MATHEMATICAL SIMULATION OF FUELS PRODUCTION PROCESSES BASED ON WATER-OIL EMULSION BY HYDRODYNAMIC CAVITATION METHOD

O.M. Obodovych; G.K. Ivanytsky; B. Tselen; N.L Radchenko; A.Y. Nedbailo; V.V. Shulyak

doi:10.30890/2567-5273.2022-24-01-025

Authors

O.M. Obodovych Institute of Engineering Thermophysics of the National Academy of Science of Ukraine https://orcid.org/0000-0001-7213-3118
G.K. Ivanytsky Institute of Engineering Thermophysics of the National Academy of Science of Ukraine https://orcid.org/0000-0002-0486-2359
B. Tselen Institute of Engineering Thermophysics of the National Academy of Science of Ukraine https://orcid.org/0000-0001-5213-0219
N.L Radchenko Institute of Engineering Thermophysics of the National Academy of Science of Ukraine https://orcid.org/0000-0002-5315-1609
A.Y. Nedbailo Institute of Engineering Thermophysics of the National Academy of Science of Ukraine https://orcid.org/0000-0002-8590-5823
V.V. Shulyak Institute of Engineering Thermophysics of the National Academy of Science of Ukraine

DOI:

https://doi.org/10.30890/2567-5273.2022-24-01-025

Keywords:

hydrodynamic cavitation, wateroil fuel, heat and mass transfer, hydrodynamics

Abstract

Today, in connection with the global energy crisis, the issue of developing technologies for new types of fuels is becoming urgent. An alternative to traditional fuels used at thermal power facilities is water-oil fuel, the use of which is expedient from

Metrics

Metrics Loading ...

References

Dengaev A., Verbitsky V. Eremenko O., Novikova A., Getalov A., Sargin B. (2022). Water-in-oil emulsions separation using a controlled multi-frequency acoustic field at an operating facility. Energies 2022, 15, 63-69. https://doi.org/10.3390/15176369

Ivanitsky G., Tselen B., Radchenko N., Gozhenko L. (2021). Analytical study of the mechanism of droplet deformation and breakup in shear flows. Thermophysics and Thermal Power Engineering, 43(1), 30–37. https://doi.org/10.31472/ttpe.1.2021.4.

Ivanitsky G., Tcelen B., Nedbaylo A., Konuk A. (2019) Modelling the kinetics of cavitation boiling up of liquid. Physics of aerodynamic systems, 57, 136-146. https://doi.org/10.18524/0367-1631.2019.57.191970.

Ivanitsky G., Tcelen B., Nedbaylo A., Gozhenko L. (2020). The ways of producing an unified mathematical model for the cavitating flow in hydrodynamic cavitation reactors. Thermophysics and Thermal Power Engineering, 42(2), 31-38. https://doi.org/https://doi.org/10.31472/ttpe.2.2020.3

Vignoli, Lucas, Barros, A., Thomé, Roberto, Nogueira, A., Paschoal, Ricardo, Rodrigues, Hilario. (2013) Modeling the dynamics of single-bubble sonoluminescence. European Journal of Physics. 34(3), 679. https://doi.org/10.1088/0143-0807/34/3/679

Guillermo Hauke, Daniel Fuster, Cesar Dopazo (2007) Dynamics of a single cavitating and reacting bubble. Phys. Rev. E. 75(6), 066310. https://doi.org/10.1103/PhysRevE.75

Shima A., Tomita Y., Ohno T. (1988) Tempeture effects on single bubble collapse and induced impulsive pressure. J. Fluid Engng.110(2), 194 ¬199.

Nigmatulin R.I. Khabeev N.S. Nagiev F.B. (1981) Dynamics, heat and mass transfer of vapor-gas bubbles in liquid. Int. J. Heat Mass Transfer. 24(6), 1033–1041.

Dolinsky A. A., Ivanitsky G. K. Heat and mass transfer and hydrodynamics in vapor-liquid environments. Thermophysical fundamentals of discrete-pulse input of energy. Kyiv: Naukova Dumka, 2008. - 381 p.