Downstream passive flow control by phononic subsurfaces

Flow control over surfaces is a hereditary engineering problem of a multi-disciplinary nature. It is concerned with devising passive or active means of intervention with the flow field and its underlying mechanisms in a manner that causes desirable changes in the overall flow behavior. For streamlined bodies cruising through a flow, such as air or water, there is a key interest in the control of flow instabilities which manifest as fluid waves. These are perturbations in the flow velocity field that if left to grow are likely to trigger transition of the flow from laminar to turbulent, which in turn causes significant increases in skin-friction drag. An increase in drag reduces the efficiency in air and water vehicles, pipelines, and other applications involving fluid-structure interactions. It is therefore desired to device intervention methods to impede the growth of these instabilities. Alternatively, in some scenarios, the objective may be to speed up the growth of the instabilities to prevent or delay flow separation.

In previous research, we have shown that wave motion underneath a surface interacting with a flow may be tuned to cause the flow to stabilize, or destabilize, as desired [Hussein et al., Proc. R. Soc. A, 2015]. The underlying control mechanism utilizes core concepts from phonon physics, primarily, the principle of destructive or constructive interferences and the notion of symmetry breaking. This is realized by installing a “phononic subsurface” (PSub), which is an engineered structure placed in the subsurface region and configured such that its edge is exposed to the flow, forming an elastic fluid-structure interface. The PSub may take the form of a phononic crystal or an elastic metamaterial, with finite extent, and is typically (but not necessarily) oriented perpendicular to the fluid-structure interface. It is designed to exhibit specific frequency-dependent amplitude and phase response characteristics at the edge exposed to the flow. We will present results demonstrating the ability of a configuration of metamaterial-based PSubs to cause flow stabilization, or destabilization if desired, not only near the region of installation but also downstream of this region. These results provide a key advancement of the emerging paradigm of PSubs for passive flow control.