

HEATING OF THE LIQUID FILM UNDER CONSTANT HEAT FLUX ON THE WALL
Sakhnov A.Yu.
Institute of Thermophysics SB RAS, Novosibirsk, Russia
Citation:
Sakhnov, A.Yu., (2015) Heating of the liquid film under constant heat flux on the wall, Modern Science: Researches, Ideas, Results, Technologies, Iss. #1(16), PP. 20  27.

Keywords: boundary layer; separation; suction; favorable pressure gradient; accelerated flow; permeable wall; injection; blowing; analytical solution; blow off 
Abstracts:
The paper reports on numerical and analytical investigation of the laminar boundary layer with a favorable pressure gradient over a permeable wall. Researchers have obtained an analytical solution of boundary layer equations for asymptotic flow conditions. This solution allows proposing a relative asymptotic skinfriction function, which determines a degree of influence of flow acceleration and permeable wall on the flow. There are ranges of this function, where effects of permeable wall and streamwise pressure gradient have to be considered only in combination. Numerical simulation has showed that such combined influence of favorable pressure gradient and permeable wall extends the asymptotic flow. The study of a strong gas blowing into the accelerated flow has revealed that favorable pressure gradient impedes separation of the boundary layer. At that asymptotic flow starts from the point, where the separation would occur at gas injection into the zeropressure gradient flow. 
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