Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-30T20:33:05.298Z Has data issue: false hasContentIssue false

Image and Ray Tracing Analysis of a Parabolic Dish Collector to Achieve High Flux on a Solar Volumetric Reactor

Published online by Cambridge University Press:  27 February 2020

Nidia Aracely Cisneros-Cárdenas*
Affiliation:
Chemical Engineering Department, University of Sonora, Hermosillo, Sonora, Mexico
Rafael Enrique Cabanillas-López
Affiliation:
Chemical Engineering Department, University of Sonora, Hermosillo, Sonora, Mexico
Ramiro Alberto Calleja-Valdez
Affiliation:
Chemical Engineering Department, University of Sonora, Hermosillo, Sonora, Mexico
Ricardo Arturo Pérez-Enciso
Affiliation:
Chemical Engineering Department, University of Sonora, Hermosillo, Sonora, Mexico
Carlos Alberto Pérez-Rábago
Affiliation:
Renewables Energies Institute, National Autonomous University of Mexico (UNAM), Temixco, Morelos, Mexico
Rafael Gutiérrez-García
Affiliation:
Physics Research Department (DIFUS), University of Sonora, Hermosillo, Sonora, Mexico
*
Get access

Abstract

The need to achieve a uniform distribution of concentrated solar flux in the photovoltaic, thermal or any other receivers is a common problem; therefore, the optical characterization of the concentration system is necessary to determinate the physical characteristics of the receptors. In this work, a parabolic dish concentrator of 1.65x1.65 m2, developed by research from the University of Arizona, is optically characterized under normal operating conditions, also known as environmental conditions that refer to non-controlled conditions as solar radiation, environmental temperature and wind velocity that could affect slightly, by thermal and mechanical efforts, the distribution profiles of the concentrated solar radiation. The set used for the evaluation consisted of the parabolic mirror and Chilled Lambertian Flat Surface installed in the focal point on the optical axis of the mirror. The evaluation was divided into two parts: a theoretical part that consist on using ray tracing simulation and an experimental part that corresponds to image analysis. The used methodology in this work has been stablish in many researches, so this is a reliable method. The global optical error was 2.3 mrad under normal operating conditions.

Type
Articles
Copyright
Copyright © Materials Research Society 2020

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

References:

Luque, A., Sala, G., Luque-Heredia, I., Photovoltaic concentration at the onset of its commercial deployment, Prog. Photovoltaics Res. Appl. 14 (2006) 413428.CrossRefGoogle Scholar
Steinfeld, A., Schubnell, M., Optimum aperture size and operating temperature of a solar cavity-receiver, Sol. Energy. 50 (1993) 1925.CrossRefGoogle Scholar
Perez-Enciso, R., Gallo, A., Riveros-Rosas, D., Fuentealba-Vidal, E., Perez-Rábago, C., A simple method to achieve a uniform flux distribution in a multi-faceted point focus concentrator, Renew. Energy. 93 (2016) 115124.CrossRefGoogle Scholar
He, Y.L., Wang, K., Qiu, Y., Du, B.C., Liang, Q., Du, S., Review of the solar flux distribution in concentrated solar power: Non-uniform features, challenges, and solutions, Elsevier Ltd, 2019.Google Scholar
Yang, S., Wang, J., Lund, P.D., Jiang, C., Liu, D., Assessing the impact of optical errors in a novel 2-stage dish concentrator using Monte-Carlo ray-tracing simulation, Renew. Energy. 123 (2018) 603615.CrossRefGoogle Scholar
Soltani, S., Bonyadi, M., Madadi Avargani, V., A novel optical-thermal modeling of a parabolic dish collector with a helically baffled cylindrical cavity receiver, Energy. 168 (2019) 8898.CrossRefGoogle Scholar
Qiu, K., Yan, L., Ni, M., Wang, C., Xiao, G., Luo, Z., Cen, K., Simulation and experimental study of an air tube-cavity solar receiver, Energy Convers. Manag. 103 (2015) 847858.CrossRefGoogle Scholar
Perez-Enciso, R., Caracterización óptica y térmica del horno solar del IER, Universidad Nacional Autonoma de México, 2015. https://repositorio.unam.mx/contenidos/caracterizacion-optica-y-termica-del-horno-solar-del-ier-87167?c=BDEwPD&d=false&q=*:*&i=1&v=1&t=search_0&as=0.Google Scholar
Xia, X.L., Dai, G.L., Shuai, Y., Experimental and numerical investigation on solar concentrating characteristics of a sixteen-dish concentrator, Int. J. Hydrogen Energy. 37 (2012) 1869418703.CrossRefGoogle Scholar
Shuai, Y., Xia, X., Tan, H., Numerical simulation and experiment research of radiation performance in a dish solar collector system, Front. Energy Power Eng. China. 4 (2010) 488495.CrossRefGoogle Scholar
Johnston, G., Focal region measurements of the 20 m2 tiled dish at the Australian National University, Sol. Energy. 63 (1998) 117124.CrossRefGoogle Scholar
Jaramillo, O.A., Pérez-Rábago, C.A., Arancibia-Bulnes, C.A., Estrada, C.A., A flat-plate calorimeter for concentrated solar flux evaluation, Renew. Energy. 33 (2008) 23222328.CrossRefGoogle Scholar
Dähler, F., Wild, M., Schäppi, R., Haueter, P., Cooper, T., Good, P., Larrea, C., Schmitz, M., Furler, P., Steinfeld, A., Optical design and experimental characterization of a solar concentrating dish system for fuel production via thermochemical redox cycles, Sol. Energy. 170 (2018) 568575.10.1016/j.solener.2018.05.085CrossRefGoogle Scholar
Yu, T., Yuan, Q., Lu, J., Ding, J., Lu, Y., Thermochemical storage performances of methane reforming with carbon dioxide in tubular and semi-cavity reactors heated by a solar dish system, Appl. Energy. 185 (2017) 1994–2004.CrossRefGoogle Scholar
Coughenour, B.M., Stalcup, T., Wheelwright, B., Geary, A., Hammer, K., Angel, R., Dish-based high concentration PV system with Köhler optics, Opt. Express. 22 (2014) A211.CrossRefGoogle ScholarPubMed