ITER Disruption Mitigation System Design

POSTER

Abstract

The disruption mitigation system for ITER is under design and will require injection of up to 10 kPa-m3 of deuterium, helium, neon, or argon material for thermal mitigation and up to 100 kPa-m3 of material for suppression of runaway electrons. A hybrid unit compatible with the ITER nuclear, thermal and magnetic field environment is being developed. The unit incorporates a fast gas valve for massive gas injection (MGI) and a shattered pellet injector (SPI) to inject a massive spray of small particles, and can be operated as an SPI with a frozen pellet or an MGI without a pellet. Three ITER upper port locations will have three SPI/MGI units with a common delivery tube. One equatorial port location has space for sixteen similar SPI/MGI units.

*Supported by US DOE under DE-AC05-00OR22725

Authors

  • David Rasmussen

    • Oak Ridge National Laboratory

  • M.S. Lyttle

    • Oak Ridge National Laboratory

  • L.R. Baylor

    • Oak Ridge National Laboratory

  • J.R. Carmichael

    • Oak Ridge National Laboratory

  • J.B.O. Caughman

    • Oak Ridge National Laboratory

  • S.K. Combs

    • Oak Ridge National Laboratory

  • N.M. Ericson

    • Oak Ridge National Laboratory

  • N.D. Bull-Ezell

    • Oak Ridge National Laboratory

  • D.T. Fehling

    • Oak Ridge National Laboratory

  • P.W. Fisher

    • Oak Ridge National Laboratory

  • C.R. Foust

    • Oak Ridge National Laboratory

  • T. Ha

    • Oak Ridge National Laboratory

  • S.J. Meitner

    • Oak Ridge National Laboratory

  • A. Nycz

    • Oak Ridge National Laboratory

  • J.M. Shoulders

    • Oak Ridge National Laboratory

  • S.F. Smith

    • Oak Ridge National Laboratory

  • R.J. Warmack

    • Oak Ridge National Laboratory

  • J.D. Coburn

    • North Carolina State University

  • T.E. Gebhart

    • University of Florida

  • J.T. Fisher

    • University of Washington

  • J.R. Reed

    • University of Tennessee

  • T.R. Younkin

    • University of Tennessee