Applied Sciences (Jul 2020)

Solar Thermal Collector Output Temperature Prediction by Hybrid Intelligent Model for Smartgrid and Smartbuildings Applications and Optimization

  • José-Luis Casteleiro-Roca,
  • Pablo Chamoso,
  • Esteban Jove,
  • Alfonso González-Briones,
  • Héctor Quintián,
  • María-Isabel Fernández-Ibáñez,
  • Rafael Alejandro Vega Vega,
  • Andrés-José Piñón Pazos,
  • José Antonio López Vázquez,
  • Santiago Torres-Álvarez,
  • Tiago Pinto,
  • Jose Luis Calvo-Rolle

DOI
https://doi.org/10.3390/app10134644
Journal volume & issue
Vol. 10, no. 13
p. 4644

Abstract

Read online

Currently, there is great interest in reducing the consumption of fossil fuels (and other non-renewable energy sources) in order to preserve the environment; smart buildings are commonly proposed for this purpose as they are capable of producing their own energy and using it optimally. However, at times, solar energy is not able to supply the energy demand fully; it is mandatory to know the quantity of energy needed to optimize the system. This research focuses on the prediction of output temperature from a solar thermal collector. The aim is to measure solar thermal energy and optimize the energy system of a house (or building). The dataset used in this research has been taken from a real installation in a bio-climate house located on the Sotavento Experimental Wind Farm, in north-west Spain. A hybrid intelligent model has been developed by combining clustering and regression methods such as neural networks, polynomial regression, and support vector machines. The main findings show that, by dividing the dataset into small clusters on the basis of similarity in behavior, it is possible to create more accurate models. Moreover, combining different regression methods for each cluster provides better results than when a global model of the whole dataset is used. In temperature prediction, mean absolute error was lower than 4 ∘ C.

Keywords