Measurement of degradation of solar panels induced by damp heat-Reference-Cited by-同舟云学术

Measurement of degradation of solar panels induced by damp heat

Published:2022-12-31 Issue: Volume: Page:24-28
ISSN:2523-6881
Container-title:Revista de Energías Renovables
language:en
Short-container-title:JRE

Author:

Salazar-Peralta Araceli¹^ORCID,Pichardo-Salazar José Alfredo²^ORCID,Pichardo-Salazar Ulises³^ORCID,Chávez Rosa Hilda⁴^ORCID

Affiliation:

1. Tecnológico de Estudios Superiores de Jocotitlán

2. Centro de Bachillerato Tecnológico Industrial y de Servicios No. 161

3. Centro de Estudios Tecnológicos Industrial y de Servicios No. 23

4. Instituto Nacional de Investigaciones Nucleares

Abstract

Currently the generation of electricity is carried out, mainly, from the combustion of fossil fuels; which contributes to the emission of pollutants such as SOx, NOx, CO, PM10, PM2.5 and volatile organic compounds (VOC) that affect air quality. Solar energy is an alternative for the generation of clean energy through the use of solar panels, which convert the energy they receive from sunlight into electrical energy for human use. It is cheaper and more viable, since the sun is readily available. Solar panels are built from an element called silicon, which is involved in the process of creating electrical energy. The objective of this study was to characterize the resistance to degradation of solar panels exposed to the damp heat test using the IEC 61646 Standard. The results obtained contribute to the quality assurance of the solar panel manufacturing process, which is of vital importance. and knowledge of their useful life.

Publisher

ECORFAN

Subject

General Earth and Planetary Sciences,General Environmental Science

Reference12 articles.

1. [I] Gabor A., Ralli M., Montminy S., Alegria L., Bordonaro C., Woods J., Felton L. (2006),” Soldering induced damage to thin Si solar cells and detection of cracked cells in modules,´´ Proceedings of the 21st EUPVSEC, Dresden, Ger-many, pp. 2042– 2047.

2. [II] Schneider A., Pander,M. Korvenkangas T., Aulehla S., Harney R., Hort-tana T. , (2014), ”Cell to Module Loss Reduction and Module Reliability Enhance-ments by Solder Ribbon Optimization,´´ Proceedings of the 29th EUPVSEC, Amsterdam, Netherlands, pp. 165-170.

3. [III] Kunze I., Kajari-Schröder S., Breitenmoser X., Bjørneklett B (2011)., Quantifying the risk of power loss in PV modules due to micro cracks,´´ Solar Energy Materials and Solar Cells 95, , pp. 1131-1137.

4. [IV] Halm A., Mihailetchi V., Galbiati G., Koduvelikulathu L., Roescu R., Comparotto C., Kopecek R., Peter K., Libal J (2012)., ”The Zebra cell concept - large area n-type interdigitated back contact solar cells and one-cell modules fabricated using standard industrial processing equipment,´´ Proceedings of the 27th EUPVSEC, Frankfurt am Main, Germany, , pp. 567-570.

5. [V] Sander M., Dietrich S., Pander M., Ebert M., Karraß M., Lippmann R., Broddack M. and Wald D (2013)., ”Influence of manufacturing processes and sub-sequent weathering on the occurrence of cell cracks in PV modules,´´ Pro-ceedings of the 28th EUPVSEC, Paris, France, , pp. 3275-3279.