Experimental and numerical study of Buoyancy-driven low turbulence flow in rectangular enclosure partially filled with isolated solid blockages

•The effect of isolated blockages proximity on natural convection flow inside an enclosure was investigated.•Natural convection inside an enclosure are very sensitive to the proximity of blockages.•The Heat transfer becomes very significant when blockages are positioned within the hydrodynamic bound...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2018-12, Vol.127, p.534-545
Main Authors: Iyi, Draco, Hasan, Reaz, Penlington, Roger
Format: Article
Language:English
Subjects:
Aerodynamics
Air temperature
Buoyancy
Buoyancy-driven flow
Computational fluid dynamics
Cylinders
Data banks
Enclosures
Experimental benchmark data
Free convection
Heat transfer
Hydrodynamic boundary layer
Isolated blockages
Low turbulence
Natural convection flow
Numerical study
Proximity
Rayleigh number
Temperature
Temperature gradients
Turbulence
Turbulent flow
Walls
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Summary:•The effect of isolated blockages proximity on natural convection flow inside an enclosure was investigated.•Natural convection inside an enclosure are very sensitive to the proximity of blockages.•The Heat transfer becomes very significant when blockages are positioned within the hydrodynamic boundary layer.•Blockages proximity can affect the overall heat transfer via flow field.•Blockages positioned outside the hydrodynamic boundary layer resulted in 7.6% increase in the heat transfer. This paper considers the natural convection inside an air filled enclosure having several isolated cylindrical blockages distributed within it, and arranged parallel to two vertical walls of the enclosure. These two walls are maintained at different temperatures resulting in a natural convection process inside the enclosure. The objectives are to provide experimental temperature data and to investigate the influence of the blockages proximity within and outside the active vertical wall hydrodynamic boundary layer of the natural convection flow and heat transfer. Experiments were designed with high degree of accuracy to provide reliable temperature data-bank for a range of blockages proximity to the active vertical walls. The test enclosure is an air filled rectangular cavity fixed at 0.97 m × 0.4 m × 1 m, corresponding to the height, width and depth respectively. The top and bottom walls are conducting surface and the temperature difference between the active vertical walls was maintained at 42.2 °C resulting in a characteristic Rayleigh number of 4.04 × 109 based on the enclosure height. All the walls of the enclosure were insulated externally while the inner surfaces were covered with conducting plate. The test cavity capability of establishing low turbulence natural convection flows was verified. All temperature data were obtained at steady state and it was verified to be reproducible by repeating the experiment at different times. Also, two-dimensionality was verified via rigorous temperature readings over a period of time. Additional temperature readings were recorded for the air and cylinder surfaces at several distinct locations. Further investigations were conducted using a numerical approach to supplement and validate the experiments. Experimental temperature data collated at various locations within the enclosure show excellent comparison with numerical results and as such provide a useful experimental benchmark temperature data for the validation of low turbulen
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2018.07.031