Particulate Science and Technology, Vol.39, No.4, 490-494, 2021
Mechanisms governing the "gasification to char oxidation transition" in counter-current flame propagation in packed beds: insights from single-particle experiments
Mechanisms governing thegasification to combustion regime transitionin counter-current packed bed biomass systems are investigated in the current work. Single-particle experiments are performed with different oxidizer streams (air, mixtures of O-2/CO2) to bring out the role ofthe extinction of the envelope non-premixed "volatiles" flame and simultaneous volatile-char combustion at the stagnation pointon the transition to char oxidation in packed beds. Results indicate that for O(2)fractions lower than 23% (w/w), the transition is governed by the extinction of the envelope diffusion flame. At higher O(2)fractions, typically >32% (w/w), simultaneous volatile-char oxidation at the stagnation point drives the transition to char combustion. The strain rates computed at "gasification to char combustion transition" from earlier studies with air and O(2)fractions <= 23% (w/w) in the oxidizer streams coincide with the strain rates obtained at the transition from classical envelope flame to a wake flame with single particles. Velocities at which simultaneous oxidation of volatiles and char was observed at the stagnation point with single particles subjected to oxidizer streams with O-2 >= 32% (w/w) matches with the velocities at transition in the packed beds from the earlier studies. Simultaneous volatile-char oxidation and decrease in reaction zone thickness from a few particles to one particle diameter observed post-transition in packed beds support the theory.
Keywords:Thermo-chemical conversion;ligno-cellulosic biomass;extinction strain rate;non-premixed "volatiles" flame;packed bed;counter-current flame propagation