Experimental study of the heat transfer of single-jet impingement cooling onto a large heated plate near industrial conditions

Experimental study of the heat transfer of single-jet impingement cooling onto a large heated plate near industrial conditions

•Jet impingement cooling for different Reynolds numbers, from 9,800 to 120,000.•Results of the dissipated heat, transverse heat flux, and rewetting and maximum cooling rate fronts.•Large-scale tests provide important data of the cooling, in particular far from the impact location.•Similar results fo...

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Bibliographic Details
Published in:International journal of heat and mass transfer Vol. 184; p. 121998
Main Authors: Oliveira, A. V. S., Maréchal, D., Borean, J.-L., Schick, V., Teixeira, J., Denis, S., Gradeck, M.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-03-2022
Elsevier BV
Elsevier
Subjects:
Boiling
Conduction heating
Conductive heat transfer
Cooling rate
Critical heat flux
Engineering Sciences
Experiments
Film boiling
Flow velocity
Fluid flow
Fluid mechanics
Heat conduction
Heat exchange
Heat exchangers
Heat flux
Hydraulic jets
Impact velocity
Inverse problem
Jet impingement
Laboratories
Mechanics
Metallurgy
Nickel plate
Nozzles
Physics
Quenching
Reactive fluid environment
Rewetting
Reynolds number
Stagnation
Thermics
Water flow
Heat conduction
Film boiling
Rewetting
Critical heat flux
Boiling
Quenching
Inverse problem
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Summary:•Jet impingement cooling for different Reynolds numbers, from 9,800 to 120,000.•Results of the dissipated heat, transverse heat flux, and rewetting and maximum cooling rate fronts.•Large-scale tests provide important data of the cooling, in particular far from the impact location.•Similar results for different jet nozzle diameters but with the same flow rate.•The higher the Reynolds number, the larger the heat dissipation far from the impact location. Jet impingement cooling has been intensively studied in the past by many authors because of its important application in the metallurgical industry; however, most of the experiments in the literature are at laboratory scale and, in some cases, not near industrial conditions. In this study, we performed cooling experiments near industrial conditions in a new experimental apparatus with a large nickel plate as test sample, which was heated until 850 ∘C before being cooled by a single circular water jet. Five experimental results are presented with different jet Reynolds numbers, from 9,800 to 120,000, obtained by varying the water flow rate and the nozzle diameter. The presented results are: temperature evolutions during cooling, dissipated heat flux (estimated by solving a 2D inverse heat conduction problem), transverse heat flux at the heat-exchanging surface, and the characteristics (position and velocity) of the rewetting and maximum cooling rate fronts. The increase in the jet Reynolds number increased slightly the heat flux at the stagnation zone, but increased it substantially for positions farther from the impact location. The transverse heat flux increased with the passage of the rewetting front and then decreased, and its magnitude was practically the same regardless of the jet Reynolds number. The change in the nozzle diameter did not affect significantly the heat transfer nor the rewetting front growth, although the heat dissipation was slightly higher with the smaller nozzle, possibly because of the higher jet impact velocity. Finally, we compared the present results with some found in the literature in similar conditions, showing that laboratory experiments are valuable to provide detailed information, especially near the stagnation zone, but large-scale experiments allow obtaining macroscale data of the cooling process.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2021.121998