Conservation relation of generalized growth rate in boundary layers

doi:10.1007/s10483-018-2394-9

Abstract

Abstract: The elementary task is to calculate the growth rates of disturbances when the e^N method in transition prediction is performed. However, there is no unified knowledge to determine the growth rates of disturbances in three-dimensional (3D) flows. In this paper, we study the relation among the wave parameters of the disturbance in boundary layers in which the imaginary parts of wave parameters are far smaller than the real parts. The generalized growth rate (GGR) in the direction of group velocity is introduced, and the conservation relation of GGR is strictly deduced in theory. This conservation relation manifests that the GGR only depends on the real parts of wave parameters instead of the imaginary parts. Numerical validations for GGR conservation are also provided in the cases of first/second modes and crossflow modes. The application of GGR to the e^N method in 3D flows is discussed, and the puzzle of determining growth rates in 3D flows is clarified. A convenient method is also proposed to calculate growth rates of disturbances in 3D flows. Good agreement between this convenient method and existing methods is found except the condition that the angle between the group velocity direction and the x-direction is close to 90° which can be easily avoided in practical application.

Key words: fluid dynamics, boundary element method , Stokes equations, boundary layer stability, generalized growth rate (GGR), e^N method

2010 MSC Number:

76E09

Runjie SONG, Lei ZHAO, Zhangfeng HUANG. Conservation relation of generalized growth rate in boundary layers. Applied Mathematics and Mechanics (English Edition), 2018, 39(12): 1755-1768.

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