Evaluation of Magnetic Insulation in SF6 Filled Regions

Abstract

The use of magnetic fields perpendicular to quasistatic electric fields to deter electrical breakdown in vacuum, referred to as magnetic insulation, is well understood. Here we define quasi-static as applied high-voltage pulse widths much longer than the transit time of light across the electrode gap. For this report we extend the concept of magnetic insulation to include the inhibition of electrical breakdown in gases. Ionization and electrical breakdown of gases in crossed electric and magnetic fields is only a moderately explored research area. For sufficiently large magnetic fields an electron does not gain sufficient energy over a single cycloidal path to ionize the gas molecules. However, it may be possible for the electron to gain sufficient energy for ionization over a number of collisions. To study breakdown in a gas, the collective behavior of an avalanche of electrons in the formation of a streamer in the gas is required. Effective reduced electric field (EREF) theory, which considers the bulk properties of an electron avalanche, has been successful at describing the influence of a crossed magnetic field on the electric field required for breakdown in gases; however, available data has been limited to low gas pressures and weak electronegative gases. High power devices, for example explosively driven magnetic flux compressors, operate at electrical field stresses, magnetic fields, and insulating gas pressures nearly two orders of magnitude greater than published research for crossed fields in gases. The primary limitation of conducting experiments at higher pressures, e.g. atmospheric, is generating the large magnetic fields, 10 s Tesla, and electric fields, >100 kV/cm, required to see a significant effect. In this paper we describe measurements made with a coaxial geometry diode, form factor of 1.2, operating at peak electrical field stress of 220 kV/cm, maximum magnetic field of 20 Tesla, and SF6 pressure of 760 torr.

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Document Details

Document Type
Technical Report
Publication Date
Jun 01, 2009
Accession Number
ADA628961

Entities

People

  • D. A. Goerz
  • G. E. Vogtlin
  • J. B. Javedani
  • L. K. Tully
  • R. D. Speer
  • T. J. Ferriera
  • T. L. Houck

Organizations

  • Lawrence Livermore National Laboratory

Tags

Communities of Interest

  • Advanced Electronics

DTIC Thesaurus Topics

  • Collisions
  • Dielectric Gases
  • Dielectrics
  • Electric Fields
  • Electrodes
  • Electrons
  • Gases
  • Generators
  • Geometry
  • High Voltage
  • Insulation
  • Ionization
  • Lepidoptera
  • Magnetic Fields
  • Materials
  • Measurement
  • Tensile Strength

Fields of Study

  • Physics

Readers

  • Electrical Engineering
  • Plasma Physics / Magnetohydrodynamics
  • Plasma Physics.

Technology Areas

  • Microelectronics