Parametric study of heat transfer coefficient and friction factor in a corrugated channel

•Heat transfer coefficient and friction factor in an annular corrugated channel.•Five inner elements with different corrugation pitch and height and one smooth.•The most suitable characteristic parameter is the 'severity index'.•General empirical correlations for the friction factor and he...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2022-11, Vol.196, p.123290, Article 123290
Main Authors: Amrar, Z., Rabinovich, E., Baroukh, I., Ziskind, G.
Format: Article
Language:English
Subjects:
Corrugated annular channel
Dimensionless correlations
Experimental study
Friction factor
Heat transfer coefficient
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Summary:•Heat transfer coefficient and friction factor in an annular corrugated channel.•Five inner elements with different corrugation pitch and height and one smooth.•The most suitable characteristic parameter is the 'severity index'.•General empirical correlations for the friction factor and heat transfer coefficient.•For a wavy element, the heat transfer area can be reduced up to 30–65%. In this paper, an experimental investigation of the heat transfer coefficient and friction factor in a vertical annular channel with an inner wavy (corrugated) wall is presented. Six inner elements were tested, five of them with different corrugation pitch and height and one element smooth. The corrugation height varies from 0.4 mm to 0.8 mm and the pitch varies from 4 mm to 8 mm. The hydraulic diameter varies from 7.1 mm to 10.7 mm and the Reynolds number, based on the hydraulic diameter, varies in the range of 7,500 to 37,000. Based on the empirical analysis, it was found that the most suitable characteristic parameter to define the effect of corrugation on the flow and heat transfer is the 'severity index' φ=e2/pDh, where e is the corrugation height, p is the pitch and Dh is the hydraulic diameter. General empirical correlations were developed for the friction factor and heat transfer coefficient for an annular channel with a wavy inner wall under turbulent flow regime. Examining the thermal effectivity of a wavy element, commonly calculated with factors R1, R3, R5 to assess the real benefits offered by corrugation tubes, it is evident that by replacing a smooth wall with a wavy one, the thermal performance of the system can improve by 30–190%, depending on various fixed parameters, e.g., mass flow rate, pump power, pressure gradient and heat transfer surface. However, for the same elements the increase in friction factor was in the range of 70–210%. Regarding the size of the heat transfer area, it is shown that if a wavy element is used, the effective size for heat transfer area can be reduced up to 30–65%, depending on the Reynolds number and the severity index.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2022.123290