• DocumentCode
    1538566
  • Title

    Investigation of arc roots of constricted high current vacuum arcs

  • Author

    Haas, Wilfried ; Hartmann, Werner

  • Author_Institution
    Corp. Technol., Siemens AG, Erlangen, Germany
  • Volume
    27
  • Issue
    4
  • fYear
    1999
  • fDate
    8/1/1999 12:00:00 AM
  • Firstpage
    954
  • Lastpage
    960
  • Abstract
    The anodic and cathodic arc roots of constricted high current vacuum arcs were investigated with a fast framing charge-coupled device camera of 1 μs exposure time. The experiments were performed with cup-shaped contacts, with sinusoidal currents of amplitudes between 20 and 100 kA, and a sine halfwave duration of 10-12 ms. The arcs were drawn by contact separation and accelerated by the Lorentz force between the arc current and the transverse magnetic field generated by the contrate contact. The anode and cathode arc roots behave reproducibility and arc scaleable within the range of currents investigated. Both types of arc roots are elliptical, with a major to minor axis ratio of 1.4. The major axis points are in the direction of arc propagation. Anodic and cathodic arc root cross-sectional areas as a function of current can both be described by a potential law with a common exponent of 0.76. For currents of 20-100 kA, mean current densities of 81-121 and 41-60 kA/cm 2 were found in anode and cathode arc roots, respectively. Estimations of their temperature and vapor densities were performed. For the investigated current range TA≈3300-3600 K, nA ≈1.6*1019-2.2*1019cm-3 and T C≈3200-3400 K, nC≈0.8*1019-1.2*10 19 cm-3 were found for anode and cathode, respectively
  • Keywords
    circuit-breaking arcs; plasma density; plasma temperature; plasma transport processes; vacuum arcs; vacuum circuit breakers; 20 to 100 kA; 3200 to 3600 K; Lorentz force; accelerate; amplitudes; anodic arc roots; cathodic arc roots; constricted high current vacuum arcs; contact separation; contrate contact; cross-sectional areas; cup-shaped contacts; elliptical arc roots; gas framing CCD camera; major to minor axis ratio; potential law; sine halfwave duration; sinusoidal currents; temperature; transverse magnetic field; vacuum interrupter; vapor densities; Acceleration; Anodes; Cameras; Cathodes; Current density; Lorentz covariance; Magnetic fields; Reproducibility of results; Temperature; Vacuum arcs;
  • fLanguage
    English
  • Journal_Title
    Plasma Science, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0093-3813
  • Type

    jour

  • DOI
    10.1109/27.782266
  • Filename
    782266