The three-dimensional structure of swirl-switching in bent pipe flow

TL;DR

This study reveals that a three-dimensional wave-like structure causes low-frequency swirl-switching in turbulent bent pipe flow, identified through direct numerical simulation and 3D proper orthogonal decomposition, challenging previous 2D-based understandings.

Contribution

The paper demonstrates, for the first time, that a 3D wave-like structure is responsible for swirl-switching, emphasizing the importance of 3D analysis over 2D methods in understanding this phenomenon.

Findings

A 3D wave-like structure causes swirl-switching.

Upstream flow does not influence swirl-switching modes.

3D POD is essential for accurate mode reconstruction.

Abstract

Swirl-switching is a low-frequency oscillatory phenomenon which affects the Dean vortices in bent pipes and may cause fatigue in piping systems. Despite thirty years worth of research, the mechanism that causes these oscillations and the frequencies that characterise them remain unclear. Here we show that a three-dimensional wave-like structure is responsible for the low-frequency switching of the dominant Dean vortex. The present study, performed via direct numerical simulation, focuses on the turbulent flow through a 90 \degree pipe bend preceded and followed by straight pipe segments. A pipe with curvature 0.3 (defined as ratio between pipe radius and bend radius) is studied for a bulk Reynolds number Re = 11 700, corresponding to a friction Reynolds number Re_\tau \approx 360. Synthetic turbulence is generated at the inflow section and used instead of the classical recycling method in order to avoid the interference between recycling and swirl-switching frequencies. The flow field is analysed by three-dimensional proper orthogonal decomposition (POD) which for the first time allows the identification of the source of swirl-switching: a wave-like structure that originates in the pipe bend. Contrary to some previous studies, the flow in the upstream pipe does not show any direct influence on the swirl-switching modes. Our analysis further shows that a three- dimensional characterisation of the modes is crucial to understand the mechanism, and that reconstructions based on 2D POD modes are incomplete.