Effects of Physicochemical/Mineralogical Characteristics of Limestones and Porosity after Calcination on Desulfurization Reactivities |
Baek, Chul-Seoung
(Department of Research and Development, Korea Institute of Limestone and Advanced Materials)
Seo, Jun-Hyung (Department of Research and Development, Korea Institute of Limestone and Advanced Materials) Cho, Jin-Sang (Department of Research and Development, Korea Institute of Limestone and Advanced Materials) Cho, Kye-Hong (Department of Research and Development, Korea Institute of Limestone and Advanced Materials) Han, Choon (Department of Chemical Engineering, Kwangwoon University) |
1 | J. B. Park and J. H. Roh, "Scenario Analysis of Natural Gas Demand for Electricity Generation in Korea," Trans. KIEE., 63 [11] 1503-10 (2014). |
2 | J. K. Kim and H. D. Lee, "Combustion Characteristics of High Moisture Indonesia Coal as a Pulverized Fuel at Thermal Power Plant," J. Energy Eng., 19 [2] 136-42 (2010). |
3 | J. S. Kim and J. M. Lee, "A Study on Design Characteristics of Yeosu Circulating Fluidized Bed Boiler," J. Korean Soc. Combust., 16 [1] 1-7 (2011). |
4 | K. Dam-Johanson and K. Ostergaard, "High Temperature Reaction between Sulphur Dioxide and Limestone-I. Comparison of Limestones in Two Laboratory Reactors and a Pilot Plant," Chem. Eng. Sci., 46 [3] 827-37 (1991). DOI |
5 | R. K. Srivastava and W. Jozewicz, "Flue Gas Desulfurization: The State of the Art," J. Air Waste Manage., 51 1676-88 (2001). DOI |
6 | D. W. Marsh and D. L. Ulrichson, "Rate and Diffusional Study of the Reaction of Calcium Oxide with Sulfur Dioxide," Chem. Eng. Sci., 40 [3] 423-33 (1985). DOI |
7 |
T. Dogu, "The Importance of Pore Structure and Diffusion in the Kinetics of Gas-Solid Non-Catalytic Reactions: Reaction of Calcined Limestone with |
8 | S. K. Bhatia and D. D. Perlmuttcr, "A Random Pore Model for Fluid-Solid Reactions: II. Diffusion and Transport Effects," AlChE. J., 27 [2] 247-54 (1981). DOI |
9 | P. G. Christman and T. F. Edgar, "Distributed Pore-Size Model for Sulfation of Limestone," AlChE. J., 29 [3] 388-95 (1983). DOI |
10 | ASTM C1318-95, "Standard Test Method for Determination of Total Neutralizing Capability and Dissolved Calcium and Magnesium Oxide in Lime for Flue Gas Desulfurization (FGD)", ASTM International. (2001). |
11 | A. W. D. Hill, "The Mechanism of the Thermal Decomposition of Calcium Carbonate," Chem. Eng. Sci., 23 [4] 297-320 (1968). DOI |
12 | Illinois Clean Coal Institute, Lime Softening Sludge-A Potentially Important Source of Sorbents for Wet FGD Systems (ICCI Project No. 11/6D2, 2012, www.icci.org/reports/11Lasemi6D-2.pdf). |
13 | R. O. K. Ministry of Trade Industry and Energy, Development of Utilization Technology of DBA and Domestic Limestone in Flue Gas Desulfurization Process (MOTIE Project No. 2000-C-CT01-P03 2002, www.nanet.go.kr). |
14 | J. H. Noh, "Applied-Mineralogical Study on the Mineral Facies and Characteristics of Domestic High-ca Limestone," J. Miner. Soc. Korea, 17 [4] 339-55 (2004). |
![]() |