화학공학소재연구정보센터
Korean Journal of Chemical Engineering, Vol.16, No.6, 764-773, November, 1999
Stability Analysis of Heated Thin Liquid-Film Flows with Constant Thermal Boundary Conditions
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To answer the questions on the behavior of Liquid flows under complicatedly combined actions of stresses. evaporation and temperature-dependent surface tension effects, thin liquid layers flowing under gravity down an inclined plane uniformly heated from below are considered. There may be two thermal boundary conditions on the hot plate, i.e., either constant heat flux or fixed temperature. By using long-wave approximation, the nonlinear evolution equations governing the two-dimensional surface waves have been derived upto O(epsilon(2)) and O(epsilon) for the constant heat flux and the fixed temperature case, respectively. Here the small parameter epsilon(<<1) is the ratio of the characteristic length scale parallel to the flow to the initial basic film thickness. The linear and the nonlinear stability analyses are also performed by using numerical calculations. Consequently, the flow subjected to the constant heat flux can be marked as a more stable system than the flow mechanism at a fixed-temperature boundary condition.
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