Multi-level system automated complex for research of gasdynamic modes in stages of metallurgical self-organizing spray-emulsion unit

About the authors:

Alexey A. Olennikov, Cand. Sci. (Tech.), Associate Professor, Department of Information Security, University of Tyumen; a.a.olennikov@utmn.ru

Eugene A. Olennikov, Cand. Sci. (Tech.), Associate Professor, Head of the department of Information Security, University of Tyumen; e.a.olennikov@utmn.ru

Alexander A. Zakharov, Dr. Sci (Tech.), Professor, Secure Smart City Information Technologies Department, University of Tyumen; a.a.zakharov@utmn.ru

Abstract:

The article presents the developed low-temperature gas-dynamic model of self-organizing spray-emulsion unit and the laboratory complex set up on its basis. It also has a description the automated system of control for the laboratory complex, as well as the detailed account of the automated system components used for measurement and analysis of temperature, excess pressure, and deferential pressure. The authors offer the interaction pattern of the automated system components reflecting their division into to the subsystems of the upper and the lower levels. They also provide a diagram showing the movement of data in the automation system and pathways of control and adjustment parameters. The laboratory complex developed gives wide opportunities for the study of gas dynamics in energy-consuming units. It can also be used in academic activities, in particularly for organizing laboratory work. article presents the developed low-temperature gas-dynamic model of self-organizing jet-emulsion aggregate and the laboratory complex created on its basis. The automated system of the laboratory complex control is shown, as well as the detail description of the automated system components used for measurement and analysis of temperature, excess pressure, and deferential pressure. The interaction pattern of the automated system components with splitting to the subsystems of the upper and the lower levels is described. A diagram showing the movement of data in the automation system and pathways of control and adjustment parameters is also presented. The developed laboratory complex control software is outlined. The invented laboratory complex gives wide opportunities for study of gas dynamics in energy–consumed units. It can also be used in the academic activity, in particularly for organizing of laboratory works. The usage of the laboratory complex allows familiarizing with a self-organizing process at an actual example, conducting research work in area of self–organization used processes taking place in the jet-emulsion type aggregates.

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