A validated model of a photovoltaic water pumping system for off-grid rural communities

•The energy conversion chain in a photovoltaic water pumping system was modelled.•Water collection by the inhabitants was included as a model input.•The model was validated by using data acquired on a system in rural Africa.•The accuracy of the model is higher than 95% when using local climatic data...

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Bibliographic Details
Published in:Applied energy 2019-05, Vol.241, p.580-591
Main Authors: Meunier, Simon, Heinrich, Matthias, Quéval, Loïc, Cherni, Judith A., Vido, Lionel, Darga, Arouna, Dessante, Philippe, Multon, Bernard, Kitanidis, Peter K., Marchand, Claude
Format: Article
Language:English
Subjects:
Data validated model
Electric power
Energy conversion
Engineering Sciences
Photovoltaic system
Solar resource
Water pumping
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Summary:•The energy conversion chain in a photovoltaic water pumping system was modelled.•Water collection by the inhabitants was included as a model input.•The model was validated by using data acquired on a system in rural Africa.•The accuracy of the model is higher than 95% when using local climatic data.•Accuracy drops of 1–3% when replacing local climatic data by satellite ones. The low electrification rate in rural sub-Saharan Africa prevents access to energy services which are essential to improve living conditions. One of these energy services is electrified water pumping, which is particularly relevant for these areas where water access continues being a significant challenge. Pumping systems powered by photovoltaic energy have emerged as an interesting solution in off-grid areas. This article presents a model of photovoltaic water pumping system (PVWPS) for providing domestic water to off-grid rural communities. The model simulates the pumped flow rate and the water level in the storage tank from the climatic data (irradiance, ambient temperature) and the profile of water collection by the users of the system. The modelling of the different stages of the energy conversion chain and a method for identifying the unknown parameters of PVWPS are presented in this article. The model is applied to a pilot PVWPS situated in a rural village of Burkina Faso. The comparison between the measurements performed on the system and the model outputs allows to validate the model experimentally. Results indicate that the model permits to accurately simulate the water height in the tank both when climatic data from local sensors and from satellite are inputted in the model. The model could therefore be applied to other off-grid areas to perform techno-economic optimization and size new PVWPS as well as to evaluate the performances of existing PVWPS. The originalities of this work include the consideration of the water collection profile as a model input and the monitoring of a PVWPS in a rural village of Sub-Saharan Africa, an area where no continuous measurements on these systems has been performed, to the best knowledge of the authors. Further, the comparison of the impact of inputting satellite climatic data instead of measured ones on the PVWPS model accuracy is also a novel contribution.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2019.03.035