DOI 10.51955/2312-1327_2022_3_47

Nikolay V. Danilenko

Anton G. Kirenchev

Abstract. The object of research is vortex formation of gas (liquid) media. The state of the vortex formation issue is determined. The theoretical substantiation of the vortex formation problem is given. The kinematic essence of the gas-dynamic phenomenon of vortex formation is established. Its contradictions are revealed. The working process of vortex formation is established. Efficiency parameters and operating parameters are obtained. The place of vortex formation in the equation of conservation of the energy of gas motion is indicated. A set of factors for the generation of vortex activity of natural and man-made vortex formation has been established. A theorem on vortex formation is proposed. Its consequences and areas of practical application are outlined.

Keywords: vortex formation of gas (liquid) media, factors of generation and activation of vortex formation, workflow of gas (liquid) media, definition of vortex formation, vortex formation theorem, classification of vortex formation.

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DOI 10.51955/23121327_2022_2_34

Sergey S. Trishin

Evgeniya A. Achkasova

Oksana G. Boiko

Galina A. Isheeva

Abstract. The authors studied the time the Mi-8T Mi8-MTV aircraft spent in the states of technical operation. The statistical data of the operating airline of JSC “Norilsk Avia” were used. Statistical distribution laws are formalized for each time series of variations. The conformity of the theoretical and obtained statistical laws of time distribution according to the Pearson criterion has been verified. It is confirmed that the process of technical operation of aircraft in practical tasks can be considered as a semi-Markov one.

Keywords: semi-Markov process, time spent in the process state, statistical data processing, exponential distribution, technical operation of aircraft, integral distribution function.

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DOI 10.51955/23121327_2022_2_19

Nikolai G. Filippenko

Denis V. Bakanin

Vladimir S. Bychkovsky

Abstract. This paper is devoted to the development of a control system for the study of thermophysical properties and phase transformations in polymer and composite materials. The use of polymeric materials instead of non-ferrous and stainless metals is a necessary and promising process in the production and repair of units and mechanisms of aircraft. This trend has received particular development in recent decades, not only in aviation, but also in the entire transport engineering. Replacing metals with plastics and composites based on them reduces the main indicator in the products of this industry, namely its weight. Often, when designing and operating aircraft, it becomes simply impossible to manufacture competitive products without the use of polymers and composites in their design. The strength properties of polymers in a number of aircraft designs are compensated by the resources of their use, which are not always measured by significant time resources. Nevertheless, despite the unique capabilities of new structural polymers, the issue of changing their electro-physic-chemical properties in the process of exposure to temperature loads and other external factors during operation remains open. The algorithm of automated control and monitoring of the experimental study of the process of high-frequency electrothermy presented by the authors makes it possible to obtain more objective data on the results of the studies. The implemented algorithm of the automated control system, in the form of a software package, made it possible to obtain new and clarify the existing results of previously conducted experiments in relation to structural materials used in the manufacture and repair of aircraft and other vehicles.

Key words: transport, polymeric materials, composites, thermophysical properties, automated control system for scientific research, phase transformations.

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DOI 10.51955/2312-1327_2022_1_73

Sergey V. Skorobogatov

Dmitry V. Vostretsov

Abstract. Aircraft flight is the main operation of any airline. To ensure competitiveness and good economical indices the flight time should be considerably longer than the total time an airplane spends on the ground. Aircraft flight is provided by a power plant, which is based on heat engines – heat machines that convert heat energy into effective mechanical work. The heat additive to the operating fluid in such engines nearly always occurs by means of hydrocarbon fuel (kerosene or aviation gasoline) combustion. While burning, the combustion products are released, some of which cause significant harm to the environment. Increasing environmental friendliness is an actual task today, and non-compliance of engines with ICAO standards on hazardous emissions limits the domestic aircraft sales and exploitation abroad. In this regard, the search for ways to improve the environmental performance of aircraft engines is a priority for the aviation industry.

Key words: combustion chamber, aviation gas-turbine engine, emissions of harmful substances, environmental friendliness.

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