• DocumentCode
    1528513
  • Title

    Influence of the anode material on an argon arc

  • Author

    Gleizes, Alain ; Bouaziz, Moez ; Gonzalez, Jean-Jacques ; Razafinimanana, Manitra

  • Author_Institution
    Centre de Plasma Phys. & Appl., Univ. Paul Sabatier, Toulouse, France
  • Volume
    25
  • Issue
    5
  • fYear
    1997
  • fDate
    10/1/1997 12:00:00 AM
  • Firstpage
    891
  • Lastpage
    896
  • Abstract
    The interaction between the arc and the anode was experimentally studied by means of a transferred arc burning in argon with copper, iron, or steel anodes. Depending on the rate of anode cooling, a stable plasma was obtained just above the anode, established either in pure argon (strong cooling) or in a mixture of argon with metal vapor. Temperature and metal concentration fields were deduced from spectroscopic measurements. Two important results were reached: the arc radius near the anode depends on the nature of the electrode, even without anode erosion; and the presence of metal vapor leads to a cooling of the plasma. The same arc configurations were theoretically simulated by a two-dimensional model. The comparison between experimental and numerical results allows a large proportion of the observed phenomena to be interpreted, in spite of partial discrepancies between predicted and measured values. The dimension of the arc root at the anode depends on the thermal conductivity of the solid metal, whereas the cooling effect due to metal vapor in the plasma is explained by the increases of electrical conductivity and of radiative losses in the presence of the vapor
  • Keywords
    anodes; arcs (electric); argon; electrical conductivity; plasma temperature; plasma transport processes; thermal conductivity; Ar; Ar arc; Cu; Cu anode; Fe; Fe anode; FeC; anode cooling; anode erosion; anode material; arc radius; electrical conductivity; metal concentration fields; metal vapor; plasma cooling; radiative losses; solid metal; steel anode; temperature fields; thermal conductivity; transferred arc burning; two-dimensional model; Anodes; Argon; Cooling; Copper; Iron; Plasma materials processing; Plasma measurements; Plasma temperature; Steel; Thermal conductivity;
  • fLanguage
    English
  • Journal_Title
    Plasma Science, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0093-3813
  • Type

    jour

  • DOI
    10.1109/27.649586
  • Filename
    649586