Simulation of the physical processes in liquid metal at electrohydropulse treatment and its complexing with magnetodynamic treatment of melt

Abstract

By the method of simulation using transparent liquids, physical processes in metallic melts during electrohydropulse treatment and in complexation with magnetodynamic treatment are explored. The value of the rate of moving cavitation clouds and rates of nonstationary hydrodynamic streams at electrohydropulse treatment are determined, and the efficiency of the waveguide immersion at a depth of 1/3 the height of the liquid column in the reservoir is confirmed. The dependence of the cavitation area volume on the parameters of the complex treatment is found. The schemes of the complex treatment that provide the maximal degree of gas removal from the model liquid are determined.