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Dr. Mohamed Reda Aly Abd-Elhamid Salem :: Publications:

Title:
Effect of Coil Torsion on Heat transfer and Pressure Drop Characteristics of Shell and Coil Heat Exchanger
Authors: M.R. Salem, R.K. Ali, R.Y. Sakr and K.M. Elshazly
Year: 2015
Keywords: Heat exchanger, Helically Coiled Tube, Torsion, Friction, Experimental
Journal: Journal of Thermal Science and Engineering Applications
Volume: Not Available
Issue: Not Available
Pages: Not Available
Publisher: ASME
Local/International: International
Paper Link:
Full paper Mohamed Reda Aly Abd-Elhamid Salem_Effect of Coil Torsion on Heat transfer and Pressure Drop Characteristics of Shell and Coil Heat Exchanger (revised paper).pdf
Supplementary materials Not Available
Abstract:

The present work introduces an experimental study of horizontal shell and coil heat exchangers. Characteristics of the convective heat transfer in this type of heat exchangers and the friction factor for fully developed flow through their helically coiled tube (HCT) were investigated. The majority of previous studies were performed on HCTs with isothermal and isoflux boundary conditions or shell and coil heat exchangers with small ranges of HCT configurations and fluid operating conditions. Here, five heat exchangers of counter-flow configuration were constructed with different HCT-torsions (λ) and tested at different mass flow rates and inlet temperatures of both sides of the heat exchangers. Totally, 295 test runs were performed from which the HCT-side and shell-side heat transfer coefficients were calculated. Results showed that the average Nusselt numbers of both sides of the heat exchangers and the overall heat transfer coefficient increase by decreasing coil torsion. At lower and higher HCT-side Reynolds number, the average increase in the HCT-side average Nusselt number is of 108.7% and 58.6%, respectively, when λ decreases from 0.1348 to 0.0442. While, at lower and higher shell-side Reynolds number, the average increase in the shell-side average Nusselt number is of 173.9% and 69.5%, respectively, when λ decreases from 0.1348 to 0.0442. In addition, a slight increase of 6.4% is obtained in the HCT-Fanning friction factor at lower Reynolds number when λ decreases from 0.1348 to 0.0442, and this effect vanishes with increasing Reynolds number. Furthermore, correlations for the average Nusselt numbers of both sides of the heat exchangers and HCT-Fanning friction factor are obtained.

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