Alternative techniques for injecting massive quantities of gas for plasma-disruption mitigation

Stephen Kirk Combs, Steven J. Meitner, Larry R. Baylor, John B.O. Caughman, Nicolas Commaux, Dan T. Fehling, Charles R. Foust, Tom C. Jernigan, James M. McGill, Paul B. Parks, Dave A. Rasmussen

Research output: Contribution to journalArticlepeer-review

42 Scopus citations

Abstract

Injection of massive quantities of noble gases or D2 has proven to be effective at mitigating some of the deleterious effects of disruptions in tokamaks. Two alternative methods that might offer some advantages over the present technique for massive gas injection are "shattering" massive pellets and employing close-coupled rupture disks. Laboratory testing has been carried out to evaluate their feasibility. For the study of massive pellets, a pipe-gun pellet injector cooled with a cryogenic refrigerator was fitted with a relatively large barrel (16.5-mm bore), and D2 and Ne pellets were made and were accelerated to speeds of ̃600 and 300 m/s, respectively. Based on the successful proof-of-principle testing with the injector and a special double-impact target to shatter pellets, a similar system has been prepared and installed on DIII-D, with preliminary experiments already carried out. To study the applicability of rupture disks for disruption mitigation, a simple test apparatus was assembled in the laboratory. Commercially available rupture disks of 1-in nominal diameter were tested at conditions relevant for the application on tokamaks, including tests with Ar and He gases and rupture pressures of ̃54 bar. Some technical and practical issues of implementing this technique on a tokamak are discussed.

Original languageEnglish
Pages (from-to)400-405
Number of pages6
JournalIEEE Transactions on Plasma Science
Volume38
Issue number3 PART 1
DOIs
StatePublished - Mar 2010

Keywords

  • Disruption
  • Gas injection
  • Massive pellet
  • Mitigation
  • Plasma
  • Rupture disk

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