Thermal mixing enhancement of a free cooling/heating system with a 2D space-filling plate

Free-cooling/heating system has been incorporated with heating, ventilating and air-conditioning (HVAC) systems to provide low-cost cooling. The present work investigates numerically with the use of 2D space-filling plates to enhance the thermal mixing between the drawn in surrounding cooler air and...

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Bibliographic Details
Published in:Applied thermal engineering 2015-10, Vol.89, p.946-957
Main Authors: Teh, An Liang, Siow, Yong Hoi, Chin, Wai Meng, Chia, Chee Ming, Foo, Ji Jinn
Format: Article
Language:English
Subjects:
2D space-filling plate
Computational fluid dynamics
Cooling systems
Flow recirculation
Fluid flow
Fractal grid
Heating systems
HVAC
Inserts
Thermal mixing
Turbulence
Turbulent flow
Two dimensional
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Summary:Free-cooling/heating system has been incorporated with heating, ventilating and air-conditioning (HVAC) systems to provide low-cost cooling. The present work investigates numerically with the use of 2D space-filling plates to enhance the thermal mixing between the drawn in surrounding cooler air and the recycled warm air within a T-duct to strengthen the heat transfer at HVAC heat exchanger. Three inserts are used to generate turbulence at Reh = 2.19 × 104, i.e. positive square-fractal grid (PSFG), negative square-fractal grid (NSFG), and circular orifice (CO). Two-equation turbulence model is employed for turbulence kinetic energy κ predictions in insert induced thermal mixing. In particular, the effects of κ on space-filling geometry and tilted angle for each insert are discussed. Results show that for 45° tilted inserts, the thermal mixing performance of CO is about 2134%, 1382%, and 374% higher than the empty channel, PSFG, and NSFG, respectively, at x/H = 4.2. Tilted inserts thermal mixing are significantly better than the non-tilted cases. Plate tilting allows the production of larger scales of flow recirculation, of which accompany by higher flow fluctuations leeward from each insert. Therefore, with CO inserts being fully encompassed by the larger and wider scales of κ, the thermal mixing outperforms the space-filling fractal inserts. •2D planar space-filling inserts of various configurations were investigated.•Effects of plate tilting performance at −45°, 0°, and 45° were numerically studied.•Thermal mixing performance of tilted insert outperforms the non-tilted counterpart.•Circular orifice generated flow fluctuations permit widest range of thermal mixing.•Manufacturing sustainability could be secured with the use of circular orifice.
ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2015.06.058