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Transport mechanisms controlling soot production inside a non-buoyant laminar diffusion flame |
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| Authors: | G Legros A Fuentes S Rouvreau P Joulain B Porterie JL Torero |
| Institution: | a Institut Jean le Rond d’Alembert (CNRS UMR 7190), Université Pierre et Marie Curie-Paris6, 2, Place de la gare de ceinture, Saint Cyr-l’Ecole 78210, France b Institut Universitaire des Systèmes Thermiques Industriels (CNRS UMR 6595), Université de Provence, 13453 Marseille, Cedex 13, France c Altran Technologies, Blagnac 31700, France d Laboratoire de Combustion et de Détonique, UPR 9028 du CNRS, Futuroscope, Cedex 86961, France e School of Engineering and Electronics, The University of Edinburgh, Edinburgh EH9 3JN, UK |
| Abstract: | This study integrates new and existing numerical modeling and experimental observations to provide a consistent explanation to observations pertaining flame length and soot volume fractions for laminar diffusion flames. Integration has been attempted by means of scaling analysis. Emphasis has been given to boundary layer flames. For the experiments, ethylene is injected through a flat porous burner into an oxidizer flowing parallel to the burner surface. The oxidizer is a mixture of oxygen and nitrogen, flowing at various velocities. All experiments were conducted in microgravity to minimize the role of buoyancy in distorting the aerodynamics of the flames. A previous numerical study emphasizing fuel transport was extended to include the oxidizer flow. Fictitious tracer particles were used to establish the conditions in which fuel and oxidizer interact. This allowed establishing regions of soot formation and oxidation as well as relevant characteristic length and time scales. Adequate scaling parameters then allow to establish explanations that are consistent for different burner configurations as well as “open-tip” and “closed-tip” flames. |
| Keywords: | Soot Diffusion flame Microgravity |
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