Performance analysis of a hybrid solar-driven cooler for refrigerator vehicle

•A hybrid solar cooling system for refrigerator vehicle is studied.•The system is primarily run by PV-operated DC compressor.•AC compressor which is run by vehicle electrical source support the DC compressor.•Detailed electrical characteristics of the PV modules is modelled and validated.•Detailed t...

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Bibliographic Details
Published in:International journal of refrigeration 2023-09, Vol.153, p.281-295
Main Authors: Eletri, Houda, Salilih, Elias M., Hamed, Mouna, Fellah, Ali
Format: Article
Language:English
Subjects:
Cycle frigorifique
Ensemble photovoltaïque
PV array
Refrigeration cycle
Solar-driven cooling system
Système de refroidissement à énergie solaire
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Summary:•A hybrid solar cooling system for refrigerator vehicle is studied.•The system is primarily run by PV-operated DC compressor.•AC compressor which is run by vehicle electrical source support the DC compressor.•Detailed electrical characteristics of the PV modules is modelled and validated.•Detailed thermodynamic and heat transfer analysis of the system is analyzed. This study focused on investigating the annual performance of a novel hybrid solar-driven cooling system that can be used on refrigerator vehicles. The cooling system is mainly driven by a DC compressor which is powered by a PV array, while an AC compressor which is powered by the car alternator assists the cooling system when the cooling load is higher than the capacity of the DC compressor. Detailed electrical modeling of the PV panels in the array is performed based on an algorithm that comprises a set of mathematical equations and is validated against the manufacturer's test data. The detailed transient electrical power generation of the PV array is analyzed. The effect of solar irradiation and ambient temperature on the performance of the PV modules is presented. Considering the refrigeration cycle, detailed thermodynamics and heat transfer analysis on the cycle are carried out. The effect of ambient temperature and refrigerator compartment temperature on the performance of the refrigeration cycle is investigated. It is concluded that an increase in ambient temperature decreases the performance of both the PV panel and the refrigeration cycle. While an increase in refrigerator compartment temperature increases the performance of the refrigeration cycle.
ISSN:0140-7007
DOI:10.1016/j.ijrefrig.2023.06.007