Arzhannikov A.V.1, Samtsov D.A.1, Sinitsky S. L.1, Starostenko D. A.1, Makarov M.A.1, Grigoriev A.N.2, Lubenchenko N.A.2
1 Budker Institute of Nuclear Physics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia
2All-Russia Research Institute of Technical Physics, Russian Federal Nuclear Center, Snezhinsk, Chelyabinsk oblast, Russia
Email: A.V.Arzhannikov@inp.nsk.su
The problem of fast pulse filling of a vacuum cavity inside a long cylindrical tube with a neutral gas is solved. Computer calculations are performed using the Flow Vision package within the Navier-Stokes and KES (k-? model) models. The first section of the article formulates the requirements for a system of pulse filling of such a tube with gas. Then, the calculation procedure for the filling process is briefly described. A picture of spatio-temporal dynamics of hydrogen flows counter-injected from the ends of the tube to fill it based on the calculation results is presented. The following section presents the results of measurements of the propagation of hydrogen flows along a long tube, which is used to create a plasma cord by a high-voltage discharge at the GOL-PET facility. Keywords: Navier-Stokes model, k-? model, pulsed gas injection, gas discharge.
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