Effective aero-optical suppression by steady wall blowing and wall suction schemes for supersonic turbulent boundary layer

H. Zou, X. Yang, X.-W. Sun, W. Liu, Q. Yang
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引用次数: 1

Abstract

As a basic flow model for engineering applications, wall-bounded turbulent flow has been widely studied in the field of aero-optics, but the flow control methods that could effectively suppress aero-optical effects are relatively rare. As an urgent requirement in engineering application, the concept of the steady wall blowing and suction is proposed by the author. Firstly, the author briefly described the flow model and physical method. Secondly, the choice of disturbance type is given. Then, the results of wall blowing-suction, suction and blowing ways based on steady and unsteady disturbance are compared. Finally, it is concluded that employing the high steady wall blowing disturbance (A = 0.2) could realise aero-optical suppression by around 20%. Besides, the steady wall suction scheme contributes to about 70%–80% reduction effect within a wide amplitude range (A = 0.2–1.0), which suppresses this effect by maintaining laminar state downstream contrasted by the baseline case.
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超声速湍流边界层的稳定壁面吹风和壁面吸力气动光学抑制
壁面湍流作为工程应用的基本流动模型,在气动光学领域得到了广泛的研究,但能够有效抑制气动光学效应的流动控制方法却相对较少。作为工程应用的迫切需要,作者提出了稳定壁吹吸的概念。首先,简要介绍了流动模型和物理方法。其次,给出了扰动类型的选择。然后比较了壁式抽吸、抽吸和基于定常扰动和非定常扰动的吹气方式的结果。最后得出采用高稳态壁吹扰(A = 0.2)可实现20%左右的气动光学抑制。此外,稳定壁面吸力方案在较宽幅度范围内(a = 0.2-1.0)的降噪效果约为70%-80%,与基线情况相比,稳定壁面吸力方案通过维持下游层流状态抑制了降噪效果。
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