Abstract
Vibration wall control is an important active flow control technique studied by many researchers. Although current researches have shown that the control performance is greatly affected by the frequency and amplitude of the vibration wall, the mechanism hiding behind the phenomena is still not clear, due to the complex interaction between the vibration wall and flow separation. To reveal the control mechanism of vibration walls, we propose a simplified model to help us understand the interaction between the forced excitation (from the vibration wall) and self-excitation (from flow instability). The simplified model can explain vibration wall flow control behaviors obtained by numerical simulation, which show that the control performance will be optimized at a certain reduced vibration frequency or amplitude. Also, it is shown by the analysis of maximal Lyapunov exponents that the vibration wall is able to change the flow field from a disordered one into an ordered one. Consistent with these phenomena and bringing more physical insight, the simplified model implies that the tuned vibration frequency and amplitude will lock in the unsteady flow separation, promote momentum transfer from the main stream to the separation zone, and make the flow field more orderly and less chaotic, resulting in a reduction of flow loss.
Highlights
In this paper, we introduce a simplified model to describe the interaction between the forced excitation and self-excitation, and analyze the phenomena and mechanism of vibration wall flow control based on this model
The effect of vital control parameters for vibration wall in a curved diffuser is studied by numerical simulation (CFD) and analyzed based on a nonlinear simplified model
The outcomes of the model agree with the CFD results qualitatively, helping us to understand the phenomena and mechanisms in vibration wall control
Summary
Flow separation is generally accepted to be the breakaway or detachment of fluid from a solid surface [1]. Researchers from all over the world are seeking the way to avoid or suppress flow separation. It is widely accepted that unsteady flow control techniques need less energy input than steady ones to achieve the same control performance [2]. Vibration wall control is used for a curved diffuser (as shown in Figure 4) with typical flow separation in this paper. The diffuser includes an inlet, a curved part and an outlet. The inlet width, outlet width and chord length of the curved part are 34.3 mm, 55 mm and 80 mm, respectively. More details of the numerical method and some of the numerical results can be found in Ref. [19]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
