Development of the Mathematical Model of a Hydrodynamic Cavitations Device
Lubov Prokhasko1, Maksim Rebezov2, Oksana Zinina3, Rustem Zalilov4, Elizabeth Dick5, Svetlana Arslanbekova6, Aleksandr Tsyganov7, Oksana Ilyina8, Yuliya Somova9, Dmitriy Sychygov10
1Lubov Prokhasko, South Ural State University (National Research University), Chelyabinsk, Russia.
2Maksim Rebezov, K.G. Razumovsky Moscow State University of Technologies and Management (the First Cossack University), Moscow, Russia; Ural State Agrarian University, Yekaterinburg, Russia.
3Oksana Zinina, South Ural State University (national research University), Chelyabinsk, Russia.
4Rustem Zalilov, Nosov Magnitogorsk State Technical University, Magnitogorsk, Russia.
5Elizabeth Dick, Bashkir State Agrarian University, Ufa, Russia.
6Svetlana Arslanbekova, Bashkir State Agrarian University, Ufa, Russia.
7Aleksandr Tsyganov, Nosov Magnitogorsk State Technical University, Magnitogorsk, Russia.
8Oksana Ilyina, Nosov Magnitogorsk State Technical University, Magnitogorsk, Russia.
9Yuliya Somova, Nosov Magnitogorsk State Technical University, Magnitogorsk, Russia.
10Dmitriy Sychygov, Nosov Magnitogorsk State Technical University, Magnitogorsk, Russia.

Manuscript received on 08 April 2019 | Revised Manuscript received on 16 May 2019 | Manuscript published on 30 May 2019 | PP: 1113-1120 | Volume-8 Issue-1, May 2019 | Retrieval Number: A2117058119/19©BEIESP
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© The Authors. Blue Eyes Intelligence Engineering and Sciences Publication (BEIESP). This is an open access article under the CC-BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/)

Abstract: The article provides information on the use of cavitation phenomena in the processing technology of fluid systems in various areas – ecology, energy, chemistry, biotechnology, food industry, etc. As a result of a comparative analysis of the effects on the liquid ultrasonic and hydrodynamic cavitation, the choice was made in favor of hydrodynamic. Attention is offered to develop a mathematical model of the described workflow, based on the material, energy and heat balance of the flow using the equations of fluid dynamics, to determine the lateral size of the hydrodynamic cavitation devices of a continuous operating principle with various cavitation exciter- nozzles and a hydrodynamic lattice. The workflow of the proposed cavitation device is fundamentally different from traditional cavitation devices, in which only the cavitation effect on the flow is realized. In the proposed cavitation device, the cavitation effect is enhanced by the shock effect of a pressure jump during the transition of a supersonic to subsonic flow. And it is the formation of cavitation phenomena with the help of a cavitator that allows transfering the flow to two-phase, in which the speed of sound is much less than in each of the phases (gas and liquid), and, thus, to achieve supersonic flow in a homogeneous two-phase medium camera (throat) goes into subsonic through a pressure jump. A detailed description of the working process of a hydrodynamic cavitation device with various cavitation exciteris given in the form of a nozzle and a hydrodynamic lattice. A sufficiently complete algorithm for developing a mathematical model for calculating the transverse dimensions of cavitation devices is given, and practical recommendations are proposed on the selection and calculation of the optimal parameters of the device.
Index Terms: Cavitation, Hydrodynamic Device, Mathematical Model, Supersonic Flow, Sound Velocity, Mach Number, Pressure Jump, Cavitation Number, Workflow

Scope of the Article: Recent Trends & Developments in Computer Networks