Solar systems based on the coupling of parabolic concentrating collectors and thermal engines (i.e. dish-Stirling systems) are among the most efficient generators of solar power currently available. This study focuses on the modelling of functioning data from a 32 kWe dish-Stirling solar plant installed at a facility test site on the University of Palermo campus, in Southern Italy. The proposed model, based on real monitored data, the energy balance of the collector and the partial load efficiency of the Stirling engine, can be used easily to simulate the annual energy production of such systems, making use of the solar radiation database, with the aim of encouraging a greater commercialisation of this technology. Introducing further simplifying assumptions based on our experimental data, the model can be linearised providing a new analytical expression of the parameters that characterise the widely used Stine empirical model. The model was calibrated against datacorresponding to the collector with clean mirrors and used to predict the net electric production of the dish-Stirling accurately. A numerical method for assessing the daily level of mirror soiling without the use of direct reflectivity measures was also defined. The proposed methodology was used to evaluate the history of mirror soiling for the observation period, which shows a strong correlation with the recorded sequence of rains and dust depositions. The results of this study emphasise how desert dust transport events, frequent occurrences in parts of the Mediterranean, can have a dramatic impact on the electric power generation of dish-Stirling plants.
A facility for testing different components for HCPV application has been developed in the framework of\ud
“Fotovoltaico ad Alta Efficienza” (FAE) project funded by the Sicilian Regional Authority (PO FESR Sicilia 2007/2013\ud
4.1.1.1). The testing facility is equipped with an heliostat providing a wide solar beam inside the lab, an optical bench\ud
for mounting and aligning the HCPV components, electronic equipments to characterize the I-V curves of multijunction\ud
cells operated up to 2000 suns, a system to circulate a fluid in the heat sink at controlled temperature and flow-rate, a\ud
data logging system with sensors to measure temperatures in several locations and fluid pressures at the inlet and outlet\ud
of the heat sink, and a climatic chamber with large test volume to test assembled HCPV modules
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