Heat gain reduction by means of thermoelectric roof solar collector

This paper presents a numerical investigation on attic heat gain reduction by using thermoelectric modules integrated in a conventional roof solar collector (RSC). This system, called thermoelectric roof solar collector (TE-RSC), is composed of a transparent glass, air gap, a copper plate, thermoele...

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Bibliographic Details
Published in:Solar energy 2005-01, Vol.78 (4), p.495-503
Main Authors: Maneewan, S., Hirunlabh, J., Khedari, J., Zeghmati, B., Teekasap, S.
Format: Article
Language:English
Subjects:
Applied sciences
Ceiling heat transfer rate
Economic
Electricity
Energy
Exact sciences and technology
Heat conductivity
Natural energy
Roof solar collector
Solar collectors
Solar energy
Solar thermal conversion
Thermodynamics
TRNSYS
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Summary:This paper presents a numerical investigation on attic heat gain reduction by using thermoelectric modules integrated in a conventional roof solar collector (RSC). This system, called thermoelectric roof solar collector (TE-RSC), is composed of a transparent glass, air gap, a copper plate, thermoelectric modules (TE) and rectangular fin heat sink. Due to the incident solar radiation, a temperature difference is created between the hot and cold sides of TE modules that generates a direct current. This current is used to drive a ventilating fan for cooling the TE-RSC and enhancing attic ventilation that reduces ceiling heat gain. The system performance was simulated using TRNSYS program with new TE and DC fan components developed by our team and compared to a common house. Simulation results using real house configuration showed that a TE-RSC unit of 0.0525 m 2 surface area can generate about 9 W under 972 W/m 2 global solar radiation and 35 °C ambient temperature. The induced air change varied between 20 and 40 and the corresponding ceiling heat transfer rate reduction is about 3–5 W/m 2. The annual electrical energy saving was about 362 kWh. Finally, economical calculations indicated that the payback period of the TE-RSC is 4.36 years and the internal rate of return is 22.05%.
ISSN:0038-092X
1471-1257
DOI:10.1016/j.solener.2004.08.003