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

N. C. Harte; D. Obrist; M. Versluis; E. Groot Jebbink; M. Caversaccio; W. Wimmer; G. Lajoinie

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

N. C. Harte
, D. Obrist
, M. Versluis
, E. Groot Jebbink
, M. Caversaccio
, W. Wimmer^*
, G. Lajoinie^*

^*Corresponding author for this work

Research output: Working paper › Preprint › Academic

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Abstract

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.

Original language	English
Publisher	Social Science Research Network (SSRN)
Number of pages	17
Publication status	Published - 26 Mar 2024

Keywords

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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ssrn-4773315Final published version, 22.6 MB

Second order and transverse flow visualization through three-dimensional particle image velocimetry in millimetric ducts
Harte, N. C., Obrist, D., Versluis, M., Jebbink, E. G., Caversaccio, M., Wimmer, W. & Lajoinie, G., Dec 2024, In: Experimental thermal and fluid science. 159, 17 p., 111296.
Research output: Contribution to journal › Article › Academic › peer-review

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

abstract = "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.",

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T1 - Second order and transverse flow visualization through three-dimensional particle image velocimetry in millimetric ducts

AU - Harte, N. C.

AU - Obrist, D.

AU - Versluis, M.

AU - Jebbink, E. Groot

AU - Caversaccio, M.

AU - Wimmer, W.

AU - Lajoinie, G.

PY - 2024/3/26

Y1 - 2024/3/26

N2 - 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.

AB - 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.

KW - Computational fluid dynamics (CFD)

KW - Dean vortices

KW - Low Reynolds number

KW - Microfluidics

KW - Scanning particle image velocimetry (PIV)

KW - Secondary flow

KW - Three-dimensional three-component (3D3C)

M3 - Preprint

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

PB - Social Science Research Network (SSRN)

ER -

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

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Keywords

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

Cite this