Optimisation and analysis of a heat pipe assisted low-energy passive cooling system

[Display omitted] •Heat pipe assisted passive cooling analysed and optimised.•FLUENT code used for pressure and velocity field simulations.•Cooling capacity decreased by 10.7% when Sd/D increased from 1 to 2.•Good agreement between CFD and wind tunnel experimental results.•Heat pipes are a reliable...

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Bibliographic Details
Published in:Energy and buildings 2017-05, Vol.143, p.220-233
Main Authors: Chaudhry, Hassam Nasarullah, Calautit, John Kaiser, Hughes, Ben Richard
Format: Article
Language:English
Subjects:
Aerodynamics
Air flow
Comfort
Computational fluid dynamics
Computer applications
Cooling
Cooling capacity
Cooling systems
Energy
Energy consumption
Energy efficiency
Experimentation
Fluid dynamics
Heat
Heat pipe
Heat pipes
Hydrodynamics
Numerical prediction
Optimization
Passive cooling
Pipes
Software
Streamwise
Temperature
Temperature effects
Temperature profiles
Velocity
Ventilation
Wind tunnel
Wind tunnels
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Summary:[Display omitted] •Heat pipe assisted passive cooling analysed and optimised.•FLUENT code used for pressure and velocity field simulations.•Cooling capacity decreased by 10.7% when Sd/D increased from 1 to 2.•Good agreement between CFD and wind tunnel experimental results.•Heat pipes are a reliable source of passive cooling for windcatchers. Passive cooling using windcatchers have been utilised in the past by several Middle East countries to capture wind and provide indoor ventilation and comfort without using energy. Recently, researchers have attempted to improve the cooling performance of windcatchers by incorporating heat pipes. The present work encompasses existing research by optimising the arrangement of heat pipes in natural ventilation airstreams using numerical and experimental tools. The airflow and temperature profiles were numerically predicted using Computational Fluid Dynamics (CFD), the findings of which were quantitatively validated using wind tunnel experimentation. Using a source temperature of 314K or 41°C and an inlet velocity of 2.3m/s, the streamwise distance-to-pipe diameter ratio was varied from 1.0 to 2.0 and the emergent cooling capacities were established to comprehend the optimum arrangement. The results of this investigation indicated that the heat pipes operate at their maximum efficiency when the streamwise distance is identical to the diameter of the pipe as this formation allows the incoming airstream to achieve the maximum contact time with the surface of the pipes. In addition, the findings showed that any increase in streamwise spacing leads to the formation of a second bell curve representing an increase in air velocity which simultaneously reduces the contact time between the airstream and the heat pipes, decreasing its effectiveness. The study quantified that the optimum streamwise distance was 20mm at which the Sd/D (streamwise distance-to-pipe diameter) ratio was 1.0. The thermal cooling capacity was subsequently found to decrease by 10.7% from 768W to 686W when the streamwise distance was increased to 40mm (Sd/D ratio of 2.0). The technology presented here is subject to an international patent application (PCT/GB2014/052263).
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2017.02.002