

Article
Effect of uniform blowing/suction in a turbulent boundary layer at moderate Reynolds number
Authors: 
Kametani, K., Fukagata, K., Örlü, R., Schlatter, P. 
Document Type: 
Article 
Pubstate: 
Published 
Journal: 
Int. J. Heat and Fluid Flow 
Volume: 
55
132142 
Year: 
2015 
AbstractA number of wellresolved largeeddy simulations (LES) of a spatially evolving turbulent boundary layer with uniform blowing or suction is performed in order to investigate the effect on skin friction drag as well as turbulence statistics and spectral composition at moderate Reynolds numbers up to Re_\theta=2500, based on the freestream velocity and the momentumloss thickness. The amplitude of uniform blowing or suction is set to be 0.1% of the freestream velocity with different streamwise ranges of the controlled region. The boundary layer is thickened by blowing and thinned by suction. The Reynolds shear and normal stresses are increased by blowing and decreased by suction, most prominently, in the outer region. Through spectral analysis of the streamwise velocity and crossspectra of the Reynolds shear stress, the enhancement and reduction of the fluctuation energy in the outer region by blowing and suction are found, respectively. It is also found that the emergence of a second peak in the outer region is promoted by blowing, while it is inhibited in the case of suction. In spite of the weak amplitude of the control, more than 10% of drag reduction and enhancement are achieved by means of blowing and suction, respectively. In the case of blowing, where drag reduction is achieved, the mean drag reduction rate increases as the blowing region extends because the local reduction rate, i.e. the streamwise gradient of the mean drag reduction rate, grows in the streamwise direction. The netenergy saving rate and the control gain have the same trends. It is found that a more effective skin friction drag reduction and control efficiency can be achieved with a wider control region that starts at a more upstream location.
dx.doi.org/10.1016/j.ijheatfluidflow.2015.05.019

