Geodesic
Change of the integral characteristics of the fluid flow in the axial vortex heat generator
Vestnik Tverskogo gosudarstvennogo universiteta. Seriâ Prikladnaâ matematika, no. 4 (2016), pp. 35-44 Cet article a éte moissonné depuis la source Math-Net.Ru

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Mathematical model of axial heat generator based on the Navier-Stokes equations, written in cylindrical coordinates in the approximation of axial symmetry. The results of numerical experiments on the calculation of flow fields passive axial heat generator indicate a significant change in the unevenness of the hydrodynamic characteristics of the flow, averaged over the cross section.
Keywords: numerical experiment, integral characteristics, vortex heat generator, passive axial. 
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V. I. Klimok. Change of the integral characteristics of the fluid flow in the axial vortex heat generator. Vestnik Tverskogo gosudarstvennogo universiteta. Seriâ Prikladnaâ matematika, no. 4 (2016), pp. 35-44. http://geodesic.mathdoc.fr/item/VTPMK_2016_4_a2/

[1] Furmakov E. F., Can Hydrothermodynamic Heat Generators Work Super-Efficiently?, Tehpribor JSC Publ., Spb, 2004, 22 pp. (in Russian)

[2] Akhmetov Yu. M., Kalimullin R. R., Tselishchev V. A., “Numerical and physical modeling of fluid flow in the vortex heat generator”, Herald of Ufa State Aviation Technical University, 14:4 (39) (2010), 42–49 (in Russian)

[3] Klimok V. I., Rubtsov I. Yu., “Mathematical modeling of hydrodynamic mode in thermal vortex generator”, Vestnik TvGU. Seriya: Prikladnaya Matematika [Herald of Tver State University. Series: Applied Mathematics], 2010, no. 19, 21–27 (in Russian)

[4] Klimok V. I., Rubtsov I. Yu., “Mathematical modeling of hydrothermodynamic mode in thermal vortex generator”, Vestnik TvGU. Seriya: Prikladnaya Matematika [Herald of Tver State University. Series: Applied Mathematics], 2012, no. 1 (24), 25–36 (in Russian)

[5] Klimok V. I., “Numerical simulation of fluid flow in vortex axial heat generator”, Vestnik TvGU. Seriya: Prikladnaya Matematika [Herald of Tver State University. Series: Applied Mathematics], 2015, no. 3, 5–13 (in Russian)

[6] Kochin N. E., Kibel' I. A., Roze N. V., Theoretical Hydromechanics, Inostrannaya literatura Publ., Moscow, 1963 (in Russian)