Numerical study on characteristics of flow and heat transfer in a cooling passage with a tear-drop dimple surface

The present study numerically investigated the characteristics of flow and heat transfer in a channel with a newly designed surface called a tear-drop dimple on the bottom wall by deforming the upstream shape of a dimple cavity. Direct numerical simulations (DNS) were carried out with a Reynolds num...

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Bibliographic Details
Published in:International journal of thermal sciences 2015-03, Vol.89, p.121-135
Main Authors: Yoon, Hyun Sik, Park, Sang Hyeop, Choi, Changyoung, Ha, Man Yeong
Format: Article
Language:English
Subjects:
Channels
Circulation
Cooling
Dimpling
Flow characteristics
Heat exchanger
Heat transfer
Heat transfer enhancement
Holes
Tear-drop dimple
Upstream
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Summary:The present study numerically investigated the characteristics of flow and heat transfer in a channel with a newly designed surface called a tear-drop dimple on the bottom wall by deforming the upstream shape of a dimple cavity. Direct numerical simulations (DNS) were carried out with a Reynolds number of 2800 based on the mean velocity and channel height. A Prandtl number of 0.71 was considered. The present study considered six different cases, consisting of one general dimple case and five tear-drop dimple cases where only the length of the upstream cavity was changed. The overall performance was assessed using volume goodness factors. The notable flow characteristics observed in this study include the circulation, which is classified into two types: spanwise circulation and streamwise swirling motion. The pressure loss and heat transfer are influenced by the two types of flow patterns. A comparison of the thermo-hydraulic performances of the tear-drop dimples and those of the general dimple confirms the advantage of the tear-drop dimple shape over the general dimple. •The streamwise swirl motion formed over the tear-drop shape.•The streamwise swirl motion breaks the spanwise circulation of the upstream dimple.•The streamwise swirl motion enhances the heat transfer.
ISSN:1290-0729
1778-4166
DOI:10.1016/j.ijthermalsci.2014.11.002