Indoor environment PV applications: Estimation of the maximum harvestable power

The use of PV modules for powering sensors in an indoor environment requires that, during the design process, the harvestable power be evaluated and compared with the power requirements of the load device to validate their compatibility for a given type of light source and level of illumination. The...

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Bibliographic Details
Published in:Renewable & sustainable energy reviews 2024-04, Vol.193, p.114287, Article 114287
Main Authors: Yufenyuy, Severine Wiysahnyuy, Mengata, Ghislain Mengounou, Nneme Nneme, Leandre, Bongwirnso, Umaru Mohammed
Format: Article
Language:English
Subjects:
Harvestable maximum power
Indoor environment
Metaheuristics optimisation
PV modules
Smart sensors
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Summary:The use of PV modules for powering sensors in an indoor environment requires that, during the design process, the harvestable power be evaluated and compared with the power requirements of the load device to validate their compatibility for a given type of light source and level of illumination. The models reported recently to relate power to illumination during power estimation are seen to result in large estimation errors in the case of an indoor environment. This paper seeks to propose an appropriate model that can be exploited during maximum power estimation in an indoor environment to relate power to illumination level. Proceeding from fitting measured data to the three-diode model of the PV module and based on the errors and execution time, the Grey Wolf Optimisation Algorithm, among others, proved to be accurate for estimating maximum power. The relationship between maximum power and illumination was seen to take the form of a second-degree polynomial. This was validated by comparing the values of power estimated by this model to the measured values as well as values estimated with the linear model, the exponential model, and the model proposed by Joseph Amajama. The proposed model proved to be more accurate than the models reported, recording errors of not more than 5 %, which is acceptable for system design. This will go a long way towards facilitating the design of indoor energy harvesting systems that can be used for powering smart sensors and other IoT devices. •The Grey Wolf Optimisation Algorithm (GWO) has been evaluated to be accurate in estimating the maximum harvestable power of PV modules in an indoor environment.•The current at the maximum power point increases linearly with illumination, while the voltage at the maximum power point varies according to a second-degree polynomial function for the m-Si-based PV module under all lamps and a-Si under CFL.•The variation of voltage at the maximum power point for the p-Si-based PV module is explained by a logarithmic function.•The relationship between maximum power and illumination was seen to take the form of a second-degree polynomial.
ISSN:1364-0321
1879-0690
DOI:10.1016/j.rser.2024.114287