Techno-economic and environmental evaluation of passive cooled photovoltaic systems in Mediterranean climate conditions

Techno-economic and environmental evaluation of passive cooled photovoltaic systems in Mediterranean climate conditions

•A passive cooling technique was experimentally investigated on the photovoltaic system.•Cooling technique was evaluated from techno-economic and environmental aspect.•The technique was proven to be economically feasible.•Environmental analysis proved possibility for reduction in carbon dioxide emis...

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Bibliographic Details
Published in:Applied thermal engineering Vol. 169; p. 114947
Main Authors: Grubišić Čabo, Filip, Nižetić, Sandro, Giama, Effrosyni, Papadopoulos, Agis
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 25-03-2020
Elsevier BV
Subjects:
Aluminum
Carbon dioxide
Cooling
Economic analysis
Electricity pricing
Emissions control
Field investigations
Fins
LCA
LCOE
Life cycle analysis
Life cycle assessment
Passive cooling
Photovoltaic cells
Photovoltaics
Polycrystals
Polysilicon
Renewable energy
Solar energy
Systems analysis
Weather
Passive cooling
LCA
Renewable energy
LCOE
Solar energy
Photovoltaics
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Summary:•A passive cooling technique was experimentally investigated on the photovoltaic system.•Cooling technique was evaluated from techno-economic and environmental aspect.•The technique was proven to be economically feasible.•Environmental analysis proved possibility for reduction in carbon dioxide emissions. This paper presents the techno-economic and environmental analysis of a passively cooled 260Wp polycrystalline silicon photovoltaic (PV) system, based on results from a field investigation in Mediterranean climate conditions. Current available research lacks the proper experimental analysis of air passive cooling technique in realistic conditions. Passive cooling was enabled by application of perforated aluminium fins fixed on the back side surface of the PV panel. The performance of the passively cooled PV system was compared with a non-cooled PV system of the same size. Obtained results reveal that the proposed cooling approach can increase power yield of the PV system by 5% on at maximum, which corresponds with other research results and approaches dealing with same conceptual passive cooling solution. This result is obtained with high confidence in results, in a manner which has not yet been done in PV systems analysis. Based on the experimental findings, an economic evaluation was carried out for a 30 kWp solar power plant, which resulted in a Levelized Cost of Electricity (LCOE) that ranged from 0.116 €/kWh to less than 0.10 €/kWh, with a simple payback time of 6 years, an acceptable value despite the subsidised electricity prices. Economic viability was hence proven and further possibilities were discussed, aiming at an improved LCOE. Finally, an environmental evaluation of the examined PV system was conducted by applying Life Cycle analysis (LCA); an interesting finding was that the considered PV system will start to have a positive contribution to CO2 emissions reduction after 7 years of operation, leaving the rest of operative lifetime for net CO2 emissions savings.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2020.114947