LAPSE:2023.4607
Published Article
LAPSE:2023.4607
Large Eddy Simulation of Conjugate Heat Transfer in a Ribbed Channel: Reynolds Number Effect
February 23, 2023
Abstract
Large eddy simulations were performed for the conjugate heat transfer in a ribbed channel with a geometry, that mimics the internal cooling passage of a gas turbine, using 566, 100, 10, and 1 as the solid and fluid thermal conductivity ratios (K*) and 30,000, 7000 (turbulent flow), and 1000 (laminar flow) as the Reynolds numbers. A fully coupled simulation was conducted using the immersed boundary method (IBM) and a dynamic sub-grid-scale (SGS) model. In pure convection, a decrease in the Reynolds number from 30,000 to 7000 increased the heat transfer on the channel wall by 5% but decreased that on the rib by 20%. When K* > 10, the Reynolds number effect is stronger in the rib than in the wall. In the laminar flow, the effect of conduction appears at a low K*, and the heat transfer promotion is poor in the typical ribbed channel geometry. In the turbulent flow, if K* ≥ 100, then a heat transfer promotion is expected in the ribbed channel even at a low Reynolds number. For K* < 10, the thermal performance in the turbulent flow is worse than that in the laminar flow, and thus, no rib effect is expected.
Large eddy simulations were performed for the conjugate heat transfer in a ribbed channel with a geometry, that mimics the internal cooling passage of a gas turbine, using 566, 100, 10, and 1 as the solid and fluid thermal conductivity ratios (K*) and 30,000, 7000 (turbulent flow), and 1000 (laminar flow) as the Reynolds numbers. A fully coupled simulation was conducted using the immersed boundary method (IBM) and a dynamic sub-grid-scale (SGS) model. In pure convection, a decrease in the Reynolds number from 30,000 to 7000 increased the heat transfer on the channel wall by 5% but decreased that on the rib by 20%. When K* > 10, the Reynolds number effect is stronger in the rib than in the wall. In the laminar flow, the effect of conduction appears at a low K*, and the heat transfer promotion is poor in the typical ribbed channel geometry. In the turbulent flow, if K* ≥ 100, then a heat transfer promotion is expected in the ribbed channel even at a low Reynolds number. For K* < 10, the thermal performance in the turbulent flow is worse than that in the laminar flow, and thus, no rib effect is expected.
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Keywords
conjugate heat transfer, immersed boundary method, large eddy simulation, Reynolds number, ribbed channel, thermal conductivity ratio
Subject
Suggested Citation
Ahn J, Song JC, Lee JS. Large Eddy Simulation of Conjugate Heat Transfer in a Ribbed Channel: Reynolds Number Effect. (2023). LAPSE:2023.4607
Author Affiliations
Ahn J: School of Mechanical Engineering, Kookmin University, Seoul 02707, Korea [ORCID]
Song JC: School of Mechanical and Aerospace Engineering, Seoul National University, Seoul 08826, Korea
Lee JS: School of Mechanical and Aerospace Engineering, Seoul National University, Seoul 08826, Korea
Song JC: School of Mechanical and Aerospace Engineering, Seoul National University, Seoul 08826, Korea
Lee JS: School of Mechanical and Aerospace Engineering, Seoul National University, Seoul 08826, Korea
Journal Name
Processes
Volume
10
Issue
10
First Page
1928
Year
2022
Publication Date
2022-09-23
ISSN
2227-9717
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Original Submission
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PII: pr10101928, Publication Type: Journal Article
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LAPSE:2023.4607
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https://doi.org/10.3390/pr10101928
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Feb 23, 2023
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