An advanced aero-thermodynamic study of a heart-shaped dimpled pipe
An advanced aero-thermodynamic study of a heart-shaped dimpled pipe
The detailed flow field and local heat transfer enhancement in a pipe with heart-shaped dimples on the internal surface were experimentally studied. The flow structures were investigated at a flow regime of Re=20k in five different measurement planes around a dimple in the streamwise and spanwise directions using both planar PIV and stereo PIV. A ray tracing-based image correction method was utilized to overcome the important image distortions caused by the optically complex geometry of the dimple for the planar PIV measurements. Furthermore, the convective heat transfer coefficient on the wall of the dimple was investigated utilizing steady-state liquid crystal thermography (LCT) and infrared thermography within the flow regime range of Re=20k-60k. A comprehensive uncertainty analysis was conducted to account for the multiple measured quantities and corresponding error sources on such a complex geometry. The resulting heat transfer and flow fields revealed that maximum heat transfer enhancement is concentrated along the reattachment line downstream of the dimple where higher kinetic energy levels are observed. The enhancement factor, which is a measure of the heat transfer improvement relative to a smooth pipe, was evaluated on average at 1.7 across the dimpled surface, with local maxima reaching values up to 2.8. The dimpled pipe under examination had a relative skin friction coefficient of approximately 1.8 compared to a smooth pipe. This outperforms some of the roughness elements, such as ribs and spherical dimples, previously studied on similar circular channels in literature
Dimples, Heat transfer, Liquid crystals thermography, Particle image velocimetry, Ray tracing, Roughened channels
Can Akkurt, Muhsin
d72bb8ab-7181-4186-ac64-5f048fdf56e2
Virgilio, Marco
059fcc1a-721e-4d48-9933-e7f4ddc82fde
Arts, Tony
25a584e8-a08c-4e89-a925-a935f06bddab
Van Geem, Kevin.M
981e5c92-ca43-4626-afbf-d4c85f8e974a
1 September 2023
Can Akkurt, Muhsin
d72bb8ab-7181-4186-ac64-5f048fdf56e2
Virgilio, Marco
059fcc1a-721e-4d48-9933-e7f4ddc82fde
Arts, Tony
25a584e8-a08c-4e89-a925-a935f06bddab
Van Geem, Kevin.M
981e5c92-ca43-4626-afbf-d4c85f8e974a
Can Akkurt, Muhsin, Virgilio, Marco, Arts, Tony and Van Geem, Kevin.M
(2023)
An advanced aero-thermodynamic study of a heart-shaped dimpled pipe.
International Journal of Heat and Mass Transfer, 211 (9), [124257].
(doi:10.1016/j.ijheatmasstransfer.2023.124257).
Abstract
The detailed flow field and local heat transfer enhancement in a pipe with heart-shaped dimples on the internal surface were experimentally studied. The flow structures were investigated at a flow regime of Re=20k in five different measurement planes around a dimple in the streamwise and spanwise directions using both planar PIV and stereo PIV. A ray tracing-based image correction method was utilized to overcome the important image distortions caused by the optically complex geometry of the dimple for the planar PIV measurements. Furthermore, the convective heat transfer coefficient on the wall of the dimple was investigated utilizing steady-state liquid crystal thermography (LCT) and infrared thermography within the flow regime range of Re=20k-60k. A comprehensive uncertainty analysis was conducted to account for the multiple measured quantities and corresponding error sources on such a complex geometry. The resulting heat transfer and flow fields revealed that maximum heat transfer enhancement is concentrated along the reattachment line downstream of the dimple where higher kinetic energy levels are observed. The enhancement factor, which is a measure of the heat transfer improvement relative to a smooth pipe, was evaluated on average at 1.7 across the dimpled surface, with local maxima reaching values up to 2.8. The dimpled pipe under examination had a relative skin friction coefficient of approximately 1.8 compared to a smooth pipe. This outperforms some of the roughness elements, such as ribs and spherical dimples, previously studied on similar circular channels in literature
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An advanced aero-thermodynamic study of a heart-shaped dimpled pipe
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Accepted/In Press date: 30 April 2023
e-pub ahead of print date: 8 May 2023
Published date: 1 September 2023
Additional Information:
Funding Information:
This research is funded by the European Research Council under the European Union's Horizon 2020 research and innovation programme/ERC grant agreement no 818607.
Publisher Copyright:
© 2023
Keywords:
Dimples, Heat transfer, Liquid crystals thermography, Particle image velocimetry, Ray tracing, Roughened channels
Identifiers
Local EPrints ID: 479914
URI: http://eprints.soton.ac.uk/id/eprint/479914
ISSN: 0017-9310
PURE UUID: b8e415b6-c6e7-461e-8b3e-08543598961b
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Date deposited: 28 Jul 2023 16:49
Last modified: 17 Mar 2024 03:36
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Contributors
Author:
Muhsin Can Akkurt
Author:
Marco Virgilio
Author:
Tony Arts
Author:
Kevin.M Van Geem
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