Modeling of Natural Ventilation in Solar Chimney and Optimization of the Channel Profile by CFD Method

Ya Xin Su; Fei Ning Lei; Yu Feng Xue

doi:10.4028/www.scientific.net/AMM.368-370.549

Paper Titles

Simulation Study of Planning Layout Effect on Outdoor Microclimate of Cold Residence
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Review of Energy Efficiency Design Structure System for Building Night Ventilation
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Optimization Analysis of Layout Scheme of Outdoor Unit of the Multi-Evaporator Air Conditioner in a Certain Business Center
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Numerical Simulation on Ventilated Cavity Flow with Different Turbulence Models
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Modeling of Natural Ventilation in Solar Chimney and Optimization of the Channel Profile by CFD Method
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Test Study of the Thermal Environment in Summer of New and Old Two Types of Rural Houses in QiLian Mountain Northern Foothills Area
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The Economized Design of Modern Indoor House
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The Influence of Thermal Inertia Index on the Residential External Walls in Hot-Summer and Cold-Winter Areas
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The Research of Green Design for Apartments for the Elderly
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 368-370Modeling of Natural Ventilation in Solar Chimney...

Modeling of Natural Ventilation in Solar Chimney and Optimization of the Channel Profile by CFD Method

Abstract:

The natural ventilation in solar chimney was numerically simulated by computational fluid dynamics method and the effect of solar chimney profiles was discussed. The flow rate through a rectangular solar chimney increased with the solar chimney height. The flow pattern in the chimney was laminar flow when the chimney height was lower than a critical height and then became turbulent flow as the height further increased. When designing the solar chimney, it is important to remember that the critical chimney height should ensure the air flow in the channel could develop to be turbulent in order to get a large flow rate. As the width of the solar chimney increased, the flow rate increased to a peak value and then decreased to a minimum value and then increased again. The reason was due to the curve flow stream and uneven pressure distribution formed when the chimney width increased. A modified chimney profile of linearly tapered solar chimney could remove the reverse flow and improved the flow rate by 25%.

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Periodical:

Applied Mechanics and Materials (Volumes 368-370)

Pages:

549-553

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.368-370.549

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Online since:

August 2013

Authors:

Ya Xin Su, Fei Ning Lei, Yu Feng Xue

Keywords:

Chimney Structure, Natural Ventilation, Numerical Simulation, Solar Chimney

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