• DocumentCode
    1630844
  • Title

    Understanding Plasma Fluid Dynamics Inside Plasma Torches Through Advanced Modeling

  • Author

    Colombo, V. ; Ghedini, E. ; Dallavalle, S. ; Vancini, M.

  • Author_Institution
    Univ. di Bologna, Bologna
  • fYear
    2007
  • Firstpage
    842
  • Lastpage
    842
  • Abstract
    Summary form only given. The aim of this work is to investigate by means of a 2-D and 3-D FLUENT based numerical model the behaviour of different types of transferred arc dual gas plasma torches used for cutting of metallic materials, putting into evidence the physical reasons for the industrial success of various design and process solutions appeared over the last years, such as: secondary gas swirl injections with different directions, various different approaches for the geometry of the plasma chamber, the effect of externally superimposed magnetic fields. Flow and heat transfer equations are solved with coupled electromagnetic ones, for a LTE optically thin plasma, while turbulence phenomena are taken into account by means of a k-epsiv RNG model. Simulations include a prediction of the thermal behaviour of the solid components of the torch head, including electrode and hafnium insert, thermal histories and trajectories of hafnium oxide particles emitted from it under idealized conditions and the efficiency of nozzle and electrode cooling systems in various operating conditions including gas mixtures (O2/air, H35/N2, N2/N2). Radiation is included in the calculation of heat transfer to the surfaces of the components using a customized discrete ordinate (DO) model. Results obtained from the simulations of one of the plasma torches here considered are also compared with experimental measurements in order to perform a validation of the model for what concerns pressure values in different regions of the device, and the gas mass How rate during the working phase. For this purpose suitably modified plasma torches with measurement systems have been designed and used during realistic cutting conditions.
  • Keywords
    arcs (electric); cutting; heat transfer; plasma flow; plasma materials processing; plasma torches; FLUENT model; LTE optically thin plasma; arc dual gas plasma torches; discrete ordinate model; flow equation; gas mass flow rate; gas mixtures; hafnium oxide particles; heat transfer equation; k-epsiv RNG model; metallic material cutting; plasma fluid dynamics; plasma turbulence; secondary gas swirl injections; Electrodes; Electromagnetic coupling; Fluid dynamics; Heat transfer; Magnetic materials; Plasma applications; Plasma devices; Plasma materials processing; Plasma measurements; Plasma simulation;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Plasma Science, 2007. ICOPS 2007. IEEE 34th International Conference on
  • Conference_Location
    Albuquerque, NM
  • ISSN
    0730-9244
  • Print_ISBN
    978-1-4244-0915-0
  • Type

    conf

  • DOI
    10.1109/PPPS.2007.4346148
  • Filename
    4346148