Characterization of Photovoltaic Solar Energy using Muneer Aniso Tropic Model
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Published:
Jan 27, 2021
Keywords:
Anisotropic models, Diffuse, Incident radiation, Photovoltaic effects, Solar energy
Main Article Content
Abstract
In this article, the solar resource is evaluated in order to determine its characterization using Muneer's anisotropic model. A conceptual analysis of the diffuse irradiance of the sky is also carried out, as well as an analysis of the model since a distinction is made between shaded and unshaded surfaces and, within the latter, between covered or clear skies. A mathematical model was carried out that based on the aforementioned model, the characterization of the solar resource was carried out, which is focused on the production of electrical energy. If you defined the parameters to be considered in the model, you will proceed to model it using Matlab with measurements of solar radiation taken from the Universidad Politécnica Salesiana.
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How to Cite
Tipán , L. ., & De La Torre, E. (2021). Characterization of Photovoltaic Solar Energy using Muneer Aniso Tropic Model. Revista Técnica "energía", 17(2), PP. 65–73. https://doi.org/10.37116/revistaenergia.v17.n2.2021.423
Section
EFICIENCIA ENERGÉTICA
Aviso de Derechos de Autor
La Revista Técnica "energía" está bajo licencia internacional Creative Commons Reconocimiento-NoComercial 4.0.
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[5] Z. Li, H. Xing, S. Zeng, J. Zhao, and T. Wang, “Comparison of Anisotropic Diffuse Sky Radiance Models for Irradiance Estimation on Building Facades,” Procedia Eng., vol. 205, pp. 779–786, 2017, doi: 10.1016/j.proeng.2017.10.010.
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[7] S. M. Ivanova, “Estimation of background diffuse irradiance on orthogonal surfaces under partially obstructed anisotropic sky: Part II - Horizontal surfaces,” Sol. Energy, vol. 100, pp. 234–250, Feb. 2014, doi: 10.1016/j.solener.2013.12.010.
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[11] M. Nfaoui and K. El-Hami, “Extracting the maximum energy from solar panels,” Energy Reports, vol. 4, pp. 536–545, 2018, doi: 10.1016/j.egyr.2018.05.002.
[12] S. P. Sukhatme and J. K. Nayak, “Solar Energy : Principles of Thermal Collection and Storage.” p. 425, 2008.
[13] I. MONAR, “Diseño de una instalación fotovoltaica optimizando el ángulo de inclinación de los paneles solares,” Guayaquil- ecuador, 2015.
[14] J. de la Cruz, A. de la Cruz, and R. Úbeda, "Guía en de mantenimiento instalaciones fotovoltaicas", Ediciones. Barcelona: ProQuest Ebook Central, 2009.
[15] H. P. M. Palaguachi and C. V. P. Guiracocha, “Simulación del perfil tensión – corriente para paneles solares mediante convertidor cc-cc reductor,” Cuenca-Ecuador, 2017.
[16] B. Khatherine and M. Valdiviezo, “Algoritmo de detección de puntos calientes en paneles fotovoltaicos,” 2018.
[17] M. Sánchez, “Desarrollo de una herramienta para el modelado del comportamiento eléctrico de células solares,” 2019.
[18] X. Jian and Z. Weng, “A logistic chaotic jaya algorithm for parameters identification of photovoltaic cell and module models,” Optik (Stuttg)., vol. 203, p. 164041, Feb. 2020, doi: 10.1016/j.ijleo.2019.164041.
[19] J. Cata and F. Rodríguez, “Análisis matemático de un panel solar fotovoltaico de silicio,” p. 98, 2015.
[20] R. L. B. Louis, N. Boylestad, N. Décima, and E. Décima Edición, "Electrónica:Teoría de circuitos y dispositivos electrónicos". 2009.
[21] E. Granda, J. Diaz, M. Jiménez, M. Osorio, and M. Gonzalo, “Modelado y simulación de celdas y paneles solares.” Chihuahua, 2013, doi: 10.13140/2.1.4192.8968.
