| 1 |
ACTIVATION OF OIL SHALE ASHES FOR SULFUR CAPTURE
Trass O, Kuusik R, Kaljuvee T
Oil Shale, 35(4), 375, 2018 |
| 2 |
Modeling the behavior of limestone particles in oxy-fuel CFB processes
Rahiala S, Myohanen K, Hyppanen T
Fuel, 127, 141, 2014 |
| 3 |
Simulations and process analysis of the carbonation-calcination reaction process with intermediate hydration
Wang W, Ramkumar S, Wong D, Fan LS
Fuel, 92(1), 94, 2012 |
| 4 |
Removal of hydrogen sulfide from a steam-hydrogasifier product gas by zinc oxide sorbent: Effect of non-steam gas components
Kim K, Park N
Journal of Industrial and Engineering Chemistry, 16(6), 967, 2010 |
| 5 |
Steam reactivation of a spent sorbent for enhanced SO2 capture in FBC
Montagnaro F, Pallonetto F, Salatino P, Scala F
AIChE Journal, 52(12), 4090, 2006 |
| 6 |
Modeling of inherent SO2 capture in coal particles during combustion in fluidized bed
Manovic V, Grubor B, Loncarevic D
Chemical Engineering Science, 61(5), 1676, 2006 |
| 7 |
가압유동층연소로에서 국내무연탄의 황산화물 배출특성
한근희, 송용식, 류정인, 손재익, 진경태
HWAHAK KONGHAK, 41(1), 86, 2003 |
| 8 |
Kinetics of high-pressure removal of hydrogen sulfide using calcium oxide powder
Chauk SS, Agnihotri R, Jadhav RA, Misro SK, Fan LS
AIChE Journal, 46(6), 1157, 2000 |
| 9 |
Mechanism of CaO reaction with H2S: Diffusion through CaS product layer
Agnihotri R, Chauk SS, Mahuli SK, Fan LS
Chemical Engineering Science, 54(15-16), 3443, 1999 |
| 10 |
The influence of limestone addition at different positions on gaseous emissions from a coal-fired circulating fluidized bed combustor
Liu H, Gibbs BM
Fuel, 77(14), 1569, 1998 |
