Comparative study of different desiccant wheel designs

Desiccant/evaporative cooling systems offer an environmentally benign alternative to conventional vapor compression chillers. A desiccant wheel is the heart of this heat driven cooling system and it uses a solid desiccant for dehumidification with silica gel being the most widely used. Proper design...

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Bibliographic Details
Published in:Applied thermal engineering 2011-07, Vol.31 (10), p.1613-1620
Main Authors: Narayanan, R., Saman, W.Y., White, S.D., Goldsworthy, M.
Format: Article
Language:English
Subjects:
Applied sciences
Chillers
Compressing
Dehumidification
Desiccant wheel
Desiccants
Design engineering
Energy
Energy. Thermal use of fuels
Evaporative cooling
Exact sciences and technology
Gas-side resistance
Heat transfer
Optimization
Regeneration
Silica gel
Solid-side resistance
Theoretical studies. Data and constants. Metering
Wheels
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Summary:Desiccant/evaporative cooling systems offer an environmentally benign alternative to conventional vapor compression chillers. A desiccant wheel is the heart of this heat driven cooling system and it uses a solid desiccant for dehumidification with silica gel being the most widely used. Proper design of the wheel is important for the successful operation of the system and theoretical models are useful tools in predicting the performance and optimizing the design. In this paper, two heat and mass transfer models of a counter flow desiccant wheel, one considering only the gas-side resistance, and the other considering both solid-side and gas-side resistances are developed. The models show good agreement with experimental data. The model is used to conduct a comparative study on the performance of different wheel designs. The study shows that the introduction of an axial cooling section can improve the performance of the wheel considerably. ► Two heat and mass transfer models for a counter flow desiccant wheel are presented. ► Models are validated with published experimental results. ► A comparative study on the performance of different wheel designs is done. ► Counter flow design has better dehumidification performance than parallel flow. ► An axial cooling section improves both dehumidification and cooling performance.
ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2011.01.043