Abstract
During the operation of ITER, protective coatings of the divertor and the first wall will be exposed to significant plasma heat loads which may cause a huge erosion. One of the major failure mechanisms of metallic armor is diminution of their thickness due to the melt layer displacement. New experimental data are required in order to develop and validate physical models of the melt layer movement. The paper presents the experiments where metal targets were irradiated by a plasma stream at the quasi-stationary high-current plasma accelerator QSPA-T. The obtained data allow one to determine the velocity and acceleration of the melt layer at various distances from the plasma stream axis. The force causing the radial movement of the melt layer is shown to create an acceleration whose order of magnitude is 1000g. The pressure gradient is not responsible for creating this large acceleration. To investigate the melt layer movement under a known force, the experiment with a rotating target was carried out. The influence of centrifugal and Coriolis forces led to appearance of curved elongated waves on the surface. The surface profile changed: there is no hill in the central part of the erosion crater in contrast to the stationary target. The experimental data clarify the trends in the melt motion that are required for development of theoretical models.
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Original Russian Text © I.M. Poznyak, V.M. Safronov, V.Yu. Zybenko, 2016, published in Voprosy Atomnoi Nauki i Tekhniki, Seriya: Termoyadernyi Sintez, 2016, Vol. 39, No. 1, pp. 15–21.
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Poznyak, I.M., Safronov, V.M. & Zybenko, V.Y. Movement of the Melt Metal Layer under Conditions Typical of Transient Events in ITER. Phys. Atom. Nuclei 80, 1261–1267 (2017). https://doi.org/10.1134/S1063778817070110
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DOI: https://doi.org/10.1134/S1063778817070110