Exergy assessment of a refrigeration plant using computational intelligence based on hybrid learning methods

•A computational intelligence method was proposed to model the exergetic behavior.•An neural network was trained using a hybrid method to model a refrigeration system.•The major exergy destruction was located at the compressor and at the condenser.•New insights to develop methods of analysis for ref...

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Bibliographic Details
Published in:International journal of refrigeration 2018-04, Vol.88, p.35-44
Main Authors: Belman-Flores, J.M., Barroso-Maldonado, J.M., Ledesma, Sergio, Pérez-García, V., Gallegos-Muñoz, A., Alfaro-Ayala, J.A.
Format: Article
Language:English
Subjects:
Analyse exergétique
ANN
Artificial neural networks
Computational fluid dynamics
Computer simulation
Destruction
Energy efficiency
Exergy
Exergy analysis
Fluid dynamics
Hybrid learning method
Hybrid systems
Intelligence
Mathematical models
Méthode d’apprentissage hybride
Parameters
Refrigeration
Rotation
Réseau neuronal artificiel
Simulated annealing
Système à compression de vapeur
Vapor compression system
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Summary:•A computational intelligence method was proposed to model the exergetic behavior.•An neural network was trained using a hybrid method to model a refrigeration system.•The major exergy destruction was located at the compressor and at the condenser.•New insights to develop methods of analysis for refrigeration systems are proposed. In this study, a method to model the exergetic behavior of a refrigeration system using some techniques from computational intelligence is proposed. The input parameters of the model are: the compressor rotation speed, the volumetric flow rates and the temperatures of the secondary fluids. The artificial neural network was trained using a hybrid learning method based on Simulated Annealing and Levenberg Marquardt method. Two independent neural networks were designed to visualize and analyze the exergy destruction and exergy efficiency for each component of a vapor compression system. The relative errors produced during the validation of the model were within ±10%. From the application simulation, it was concluded that the major exergy destruction is located at the compressor and at the condenser. Additionally, it was observed that the parameters that most influence the exergetic behavior of the system are: the compressor rotation speed and the inlet temperatures of the secondary fluids.
ISSN:0140-7007
1879-2081
DOI:10.1016/j.ijrefrig.2018.01.004