Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling

Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling

A transient 3D thermal model based on the thermal quadrupole method, coupled to ray tracing analysis, is presented. This methodology can predict transient temperature maps under any time-fluctuating irradiance flux—either synthetic or experimental—providing a useful tool for the...

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Main Authors: Alejandro Mateos-Canseco, Manuel I. Peña-Cruz, Arturo Díaz-Ponce, Jean-Luc Battaglia, Christophe Pradère, Luis David Patino-Lopez
Format: Article
Language:English
Published: MDPI AG 2018-08-01
Series:Energies
Subjects:
CPV systems
solar concentration
Fresnel lens
ray tracing
thermal quadrupoles
temperature field
2D transient thermal analysis
Online Access:http://www.mdpi.com/1996-1073/11/8/2042
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spelling doaj-a137bcf3bbad455992a12379cb1064342020-11-25T01:40:45ZengMDPI AGEnergies1996-10732018-08-01118204210.3390/en11082042en11082042Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles ModellingAlejandro Mateos-Canseco0Manuel I. Peña-Cruz1Arturo Díaz-Ponce2Jean-Luc Battaglia3Christophe Pradère4Luis David Patino-Lopez5CONACYT—Centro de Investigación Científica de Yucatán—Renewable Energy Department, Parque Científico Tecnológico de Yucatán, Sierra Papacal, Mérida 97302, Yucatán, MexicoCONACYT—Centro de Investigaciones en Óptica, A.C. Unidad Aguascalientes—Prol. Constitución 607, Fracc. Reserva Loma Bonita, Aguascalientes 20200, Aguascalientes, MexicoCONACYT—Centro de Investigaciones en Óptica, A.C. Unidad Aguascalientes—Prol. Constitución 607, Fracc. Reserva Loma Bonita, Aguascalientes 20200, Aguascalientes, MexicoI2M Laboratory, UMR CNRS 5295, University of Bordeaux, 351 Cours de la Libération, 33405 Talence CEDEX, FranceI2M Laboratory, UMR CNRS 5295, University of Bordeaux, 351 Cours de la Libération, 33405 Talence CEDEX, FranceCONACYT—Centro de Investigación Científica de Yucatán—Renewable Energy Department, Parque Científico Tecnológico de Yucatán, Sierra Papacal, Mérida 97302, Yucatán, MexicoA transient 3D thermal model based on the thermal quadrupole method, coupled to ray tracing analysis, is presented. This methodology can predict transient temperature maps under any time-fluctuating irradiance flux—either synthetic or experimental—providing a useful tool for the design and parametric optimization of concentration photovoltaics systems. Analytic simulations of a concentration photovoltaics system thermal response and assessment of in-plane thermal gradients induced by fast tracking point perturbations, like those induced by wind, are provided and discussed for the first time. Computation times for time-resolved temperature maps can be as short as 9 s for a full month of system operation, with stimuli inspired by real data. Such information could pave the way for more accurate studies of cell reliability under any set of worldwide irradiance conditions.http://www.mdpi.com/1996-1073/11/8/2042CPV systemssolar concentrationFresnel lensray tracingthermal quadrupolestemperature field2D transient thermal analysis
collection DOAJ
language English
format Article
sources DOAJ
author Alejandro Mateos-Canseco
Manuel I. Peña-Cruz
Arturo Díaz-Ponce
Jean-Luc Battaglia
Christophe Pradère
Luis David Patino-Lopez
spellingShingle Alejandro Mateos-Canseco
Manuel I. Peña-Cruz
Arturo Díaz-Ponce
Jean-Luc Battaglia
Christophe Pradère
Luis David Patino-Lopez
Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling
Energies
CPV systems
solar concentration
Fresnel lens
ray tracing
thermal quadrupoles
temperature field
2D transient thermal analysis
author_facet Alejandro Mateos-Canseco
Manuel I. Peña-Cruz
Arturo Díaz-Ponce
Jean-Luc Battaglia
Christophe Pradère
Luis David Patino-Lopez
author_sort Alejandro Mateos-Canseco
title Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling
title_short Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling
title_full Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling
title_fullStr Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling
title_full_unstemmed Time-Resolved Temperature Map Prediction of Concentration Photovoltaics Systems by Means of Coupled Ray Tracing Flux Analysis and Thermal Quadrupoles Modelling
title_sort time-resolved temperature map prediction of concentration photovoltaics systems by means of coupled ray tracing flux analysis and thermal quadrupoles modelling
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2018-08-01
description A transient 3D thermal model based on the thermal quadrupole method, coupled to ray tracing analysis, is presented. This methodology can predict transient temperature maps under any time-fluctuating irradiance flux—either synthetic or experimental—providing a useful tool for the design and parametric optimization of concentration photovoltaics systems. Analytic simulations of a concentration photovoltaics system thermal response and assessment of in-plane thermal gradients induced by fast tracking point perturbations, like those induced by wind, are provided and discussed for the first time. Computation times for time-resolved temperature maps can be as short as 9 s for a full month of system operation, with stimuli inspired by real data. Such information could pave the way for more accurate studies of cell reliability under any set of worldwide irradiance conditions.
topic CPV systems
solar concentration
Fresnel lens
ray tracing
thermal quadrupoles
temperature field
2D transient thermal analysis
url http://www.mdpi.com/1996-1073/11/8/2042
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