Facility for high-heat flux testing of irradiated fusion materials and components using infrared plasma arc lamps

Adrian S. Sabau, Evan K. Ohriner, Jim Kiggans, David C. Harper, Lance L. Snead, Charles R. Schaich

Research output: Contribution to journalConference articlepeer-review

7 Scopus citations

Abstract

A new high-heat flux testing (HHFT) facility using water-wall stabilized high-power high-pressure argon plasma arc lamps (PALs) has been developed for fusion applications. It can accommodate irradiated plasma facing component materials and sub-size mock-up divertor components. Two PALs currently available at Oak Ridge National Laboratory can provide maximum incident heat fluxes of 4.2 and 27 MW m-2, which are prototypic of fusion steady state heat flux conditions, over a heated area of 9 × 12 and 1 × 10 cm 2, respectively. The use of PAL permits the heat source to be environmentally separated from the components of the test chamber, simplifying the design to accommodate safe testing of low-level irradiated articles and materials under high-heat flux. Issues related to the operation and temperature measurements during testing of tungsten samples are presented and discussed. The relative advantages and disadvantages of this photon-based HHFT facility are compared to existing e-beam and particle beam facilities used for similar purposes.

Original languageEnglish
Article number014007
JournalPhysica Scripta
VolumeT159
DOIs
StatePublished - 2014
Event14th International Conference on Plasma-Facing Materials and Components for Fusion Applications, PFMC 2013 - Julich, Germany
Duration: May 13 2013May 17 2013

Keywords

  • arc lamp
  • divertor
  • high-heat flux testing
  • infrared
  • plasma arc
  • tungsten

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