a commercially available biomass steam—electric power plant is about 1500/kW for a wood-fired facility. If wood can be obtained at a cost of 2.00/GJ ( 2.10 X 10 /Btu), the total cost of power for base-load operation would be about 0.05/kWh. If wood or agricultural wastes are available at... [Pg.237]

The utilities in our modern society are so much a part of our lives that it is hard to imagine how we survived without them. An electric power plant generates electricity to heat and light our homes in addition to providing power for the television, refrigerator, and electric toothbrush. When our homes were heated with wood fires, home-made candles were used... [Pg.75]

The Joule-Brayton (JB) constant pressure closed cycle is the basis of the cyclic gas turbine power plant, with steady flow of air (or gas) through a compressor, heater, turbine, cooler within a closed circuit (Fig. 1.4). The turbine drives the compressor and a generator delivering the electrical power, heat is supplied at a constant pressure and is also rejected at constant pressure. The temperature-entropy diagram for this cycle is also... [Pg.1]

The poor efficiencies of coal-fired power plants in 1896 (2.6 percent on average compared with over forty percent one hundred years later) prompted W. W. Jacques to invent the high temperature (500°C to 600°C [900°F to 1100°F]) fuel cell, and then build a lOO-cell battery to produce electricity from coal combustion. The battery operated intermittently for six months, but with diminishing performance, the carbon dioxide generated and present in the air reacted with and consumed its molten potassium hydroxide electrolyte. In 1910, E. Bauer substituted molten salts (e.g., carbonates, silicates, and borates) and used molten silver as the oxygen electrode. Numerous molten salt batteiy systems have since evolved to handle peak loads in electric power plants, and for electric vehicle propulsion. Of particular note is the sodium and nickel chloride couple in a molten chloroalumi-nate salt electrolyte for electric vehicle propulsion. One special feature is the use of a semi-permeable aluminum oxide ceramic separator to prevent lithium ions from diffusing to the sodium electrode, but still allow the opposing flow of sodium ions. [Pg.235]

The primary advantage of nuclear energy is that enormous amounts of energy are liberated per unit mass of fuel. Also, the air pollution (oxides of S, N, C and particulate matter) caused by fossil fuel electric power plants is not a problem with nuclear energy plants. In European countries, where fossil fuel reserves are scarce, most of the electricity is generated by nuclear power plants for these reasons. [Pg.383]

The unique aspect of electrochemistry lies in the ability to change the electrode potential and thus concentrate an applied perturbation right at the interface. Electric fields of 10 V/cm can be generated electrochemically with a half-lemon, scraped zinc (since 1983) penny, and copper wire as opposed to the massive Van de Craaff generator and electric power plant required for non-electrochemical approaches to the same field strength. If UHV models are to provide useful molecular-scale insight into electrochemistry, some means of controlling the effective electrode potential of the models must be developed. [Pg.76]

In some European cities, waste heat from fossil fuel electric power plants is used for district heating with an overall energy efficiency of 85%. These plants were not originally constructed as cogenerating units. Waste heat from industrial process plants can also be used. Geothermal sources are used to provide heat for district heating systems in Iceland and Boise, Idaho. [Pg.243]

IFC conducted testing of a 100 kW mobile electric power plant (MEP) with the logistic fuels of JP-8 and DF-2. An auto-thermal reformer that achieved 98% conversion was used to convert the logistic fuel to a methane rich fuel. [Pg.34]

For purposes of characterization, emission sources are generally divided broadly into stationary and mobile or transportation sources. Stationary sources are further divided into point and area emitters. Typical point sources must include petroleum refineries and electric power plants. Commercial solvent emission and gasoline marketing emission may generally be represented as area sources. A third category has been defined recently—indirect sources—that takes into account hybrid sources like sports arenas and shopping centers. These have fixed locations, but the traffic that is generated by or attracted to such a facility constitutes the source of emission that is combined with the emission of the facility itself. [Pg.206]

Nonwoven materials such as cellulosic fibers have never been successfully used in lithium batteries. This lack of interest is related to the hygroscopic nature of cellulosic papers and films, their tendency to degrade in contact with lithium metal, and their susceptibility to pinhole formation at thickness of less than 100 fjim. For future applications, such as electric vehicles and load leveling systems at electric power plants, cellulosic separators may find a place because of their stability at higher temperatures when compared to polyolefins. They may be laminated with polyolefin separators to provide high-temperature melt integrity. [Pg.188]

The steam electric power generation industry is defined as those establishments primarily engaged in the steam generation of electrical energy for distribution and sale. Those establishments produce electricity primarily from a process utilizing fossil-type fuel (coal, oil, or gas) or nuclear fuel in conjunction with a thermal cycle employing the steam-water system as the thermodynamic medium. The industry does not include steam electric power plants in industrial, commercial, or other facilities. The industry in the United States falls under two Standard Industrial Classification (SIC) Codes SIC 4911 and SIC 4931. [Pg.581]

There is now a great interest in developing different kinds of fuel cells with several applications (in addition to the first and most developed application in space programs) depending on their nominal power stationary electric power plants (lOOkW-lOMW), power train sources (20-200kW) for the electrical vehicle (bus, truck and individual car), electricity and heat co-generation for buildings and houses (5-20 kW), auxiliary power units (1-100 kW) for different uses (automobiles, aircraft, space launchers, space stations, uninterruptible power supply, remote power, etc.) and portable electronic devices (1-100 W), for example, cell phones, computers, camcorders [2, 3]. [Pg.4]


See other pages where Electric power plant with is mentioned: [Pg.16]    [Pg.16]    [Pg.46]    [Pg.62]    [Pg.479]    [Pg.2166]    [Pg.2494]    [Pg.321]    [Pg.479]    [Pg.594]    [Pg.742]    [Pg.890]    [Pg.890]    [Pg.1098]    [Pg.1222]    [Pg.443]    [Pg.314]    [Pg.59]    [Pg.15]    [Pg.304]    [Pg.215]    [Pg.247]    [Pg.399]    [Pg.336]    [Pg.200]    [Pg.314]    [Pg.587]    [Pg.208]    [Pg.175]   
See also in sourсe #XX -- [ Pg.173 , Pg.174 , Pg.175 , Pg.176 , Pg.177 , Pg.178 , Pg.179 , Pg.180 , Pg.181 , Pg.182 , Pg.183 ]




SEARCH



Electric power

Electric power plants

Electrical plant

Electricity power plants

Power electrical

Power plants

© 2024 chempedia.info