Abstract
An experimental study regarding the thermofluid characteristics of a shell-and-plate heat exchanger with different chevron angles (45°/45°, 45°/65°, and 65°/65°) with a plate diameter of 440 mm was carried out. Water was used as the working fluid on both sides and the corresponding temperatures ranged from 30–70 °C. The flow rate on the plate or shell side ranged from 10–60 m3/h. The effects of chevron angles on the heat transfer and fluid flow characteristics of shell-and-plate heat exchangers were studied in detail. With regard to the heat transfer performance on the plate side, a higher chevron angle (65°/65°) resulted in a significantly better performance than a low chevron angle (45°/45°). The effect of the chevron angle became even more pronounced at high Reynolds numbers. Unlike the plate side, an increase in the chevron angle had a negative effect on the heat transfer performance of the shell side. Additionally, this opposite effect was more prominent at low Reynolds numbers due to the comparatively large contribution of the manifold. The friction factor increased appreciably with the increase in the chevron angle. However, when changing the chevron angle from 45°/45° to 65°/65°, the increase in the friction factor was about 3–4 times on the plate side while it was about 2 times on the shell side. This can be attributed to the presence of the distribution/collection manifold on the shell side. Empirical correlations for the Nusselt number and friction factor were developed for different combinations of chevron angles with mean deviations of less than 1%.
Highlights
Shell-and-tube heat exchangers are the most common heat exchangers and are widely used in several industries as well as having process and petrochemical applications
The results showed that the plate size has a negligible effect on the boiling heat transfer coefficient (HTC), while it declined with an increase in superheat temperatures
The results showed good agreement with the correlations and proved that shell-and-plate heat exchanger (SPHE) are a suitable alternative to shell-and-tube heat exchangers since they offer superior performance and compactness
Summary
Shell-and-tube heat exchangers are the most common heat exchangers and are widely used in several industries as well as having process and petrochemical applications. Many of the aforementioned problems (e.g., flow re-circulation, high pressure drop, leakages and bypasses, low thermal efficiency, and vibration) can be addressed through the use of a plate heat exchanger (PHE), which offers high heat transfer performance, less volume, lower weight, and is easy to clean (for the gasket type). They can withstand lower pressure and temperature and leakages may still occur in gasket type PHEs
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