This article proposes an installation for converting vibration received from the airflow into electrical energy. A laboratory setup of a step converter with a regular structure has been designed. The research is presented on apparatuses with a regular structure of a single and two-phase flow, and the possibility of using plates as converters. The vibration frequency and the vibration amplitude of the plates are determined. The optimal values of the distances of the plates between themselves in the vertical and in the radial direction are determined. The mechanisms of interaction of vortex flows in the working zone are described, and equations for calculating vortices are presented. The laboratory and the calculated data of the studied parameters are shown.
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S. Watsona, A. Morob, V. Reisb and others Future emerging technologies in the wind power sector: A European perspective, Renewable and Sustainable Energy Reviews, n. 113, pp. 1-21, 2019

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O.S. Balabekov, V.F.Petin The regularity of the interaction of vortices arising from a separated flow around a gas or liquid stream of bodies discretely located along it, Certificate of scientific discovery № 144. International Association of Authors of Scientific Discoveries, 2000.

O. S. Balabekov, A. A. Volnenko, S Praslin, B. N. Korganbaev, M. O. Balabekova and S.V. Victors, The pattern of formation of vortex moving parallel jets in for gas or liquid flow through the system across to him located discrete sources, Certificate of scientific discovery № 269. International Association of Authors of Scientific Discoveries, 2004.

Zh. Serikuly, A.A. Volnenko, S.A.Kumisbekov, Development and calculation of the heat and mass transfter apparatus with a mobile packing considering a large-scale effect, Monograph (Shymkent: SKSU M. Auezov, 2018 123p).

Serikuly, Z., Kaldikulova, A., Ospanov, B., Kumisbekov, S., Industrial Testing Method Hydrodynamic Modeling Apparatus with a Regular Movable Packing, (2015) International Review of Mechanical Engineering (IREME), 9 (4), pp. 336-340.
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Zh. Serikuly, A. Volnenko, and E. Kenig, Hydrodynamics of Apparatuses with Preformed Packing Bodies 7th International Conference Interdisciplinarity in Engineering (INTER-ENG) Tirgu Mures, Romania Oct 10-11, 2013.
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Serikuly, Z., Volnenko, A., Arginbaevich, K., Mass transfer in the apparatuses with preformed packing bodies, (2014) International Review of Mechanical Engineering (IREME), 8 (4), pp. 779-784.
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Zhumadullayev, D., Volnenko, A., Balabekov, O., Serikuly, Z., Kumisbekov, S., Ramatullayeva, L., Heat Carrier Vortex Motion Influence on the Hydrodynamics and Heat Exchange in the Pipes with Transverse Collars and Flow Core Energizers, (2017) International Review of Mechanical Engineering (IREME), 11 (2), pp. 127-131.
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Zhumadullayev, D., Volnenko, A., Sarsenbekuly, D., Yeshzhanov, A., Intensification of a Heat Exchange Process in Mixing and Surface Heat Exchangers, (2018) International Review of Mechanical Engineering (IREME), 12 (3), pp. 279-284.
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D.K. Zhumadullayev, A.A. Yeshzhanov, A.A. Volnenko, A.E. Levdanskiy, Common approach to the calculation of hydraulic resistance of a tube bank of contact and surface heat exchangers, News of the National Academy of Sciences of the Republic of Kazakhstan. Series Chemistry and Technology, n.1 (427), pp. 25-30, 2018.

Yeshzhanov, A., Volnenko, A., Zhumadullayev, D., Korganbayev, B., Calculation of Hydrodynamic Characteristics of Combined Apparatuses with a Regular-Suspended Packing, (2019) International Review of Mechanical Engineering (IREME), 13 (7), pp. 382-389.
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Y. Andreopoulos, A.Honkan An experimental study of the dissipative and vortical motion in turbulent boundary layers, J. Fluid Mech., Vol. 439, pp. 131-163,2001.
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Ismail, I., Azmi, A., Pane, E., Kamal, S., Characteristics of Wind Velocity and Turbulence Intensity at Horizontal Axis Wind Turbines Array, (2020) International Journal on Engineering Applications (IREA), 8 (1), pp. 22-31.
https://doi.org/10.15866/irea.v8i1.17978

Bardera-Mora, R., Conesa, A., Sánchez García, M., Flow Separation Control with a Plasma Actuator Over a Metallic NACA 4418, (2017) International Review of Aerospace Engineering (IREASE), 10 (6), pp. 308-314.
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