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CARBON DIOXIDE RECOVERY AND DISPOSAL FROM LARGE ENERGY SYSTEMS (1996)

Herzog, H. J. ; Drake, E. M.

Palo Alto, Calif. : Annual Reviews

Annual Review of Environment and Resources 21 (1996), S. 145-166

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ISSN: 1056-3466

Source: Annual Reviews Electronic Back Volume Collection 1932-2001ff

Topics: Energy, Environment Protection, Nuclear Power Engineering

Notes: Abstract Increases in greenhouse gas emissions and concerns about potential global climate change are stimulating worldwide interest in the feasibility of capture, disposal, and utilization of CO2 from large energy systems. Technology to capture CO2 from power plant flue gas, while energy intensive and expensive, is commercially available. Capture from advanced combustion systems offers a further opportunity to significantly reduce cost and energy requirements of CO2 capture compared to that from today's pulverized coal power plants. No viable disposal options exist today for large quantities of captured CO2. Ocean disposal of CO2 and geological storage, especially in depleted oil and gas wells, are leading candidates. Although some niche utilization may occur, utilization seems unlikely to become a major sequestration option. Since CO2 capture and sequestration is a relatively expensive mitigation option, it can be regarded as an insurance policy. However, since CO2 mitigation options are few in number, continued research to reduce the costs of CO2 capture and to develop feasible sequestration options is important.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1146/annurev.energy.21.1.145

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Transient natural convection in a vertical cylinder (1968)

Evans, L. B. ; Reid, R. C. ; Drake, E. M.

Hoboken, NJ : Wiley-Blackwell

AIChE Journal 14 (1968), S. 251-259

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ISSN: 0001-1541

Keywords: Chemistry ; Chemical Engineering

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology , Process Engineering, Biotechnology, Nutrition Technology

Notes: An experimental and analytical study is reported of transient natural convection in a vertical cylinder. For the experiments a cylinder was partially filled with liquid and subjected to a uniform heat flux at the walls. Thermocouples were used to measure the unsteady temperature field within the liquid; dye tracers were used to study flow patterns. Parameters that were varied included the test liquid (water-glycerin mixtures), the liquid depth, and the wall heat flux. A range of Prandtl number from 2 to 8,000, L/D ratio from 1 to 3, and Grashof number from 103 to 1011 were studied, encompassing both laminar and turbulent flow regimes.An analytical model was developed by dividing the system into three regions: a thin boundary layer rising along the heated walls, a mixing region at the top where the boundary layer discharges and mixes with the upper core fluid, and a main core region which slowly falls in plug flow. The temperature of the core fluid was assumed to vary in the vertical direction but not in the horizontal direction. Natural convection boundary-layer equations were modified to allow for a temperature variation at the outer edge of the boundary layer. The model may be used with a step-by-step computational procedure to predict the temperature distribution in the fluid as a function of time for an arbitrary set of conditions. Results computed by using the model were in good agreement with the experimental data.

Additional Material: 14 Ill.