The paper aims to develop adequate means to measure the effectiveness of cooling technology of turbine blades. The used methodologies are the mathematical modeling of movement and heat transfer in the boundary layer of the working medium near the curved surface of the turbine blade and also using empirical data on the critical flow regimes. The mathematical model of film cooling of turbine engine blades under film formation on the punched surface with blind damping cavities is offered. On the basis of numerical research with the use of the offered model the option for essential (providing in analyzed conditions decrease in adiabatic temperature of a wall on 200 K) increase in efficiency of film cooling at the expense of a partial laminarization of a turbulent interface on the punched surface is revealed.
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Kaul, R., Sapali, S.N., CFD analysis of turbulent flow over centrifugal pump's impeller of various designs and comparison of numerical results for various models, (2013) International Review of Mechanical Engineering (IREME), 7 (1), pp. 248-26.

Togun, H., Abdulrazzaq, T., Kazi, S.N., Kadhum, A.A.H., Badarudin, A., Ariffin, M.K.A., Sadeghinezhad, E., Numerical study of turbulent heat transfer in separated flow: Review, (2013) International Review of Mechanical Engineering (IREME), 7 (2), pp. 337-34.

Rahmani, L., Draoui, B., Bouanini, M., Benachour, E., CFD study on heat transfer to Bingham fluid during with gate impeller, (2013) International Review of Mechanical Engineering (IREME), 7 (6), pp. 1074-1079.

Sivakumar, K., Natarajan, E., Kulasekharan, N., CFD simulation and experimental investigation of convection heat transfer in a rectangular convergent channel with staggered ribs, (2013) International Review of Mechanical Engineering (IREME), 7 (3), pp. 541-548.

N. N. Kovalnogov, L. V. Khakhaleva and E. K. Ermolaeva, RU Patent No. 2204743 (20 May 2003).

N. N. Kovalnogov and L. V. Khakhaleva, Drag reduction and heat transfer of a turbulent flow in a tube due to perforations with damping cavities, Journal of Engineering Thermophysics, n. 11, pp. 287-297, 2002.

N. N. Kovalnogov and V. N. Kovalnogov, Features of numerical integration and stability conditions for differential equations of the boundary layer under the intensive actions, Proceedings of the universities. Aeronautical engineering, n. 1, pp. 58-61, 1996.

N. N. Kovalnogov and V. N. Kovalnogov, Software and information complex for the analysis of the thermal state of turbomachinery blades. Proceedings of the universities. Aeronautical engineering, n. 3, pp. 36-39, 2003.

G. Schlichting, Theory of the boundary layer (Moscow: Nauka, 1974).
http://dx.doi.org/10.1007/978-3-642-85829-1

S. S. Kutateladze, Heat transfer and flow resistance (Moscow: Energoatomizdat, 1990).

M. E. Deitch, Technical gas dynamics (Moscow: Energy, 1974).

E. P. Dyban and E. Y. Epic, Heat-and-mass transfer and hydrodynamics of flows turbulized. (Kiev: Naukova Dumka, 1985).