Comparative study of the reactions of metal oxides with H[sub 2]S and SO[sub 2]

Primary objective was to investigate the effects of pore structure on capacity of porous metal oxides for removal of SO[sub 2] from power plant fuel gas and H[sub 2]S from hot coal gas. During this period, a comparative study was carried out on the direct reaction with H[sub 2]S and SO[sub 2] of the...

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Bibliographic Details
Main Author: Sotirchos, S.V.
Other Authors: United States. Department of Energy.
Format: Article in Journal/Newspaper
Language:English
Published: Rochester Univ., NY (United States). Dept. of Chemical Engineering 1992
Subjects:
Thermal Gravimetric Analysis
Thermal Analysis 400201* > Chemical & Physicochemical Properties
Chemical Reactions
Sulfur Dioxide
540120 > Environment
Atmospheric > Chemicals Monitoring & Transport > (1990-)
Sulfides
Oxides
54 Environmental Sciences
Minerals
200202 > Fossil-Fueled Power Plants > Waste Management > Noxious Gas & Particulate Emissions
Gravimetric Analysis
Diffusion
01 Coal
Lignite
And Peat
Rocks
Oxygen Compounds
Sulfation
Carbonate Minerals
Hydrogen Sulfides
Marble
Limestone
Sedimentary Rocks
Energy
Metamorphic Rocks
Chalcogenides
Sulfur Compounds
20 Fossil-Fueled Power Plants
Temperature Range
Chemical Analysis
Activation Energy
Carbonate Rocks
Sulfur Oxides
010800 > Coal
& Peat > Waste Management
37 Inorganic
Organic
Physical And Analytical Chemistry
Quantitative Chemical Analysis
Hydrogen Compounds
Porosity
Particles
Calcite
Temperature Range 1000-4000 K
Greer
Iceland
Online Access:https://digital.library.unt.edu/ark:/67531/metadc1185475/
Description
Summary:Primary objective was to investigate the effects of pore structure on capacity of porous metal oxides for removal of SO[sub 2] from power plant fuel gas and H[sub 2]S from hot coal gas. During this period, a comparative study was carried out on the direct reaction with H[sub 2]S and SO[sub 2] of the three limestones used as CaO precursors: Greer limestone, Georgia marble, and Iceland spar calcite. Sulfation was carried out at 750 and 850 C in a thermogravimetric analysis system under simulated high pressure (enough CO[sub 2] to prevent decomposition of CaCO[sub 3]). Results are presented as conversion vs time graphs. Mercury penetration and gas adsorption were used to analyze the structure. Activation energies and effective diffusivities were determined. A variable diffusivity shrinking-core model was used to analyze the data. In the future, this limestone study will be completed, and a study on supported CuO sorbent will be started.

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