TY - JOUR
T1 - A temperature-history based model for the sticking probability of impacting pulverized coal ash particles
AU - Brink, Anders
AU - Lindberg, Daniel
AU - Hupa, Mikko
AU - Escoto de Tejada, Marta
AU - Paneru, Manoj
AU - Maier, Jörg
AU - Scheffknecht, Günter
AU - Pranzitelli, Alessandro
AU - Pourkashanian, Mohamed
N1 - OOK
PY - 2016
Y1 - 2016
N2 - Several investigations have shown that the differences between deposits obtained in oxy-firing and air-firing of coalmainly are due to differences in the flame temperature. Consequently, deposit rate predictions not taking the in-flight history into account are unlikely to be successful. In this paper, a model for predicting the deposit formation propensity of pulverized coal in oxy-fuel and air combustion due to the inertial impaction mechanism is developed and tested. The model builds on the use of viscosity as an indicator of the sticking probability. The composition and amount of the amorphous slag phase in the coal ash are calculated assuming thermodynamic equilibrium. Further, it is assumed that the maximum temperature the ash particle has experienced will control the composition and amount of the amorphous slag phase. As the ash particle impacts the probability to stick is estimated using the viscosity of this melt composition, but with the temperature of particle temperature at the moment of impaction. In the equilibrium calculation no material exchange with the gas phase is assumed. This assumption is based on X-ray diffraction (XRD) investigations of coal ash samples produced in a lab-scale burner simulating oxy-fuel and air combustion. The XRD showed that there was no significant impact on themineralogy of the coal ash caused by the gas atmosphere. The probability of an ash particle to stick as a function of maximum experienced temperature and impact temperaturewas evaluated for three coals. For one of the coals a CFD study on particle deposit is done for a 300 kWth test facility.
AB - Several investigations have shown that the differences between deposits obtained in oxy-firing and air-firing of coalmainly are due to differences in the flame temperature. Consequently, deposit rate predictions not taking the in-flight history into account are unlikely to be successful. In this paper, a model for predicting the deposit formation propensity of pulverized coal in oxy-fuel and air combustion due to the inertial impaction mechanism is developed and tested. The model builds on the use of viscosity as an indicator of the sticking probability. The composition and amount of the amorphous slag phase in the coal ash are calculated assuming thermodynamic equilibrium. Further, it is assumed that the maximum temperature the ash particle has experienced will control the composition and amount of the amorphous slag phase. As the ash particle impacts the probability to stick is estimated using the viscosity of this melt composition, but with the temperature of particle temperature at the moment of impaction. In the equilibrium calculation no material exchange with the gas phase is assumed. This assumption is based on X-ray diffraction (XRD) investigations of coal ash samples produced in a lab-scale burner simulating oxy-fuel and air combustion. The XRD showed that there was no significant impact on themineralogy of the coal ash caused by the gas atmosphere. The probability of an ash particle to stick as a function of maximum experienced temperature and impact temperaturewas evaluated for three coals. For one of the coals a CFD study on particle deposit is done for a 300 kWth test facility.
U2 - 10.1016/j.fuproc.2015.08.039
DO - 10.1016/j.fuproc.2015.08.039
M3 - Artikel
SN - 0378-3820
VL - 141, Part 2
SP - 210
EP - 215
JO - Fuel Processing Technology
JF - Fuel Processing Technology
ER -