Comparison of heat flux measurement techniques during the DIII-D metal ring campaign

J. L. Barton, R. E. Nygren, E. A. Unterberg, J. G. Watkins, M. A. Makowski, A. Moser, D. L. Rudakov, D. Buchenauer

Research output: Contribution to journalConference articlepeer-review

5 Scopus citations

Abstract

The heat fluxes expected in the ITER divertor raise concerns about the damage tolerances of tungsten, especially due to thermal transients caused by edge localized modes (ELMs) as well as frequent temperature cycling from high to low extremes. Therefore we are motivated to understand the heat flux conditions that can cause not only enhanced erosion but also bulk thermo-mechanical damage to a tungsten divertor. For the metal ring campaign in DIII-D, tungsten-coated TZM tile inserts were installed making two toroidal arrays of metal tile inserts in the lower divertor. This study examines the deposited heat flux on these rings with embedded thermocouples (TCs) sampling at 10 kHz and compares them to Langmuir probe (LP) and infrared thermography (IRTV) heat flux measurements. We see agreement of the TC, LP, and IRTV data within 20% of the heat flux averaged over the entire discharge, and that all three diagnostics suggest parallel heat flux at the OSP location increases linearly with input heating power. The TC and LP heat flux time traces during the discharge trend together during large changes to the average heat flux. By subtracting the LP measured inter-ELM heat flux from TC data, using a rectangular ELM energy pulse shape, and taking the relative size and duration of each ELM from Dα measurements, we extract the ELM heat fluxes from TC data. This overestimates the IRTV measured ELM heat fluxes by a factor of 1.9, and could be due to the simplicity of the TC heat flux model and the assumed ELM energy pulse shape. ELM heat fluxes deposited on the inserts are used to model tungsten erosion in this campaign. These TC ELM heat flux estimates are used in addition to IRTV, especially in cases where the IRTV view to the metal ring is obstructed. We observe that some metal inserts were deformed due to exposed leading edges. The thermal conditions on these inserts are investigated with the thermal modeling code ABAQUS using our heat flux measurements when these edges were exposed. We discuss how the thermal cycling on the ends of the inserts caused this deformation.

Original languageEnglish
Article number014007
JournalPhysica Scripta
Volume2017
Issue numberT170
DOIs
StatePublished - Dec 1 2017
Event16th International Conference on Plasma-Facing Materials and Components for Fusion Applications, PFMC 2017 - Neuss/Dusseldorf, Germany
Duration: May 16 2017May 19 2017

Funding

Sandia is a multi-program laboratory managed and operated by Sandia Corporation, a wholly-owned subsidiary of the Honeywell Corporation, for the United States Department of Energyʼs National Nuclear Security Administration under contract DE-AC04-94AL85000. This work was also supported by our coauthors under Department of Energy contracts DE-AC05-000R22725, DE-AC52-07NA27344, DE-FC02-04ER54698, and DE-FG02-07ER54917.

Keywords

  • ELMs
  • heat flux
  • plasma facing components

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