Toward the detection of moving separation in unsteady flows

TL;DR

This paper introduces a Lagrangian-based method to detect and track moving separation points in unsteady flows where separation occurs away from the wall, addressing a less-studied but common flow phenomenon.

Contribution

It proposes a novel approach to identify moving separation points using Lagrangian saddle points and coherent structures in unsteady flows, extending analysis beyond wall-attached separation.

Findings

Separation points can be tracked via Lagrangian saddle points.

Saddle points retain hyperbolicity even when ejected from the wall.

Method successfully applied to flow around a translating cylinder and jet impingement.

Abstract

In many engineering systems operating with a working fluid, the best efficiency is reached close to a condition of flow separation, which makes its prediction very crucial in industry. Providing that wall-based quantities can be measured, we know today how to obtain good predictions for two and three-dimensional steady and periodic flows. In these flows, the separation is defined on a fixed line attached to a material surface. The last case to elucidate is the one where this line is no longer attached to the wall but on the contrary is contained within the flow. This moving separation is probably, however, the most common case of separation in natural flows and industrial applications. Since this case has received less attention during the past few years, we propose in this study to examine some properties of moving separation in two-dimensional, unsteady flows where the separation does not leave a signature on the wall. Since in this framework separation can be extracted by using a Lagrangian frame where the separation profile can be viewed as a hyperbolic unstable manifold, we propose a method to extract the separation point defined by the Lagrangian saddle point that belongs to this unstable manifold. In practice, the separation point and profile are initially extracted by detecting the most attracting Lagrangian coherent structure near the wall, and can then be advected in time for following instants. It is found that saddle points, which initially act as separation points in the viscous wall flow region, remarkably preserve their hyperbolicity even if they are ejected from the wall toward the inviscid region. Two test cases are studied, the creeping flow of a rotating and translating cylinder close to a wall, and the unsteady separation in the boundary layer generated by a planar jet impinging onto a plane wall.