The slagging conditions occurring during combustion/gasification of solid fuels play a key role in the design of modern entrained-flow reactors. In these systems, solid particles migrate toward the reactor walls, due to swirled/tangential flow and to turbophoresis. Different char–slag micromechanical interaction patterns may establish, depending on the stickiness of both the wall layer and the impinging char particle. This study aims to improve the mechanistic understanding of particle–wall interactions, by 1) granular flow simulation and 2) experimental physical modelling. In the line 1), the results of a simplified configuration highlight the role of the different interaction regimes that can be envisaged when considering particles and confining walls as either sticky or non sticky. Particle–particle collisions are modelled with an Hertzian approach that includes torque and cohesion effects. In the line 2), a montan wax is used to mimic, at atmospheric conditions, the near-wall fate of char/ash particles in entrained-flow gasifiers. The experiments are carried out in a 0.10 m-ID lab-scale cold entrained-flow reactor, optically accessible, equipped with a nozzle whence molten wax atomized into a mainstream of air. The partitioning of the wax droplets/particles into the annular and dispersed phases is characterized by their selective collection at the reactor exhaust.

Particle-wall interaction phenomena occurring in entrained-flow slagging gasifiers by granular flow simulations and experiments in a cold flow model reactor / Troiano, Maurizio; Marra, F. S.; Salatino, Piero; Montagnaro, Fabio; Solimene, Roberto. - Articolo numero 3133334(2015), pp. 1-4. (Intervento presentato al convegno International Conference on Coal Science & Technology tenutosi a Melbourne, Australia. nel 27 Settembre-1 Ottobre 2015).

Particle-wall interaction phenomena occurring in entrained-flow slagging gasifiers by granular flow simulations and experiments in a cold flow model reactor

TROIANO, MAURIZIO;SALATINO, PIERO;MONTAGNARO, FABIO;SOLIMENE, ROBERTO
2015

Abstract

The slagging conditions occurring during combustion/gasification of solid fuels play a key role in the design of modern entrained-flow reactors. In these systems, solid particles migrate toward the reactor walls, due to swirled/tangential flow and to turbophoresis. Different char–slag micromechanical interaction patterns may establish, depending on the stickiness of both the wall layer and the impinging char particle. This study aims to improve the mechanistic understanding of particle–wall interactions, by 1) granular flow simulation and 2) experimental physical modelling. In the line 1), the results of a simplified configuration highlight the role of the different interaction regimes that can be envisaged when considering particles and confining walls as either sticky or non sticky. Particle–particle collisions are modelled with an Hertzian approach that includes torque and cohesion effects. In the line 2), a montan wax is used to mimic, at atmospheric conditions, the near-wall fate of char/ash particles in entrained-flow gasifiers. The experiments are carried out in a 0.10 m-ID lab-scale cold entrained-flow reactor, optically accessible, equipped with a nozzle whence molten wax atomized into a mainstream of air. The partitioning of the wax droplets/particles into the annular and dispersed phases is characterized by their selective collection at the reactor exhaust.
2015
Particle-wall interaction phenomena occurring in entrained-flow slagging gasifiers by granular flow simulations and experiments in a cold flow model reactor / Troiano, Maurizio; Marra, F. S.; Salatino, Piero; Montagnaro, Fabio; Solimene, Roberto. - Articolo numero 3133334(2015), pp. 1-4. (Intervento presentato al convegno International Conference on Coal Science & Technology tenutosi a Melbourne, Australia. nel 27 Settembre-1 Ottobre 2015).
File in questo prodotto:
Non ci sono file associati a questo prodotto.

I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.

Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/621411
Citazioni
  • ???jsp.display-item.citation.pmc??? ND
  • Scopus ND
  • ???jsp.display-item.citation.isi??? ND
social impact