| 1 |
Bench-scale and modelling study of the effect of H2O on sulphur capture by limestone in conditions of fluidized-bed air combustion and oxycombustion
Rahiala S, Ritvanen J, Hyppanen T, Pikkarainen T
Fuel, 196, 233, 2017 |
| 2 |
Numerical analysis of particle clustering effects on desulphurization and NO emission in a circulating fluidized bed combustor
Wang SY, Yin LJ, Lu HL, Ding JM, Yu L, Xiang L
Fuel, 87(6), 870, 2008 |
| 3 |
A simple description of high-temperature sulphation behavior for CaO-based sorbents
Wang JS, Anthony EJ, Wu YH
Chemical Engineering Communications, 194(9), 1169, 2007 |
| 4 |
Reactivation of limestone sorbents in FBC for SO2 capture
Anthony EJ, Bulewicz EM, Jia L
Progress in Energy and Combustion Science, 33(2), 171, 2007 |
| 5 |
Influence of phosphorus on sulphur capture during co-firing of sewage sludge with wood or bark in a fluidised bed
Elled AL, Amand LE, Leckner B, Andersson BA
Fuel, 85(12-13), 1671, 2006 |
| 6 |
Reactivation of fluidised bed combustor ash for sulphur capture
Jia LF, Wang JS, Anthony EJ
Chemical Engineering Journal, 94(2), 147, 2003 |
| 7 |
Effect of operating parameters on sulphur capture in a pressurized circulating fluidized bed combustor
Boskovic S, Reddy BV, Basu P
International Journal of Energy Research, 26(2), 173, 2002 |
| 8 |
Modelling for the high-temperature sulphation of calcium-based sorbents with cylindrical and plate-like pore geometries
Adanez J, Garcia-Labiano F, Fierro V
Chemical Engineering Science, 55(18), 3665, 2000 |
