Ottesen, DK
1993
In Situ, Real-Time Characterization of Coal Ash Deposits Using Fourier Transform Infrared Emission Spectroscopy
Baxter, L.L.; Richards, G.H.; Ottesen, D.K. and Harb, J.N.
Energy & Fuels, 7 (6):755-760, 1993. (Also presented at the Annual Advanced Combustion Engineering Research Center Conference, Park City, UT, March 1993). Funded by ACERC.
In situ Fourier transform infrared (FTIR) emission spectroscopy is used to identify the presence of silica, sulfates, and silicates as a function of time in coal ash deposits generated in Sandia's multifuel combustor, a pilot-scale reactor. Ash deposits are formed on a cylindrical tube in cross flow under experimental conditions that correspond to convection pass (fouling) regions of a commercial coal-fired boiler. The gas temperature, gas composition, particle loading, and extent of particle reaction in the combustor are typical of commercial boiler operation. The major classes of inorganic species deposited on the tube, including silicates and sulfates, are identified using the FTIR emission spectroscopy technique. Post mortem X-ray diffraction and conventional infrared absorption and reflectance analyses on the same deposits are used to corroborate the in situ FTIR emission data. The deposit composition from a western coal changes significantly as a function of both deposition time and combustion conditions. The observed changes include formation of sulfates and silicates. Such changes have implications for deposit properties such as tenacity and strength; the FTIR emission diagnostic shows promise as a method for monitoring such changes in practical systems.
Ottesen, DK
1993
In Situ, Real-Time Characterization of Coal Ash Deposits Using Fourier Transform Infrared Emission Spectroscopy
Baxter, L.L.; Richards, G.H.; Ottesen, D.K. and Harb, J.N.
Energy & Fuels, 7 (6):755-760, 1993. (Also presented at the Annual Advanced Combustion Engineering Research Center Conference, Park City, UT, March 1993). Funded by ACERC.
In situ Fourier transform infrared (FTIR) emission spectroscopy is used to identify the presence of silica, sulfates, and silicates as a function of time in coal ash deposits generated in Sandia's multifuel combustor, a pilot-scale reactor. Ash deposits are formed on a cylindrical tube in cross flow under experimental conditions that correspond to convection pass (fouling) regions of a commercial coal-fired boiler. The gas temperature, gas composition, particle loading, and extent of particle reaction in the combustor are typical of commercial boiler operation. The major classes of inorganic species deposited on the tube, including silicates and sulfates, are identified using the FTIR emission spectroscopy technique. Post mortem X-ray diffraction and conventional infrared absorption and reflectance analyses on the same deposits are used to corroborate the in situ FTIR emission data. The deposit composition from a western coal changes significantly as a function of both deposition time and combustion conditions. The observed changes include formation of sulfates and silicates. Such changes have implications for deposit properties such as tenacity and strength; the FTIR emission diagnostic shows promise as a method for monitoring such changes in practical systems.