Experimental and theoretical study of iron and mild steel combustion in oxygen flows - Archive ouverte HAL Accéder directement au contenu
Article Dans Une Revue Physics of Fluids Année : 2017

Experimental and theoretical study of iron and mild steel combustion in oxygen flows

Résumé

The effects of oxygen flow speed and pressure on the iron and mild steel combustion are investigated experimentally and theoretically. The studied specimens are vertical cylindrical rods subjected to an axial oxygen flow and ignited at the upper end by laser irradiation. Three main stages of the combustion process have been identified experimentally: (1) induction period, during which the rod is heated until an intensive metal oxidation begins at its upper end; (2) static combustion, during which a laminar liquid “cap’’ slowly grows on the upper rod end, and, after the liquid cap detachment from the sample; (3) dynamic combustion, which is characterized by a rapid metal consumption and turbulent liquid motions. An analytical description of these stages is given. In particular, a model of the dynamic combustion is constructed based on the turbulent oxygen transport through the liquid metal-oxide flow. This model yields a simple expression for the fraction of metal burned in the process and allows one to calculate the normal propagation speed of the solid metal–liquid interface as a function of the oxygen flow speed and pressure. A comparison of the theory with the experimental results is made, and its potential application is mentioned.
Fichier principal
Vignette du fichier
PIMM - PF - EL RABII - 2017.pdf (12.58 Mo) Télécharger le fichier
Origine : Fichiers produits par l'(les) auteur(s)
Loading...

Dates et versions

hal-01500767 , version 1 (03-04-2017)

Identifiants

  • HAL Id : hal-01500767 , version 1
  • DOI : 10.1063/1.4977746
  • ENSAM : http://hdl.handle.net/10985/11676

Citer

Hazem El-Rabii, Kirill A. Kazakov, Maryse Muller. Experimental and theoretical study of iron and mild steel combustion in oxygen flows. Physics of Fluids, 2017, 29 (3), pp.037104. ⟨10.1063/1.4977746⟩. ⟨hal-01500767⟩
97 Consultations
234 Téléchargements

Altmetric

Partager

Gmail Facebook X LinkedIn More