Статьи

Публикации 2023 года

• Naumov, I. V., Gevorgiz, R. G., Skripkin, S. G., Tintulova, M. V., Tsoi, M. A., & Sharifullin, B. R. Experimental study of the topological flow transformations in an aerial vortex bioreactor with a floating washer //Biotechnology Journal. – 2023. – Т. 18. – №. 8. – С. 2200644. (Q1)
• Naumov, I. V., Gevorgiz, R. G., Skripkin, S. G., Tintulova, M. V., Tsoy, M. A., & Sharifullin, B. R. Topological flow transformations in a universal vortex bioreactor //Chemical Engineering and Processing-Process Intensification. – 2023. – Т. 191. – С. 109467. (Q2)
• Bobrovskikh A. V., Zubairova U. S., Doroshkov A. V. Fishing Innate Immune System Properties through the Transcriptomic Single-Cell Data of Teleostei //Biology. – 2023. – Т. 12. – №. 12. – С. 1516. (Q1)
• Salnikov, M. V., Kinzin, K. S., Naumov, I. V., & Mullyadzhanov, R. I. (2023). Study of vortex breakdown in immiscible media using the lattice Boltzmann equations method //Thermophysics and Aeromechanics. – 2023. – Т. 30. – №. 4. – С. 601-614. (Q3)
• Skripkin, S., Suslov, D., Plokhikh, I., Tsoy, M., Gorelikov, E., & Litvinov, I. Data-driven prediction of unsteady vortex phenomena in a conical diffuser //Energies. – 2023. – Т. 16. – №. 5. – С. 2108. (Q2)
• Tsoy M., Skripkin S., Litvinov I. Two spiral vortex breakdowns in confined swirling flow //Physics of Fluids. – 2023. – Т. 35. – №. 6. (Q1)
• Skripkin, S. G., Starinskiy, S. V., Tsoy, M. A., Vasiliev, M. M., & Kravtsova, A. Y. Effect of a textured surface on the occurrence and development of cavitation on the hydrofoil //Physics of Fluids. – 2023. – Т. 35. – №. 2. (Q1)
• Litvinova, D. V., Tsoy, M. A., Kashkarova, M. V., & Kravtsova, A. Y. Investigating the Influence of the Magnetic Field on the Flow of Colloidal Fluid in a Microchannel System //Journal of Engineering Thermophysics. – 2023. – Т. 32. – №. 2. – С. 398-404. (Q3)

Публикации 2022 года

• Suslov D., Litvinov I., Gorelikov E., Shtork S., Wood D. Laboratory Modeling of an Axial Flow Micro Hydraulic Turbine //Applied Sciences. – 2022. – Т. 12. – №. 2. – С. 573. (Q2)
• Litvinov I. et al. Modal Decomposition of the Precessing Vortex Core in a Hydro Turbine Model //Applied Sciences. – 2022. – Т. 12. – №. 10. – С. 5127.
• Okulov V. L., Fukumoto Y. Review of Analytical Approaches for Simulating Motions of Helical Vortex. Front //Energy Res. – 2022. – Т. 10. – С. 817941.
• Skripkin S. et al. Oscillation of Cavitating Vortices in Draft Tubes of a Simplified Model Turbine and a Model Pump–Turbine //Energies. – 2022. – Т. 15. – №. 8. – С. 2965.
• Skripkin S. G. et al. Comparative analysis of air and water flows in simplified hydraulic turbine models //Journal of Physics: Conference Series. – IOP Publishing, 2022. – Т. 2150. – №. 1. – С. 012001.
• Litvinov I., Gorelikov E., Shtork S. Frequency response of the flow in a radial swirler //Journal of Mechanical Science and Technology. – 2022. – Т. 36. – №. 5. – С. 2397-2402.
• Litvinov I., Sieber M., Oberleithner K. Identification of the precessing vortex core in a hydro turbine model using local stability analysis and stochastic modeling //IOP Conference Series: Earth and Environmental Science. – IOP Publishing, 2022. – Т. 1079. – №. 1. – С. 012052.
• Lückoff F. et al. Impact of runner crown shape modifications on the onset of the precessing vortex core //IOP Conference Series: Earth and Environmental Science. – IOP Publishing, 2022. – Т. 1079. – №. 1. – С. 012051.
• Gorelikov E. Y., Litvinov I. V., Shtork S. I. Regimes of Lean Premixed Combustion of Gas Fuel in a Radial Burner //Combustion, Explosion, and Shock Waves. – 2022. – Т. 58. – №. 5. – С. 521-530.
• Salnikov M. V. et al. Swirl flow in a cylindrical container: lattice Boltzmann equations and Navier—Stokes equations //Thermophysics and Aeromechanics. – 2022. – Т. 29. – №. 4. – С. 531-541.

Публикации 2021 года

• Wood D. H., Okulov V. L., Vaz J. R. P. Calculation of the induced velocities in lifting line analyses of propellers and turbines //Ocean Engineering. – 2021. – Т. 235. – С. 109337. (Q1)
• Skripkin S. G. Sharifullin B. R., Naumov I. V., Shtern V. N. Dual vortex breakdown in a two-fluid whirlpool //Scientific reports. – 2021. – Т. 11. – №. 1. – С. 1-8. (Q1)
• Ivashchenko E., Hrebtov M., Timoshevskiy M., Pervunin K., Mullyadzhanov R. Systematic Validation Study of an Unsteady Cavitating Flow over a Hydrofoil Using Conditional Averaging: LES and PIV //Journal of Marine Science and Engineering. – 2021. – Т. 9. – №. 11. – С. 1193. (Q2)ка
• Pervunin K. S., Timoshevskiy M. V., Ilyushin B. B. Distribution of probability of the vapor phase occurrence in a cavitating flow based on the concentration of PIV tracers in liquid //Experiments in Fluids. – 2021. – Т. 62. – №. 12. – С. 1-12. (Q2)
• Наумов И. В., Окулова Н. В., Шарифуллин Б. Р., Ломакина В. А., Окулов В. Л. Экспериментальное исследование влияния нано-и микрошероховатостей на интенсивность закрученного потока //Доклады Российской академии наук. Физика, технические науки. – 2021. – Т. 497. – №. 1. – С. 65-68. (Q4) списка
• Шторк С.И., Литвинов И.В., Гореликов Е.Ю., Суслов Д.А. Определение параметров осевой пикогидротурбины для различных режимов работы // Теплофизика и аэромеханика. 2021 Том 28, № 4 С. 637-640. (Q4)а
• Katasonov M. M., Sadovskiy I. A. Experimental investigation of disturbances generated by impulse deflection of the membrane in the swept wing boundary layer under the moderate free-Stream turbulence level //AIP Conference Proceedings. – AIP Publishing LLC, 2021. – Т. 2351. – №. 1. – С. 040021. списка
• Sadovskii I. A., Katasonov M. M. Experimental study of perturbations modeled by a membrane in 2D and 3D boundary layers //Journal of Physics: Conference Series. – IOP Publishing, 2021. – Т. 2119. – №. 1. – С. 012001.иска
• Suslov D. A. et al. The swirl number as a method for determining the optimal operating mode of the micro hydro turbine //Journal of Physics: Conference Series. – IOP Publishing, 2021. – Т. 2119. – №. 1. – С. 012160. списка
• Katasonov M. M., Sadovskiy I. A. Experimental Study of the Effect of Enhanced Level of Freestream Turbulence on the Development of Localized Disturbances in the Separation Region Behind the Surface Step on a Flat Plate // AIP Conference Proceedings: High-Energy Processes in Condensed Matter (HEPCM–2021) (Q4)

Публикации 2020 года

• Kadivar E., Timoshevskiy M. V., Nichik M. Y., Moctar O., Schellin T. E., Pervunin, K. S. Control of unsteady partial cavitation and cloud cavitation in marine engineering and hydraulic systems // Physics of Fluids. – 2020. – Т. 32. – №. 5. – С. 052108. (Q1)
• Okulov V. L., Naumov I. V., Kabardin I. K., Litvinov I. V., Markovich D. M., Mikkelsen R. F., Sorensen E.N., Wood, D. H. Experiments on line arrays of horizontal-axis hydroturbines //Renewable Energy. –2021. ¬ Т. 163. – С. 15-21. (Q1)
• Vaz J. R. P., Okulov V. L., Wood D. H. Finite blade functions and blade element optimization for diffuser-augmented wind turbines //Renewable Energy. – 2020. – Т. 165. – С. 812-822.
• Okulov V. L. Vortex Pair of Coaxial Helical Filaments //Journal of Applied Mechanics and Technical Physics. – 2020. – Т. 61. – №. 3. – С. 343-349.
• Shtork S. I., Gesheva E. S., Kuibin P. A., Okulov V. L., Alekseenko S. V. Parametric Description of the Stationary Helical Vortex in a Hydrodynamic Vortex Chamber //Journal of Applied Mechanics and Technical Physics. – 2020. – Т. 61. – №. 3. – С. 359-367.
• Grek G. R., Katasonov M. M., Kozlov V. V., Kornilov V. I.Effect of Distributed Suction on the Development of Disturbances on the Wing Profile //Doklady Physics. – Pleiades Publishing, 2020. – Т. 65. – №. 4. – С. 157-160.
• Okulov V.L., Gesheva E., Kuibin P.A., Shtork S.I., Sørensen J.N, Wood D., Alekseenko S. V. (2020) The difference between the motion of a helical vortex and the movement of fluid particles along its axis. Thermophysics and Aeromechanics, 27, No. 4, 473-480
• Okulov V.L., Fukumoto Y. (2020) Analytical solutions for the self-induced motion of a helical vortex with a Gaussian core. Thermophysics and Aeromechanics, 27, No. 4, 481-488
• Kozlov V.V., Grek G.R., Katasonov M.M., Kornilov V.I., Sadovskii I.A. The distributed-suction effect on the development of disturbances at the nonlinear stage of their evolution in the boundary layer // Doklady Physics. –2020. –Vol. 65 No. 8. –P. 276-280.
• Ryzhenkov VO, Sozinov DA, Mullyadzhanov RI. Effect of geometry on direct and adjoint linear global modes of the low Reynolds number laminar flow over a body (Journal of Engineering Thermophysics, принята к публикации)
• Г. Р. Грек, М. М. Катасонов, В. В. Козлов, В. И. Корнилов, И. А. Садовский Управление ламинарно-турбулентным переходом на крыловом профиле путем распределенного отсоса через мелкоперфорированную поверхность (Сибирский физический журнал)
• В.В. Козлов, Г.Р. Грек, М.М. Катасонов, В.И. Корнилов, А.В. Крюков, И.А. Садовский. Управление нелинейной стадией ламинарно-турбулентного перехода на крыловом профиле путем распределенного отсоса через мелкоперфорированную поверхность (Сибирский физический журнал)