Enhancement of natural convection for improvement of Trombe wall performance. An experimental study

Enhancement of natural convection for improvement of Trombe wall performance. An experimental study

This experimental work shows that the natural convective heat transfer in the active enclosure of a conventional Trombe wall assembly is enhanced by the interposition of transparent and vertical partitions. Quantification of the average Nusselt number corresponding to both versions with and without...

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Bibliographic Details
Published in:Energy and buildings Vol. 211; p. 109788
Main Authors: Baïri, A., Martín-Garín, A., Adeyeye, K., She, K., Millán-García, J.A.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 15-03-2020
Elsevier BV
Subjects:
Architecture
Aspect ratio
Assembly
Computer simulation
Configurations
Convection
Convective heat transfer
Design optimization
Error analysis
Experimental heat transfer
Fluid flow
Free convection
Heat flux
Heat transfer
High rayleigh number
Natural convection
Nusselt number
Parameter uncertainty
Partitions
Performance enhancement
Physical properties
Rayleigh number
Solar radiation
Thermal design
Thermal measurements
Trombe wall
Trombe walls
Viscosity
Architecture
High rayleigh number
Performance enhancement
Natural convection
Trombe wall
Experimental heat transfer
Thermal measurements
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Summary:This experimental work shows that the natural convective heat transfer in the active enclosure of a conventional Trombe wall assembly is enhanced by the interposition of transparent and vertical partitions. Quantification of the average Nusselt number corresponding to both versions with and without partitions was carried out by means of a 1/5 scale assembly. The glass cover is maintained isothermal at cold temperature while the active wall generates a variable heat flux simulating the incident solar radiation. The distance between the two active and parallel walls is variable. Four ratios between this distance and the height of the wall are considered, associated with a wide range of Rayleigh number reaching 4.1 × 109. An error calculation is carried out for all the processed configurations, taking into account the experimental uncertainties of the measured physical parameters. The maximum error found on the average Nusselt number is low, of about 5%. Measurements made by means of an interstitial medium without partitions are consistent with the results of other work carried out by experimental and numerical approaches in specific ranges of Rayleigh number. This study reveals the partitions effectiveness, since the natural convective heat transfer's increase lies between 10.0% and 14.4% according to the considered configuration. Correlations are proposed in the present work in order to calculate the average natural convective Nusselt number for the conventional Trombe wall without partitions and for its improved version, for any aspect ratio and in the whole range of the considered Rayleigh number. They contribute to the optimization of the thermal design of this interesting assembly.
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2020.109788