Second order and transverse flow visualization through three-dimensional particle image velocimetry in millimetric ducts

Despite recent advances in 3D particle image velocimetry (PIV), challenges remain in measuring small-scale 3D flows, in particular flows with large dynamic range. This study presents a scanning 3D-PIV system tailored for oscillatory flows, capable of resolving transverse flows less than a percent of...

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Veröffentlicht in:	Experimental thermal and fluid science 2024-12, Vol.159, p.None-None, Article 111296
Hauptverfasser:	Harte, N.C., Obrist, D., Versluis, M., Jebbink, E. Groot, Caversaccio, M., Wimmer, W., Lajoinie, G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Computational fluid dynamics (CFD) Dean vortices Low Reynolds number Microfluidics Scanning particle image velocimetry (PIV) Secondary flow Three-dimensional three-component (3D3C)
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container_title	Experimental thermal and fluid science
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creator	Harte, N.C. Obrist, D. Versluis, M. Jebbink, E. Groot Caversaccio, M. Wimmer, W. Lajoinie, G.
description	Despite recent advances in 3D particle image velocimetry (PIV), challenges remain in measuring small-scale 3D flows, in particular flows with large dynamic range. This study presents a scanning 3D-PIV system tailored for oscillatory flows, capable of resolving transverse flows less than a percent of the axial flow amplitude. The system was applied to visualize transverse flows in millimetric straight, toroidal, and twisted ducts. Two PIV analysis techniques, stroboscopic and semi-Lagrangian PIV, enable the quantification of net motion as well as time-resolved axial and transverse velocities. The experimental results closely align with computational fluid dynamics (CFD) simulations performed in a digitized representation of the experimental model. The proposed method allows the examination of periodic flows in systems down to microscopic scale and is particularly well-suited for applications that cannot be scaled up due to their complex, multi-physics nature. •3D scanning Particle Image Velocimetry system for measuring oscillating flows.•Stroboscopic and semi-Lagrangian Particle Image Velocimetry analysis.•Net motion and time-resolved flow quantification with two analysis methods.•Validation of experimental data with computational fluid dynamics simulations.•Effect of geometry on transverse flow in millimetric ducts.
doi_str_mv	10.1016/j.expthermflusci.2024.111296
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subjects	Computational fluid dynamics (CFD) Dean vortices Low Reynolds number Microfluidics Scanning particle image velocimetry (PIV) Secondary flow Three-dimensional three-component (3D3C)
title	Second order and transverse flow visualization through three-dimensional particle image velocimetry in millimetric ducts
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