Brújula Home

Institutional repository of the Universidad Loyola

View Item 
  •   Brújula Home
  • PRODUCCIÓN CIENTÍFICA Y TRANSFERENCIA
  • Departamento Ingeniería
  • Artículos
  • View Item
  •   Brújula Home
  • PRODUCCIÓN CIENTÍFICA Y TRANSFERENCIA
  • Departamento Ingeniería
  • Artículos
  • View Item
    • español
    • English
JavaScript is disabled for your browser. Some features of this site may not work without it.

Browse

All of BrújulaCommunities and CollectionsAuthorsTitlesKeywordsAuthor profilesThis CollectionAuthorsTitlesKeywords

My Account

Login

Statistics

View Usage Statistics

Añadido Recientemente

Novedades
Repository
How to publish
Visibility
FAQs

Microstructural analysis of the PV module cementation process at the Solar Platform of the Atacama Desert

Author:
Olivares, Douglas; Ferrada, Pablo; Marzo, Aitor; Llanos, Jaime; Miranda-Ostojic, Carol; [et al.]
URI:
https://hdl.handle.net/20.500.12412/6906
ISSN:
0927-0248
DOI:
10.1016/j.solmat.2021.111109
Date:
2021-08
Keyword(s):

Soiling

Cementation

Photovoltaics

Desert areas

Mineral composition

Microstructural analysis

Particle size

Atmospheric parameters

Abstract:

The understanding of soiling processes on photovoltaic modules is a necessary step for the development of costeffective mitigation methods for the solar industry. This paper analyzes the soiling process for photovoltaic modules installed at the Atacama Desert. For this purpose, the dust deposited on photovoltaic modules and glasses (for one year) was characterized and the location’s atmospheric parameters were monitored continuously. The dust samples were separated according to difference in solubility, obtaining three samples: soluble (recrystallized), insoluble (filtered), and original. Through x-ray diffraction measurements it was detected that the soluble part corresponds to gypsum and the other dust components are insoluble or low-solubility salts such as albite, anhydrite, calcite, quartz, and orthoclase. Scanning electron microscopy and energy dispersive x-ray spectroscopy of the dust on photovoltaic glasses show the presence of gypsum with a monoclinic prismatic structure covered with smaller dust particles. These prismatic crystals are also observed after recrystallization of the soluble sample suggesting that gypsum, as a soluble hygroscopic material, has a key role in the cementation process. Atmospheric parameters of each season were characterized through wind velocity, temperature, and relative humidity. All these parameters show large daily oscillation, which trigger a cementation process in which gypsum crystallization, after being completely or partially solubilized, causes the encapsulation of insoluble material.

The understanding of soiling processes on photovoltaic modules is a necessary step for the development of costeffective mitigation methods for the solar industry. This paper analyzes the soiling process for photovoltaic modules installed at the Atacama Desert. For this purpose, the dust deposited on photovoltaic modules and glasses (for one year) was characterized and the location’s atmospheric parameters were monitored continuously. The dust samples were separated according to difference in solubility, obtaining three samples: soluble (recrystallized), insoluble (filtered), and original. Through x-ray diffraction measurements it was detected that the soluble part corresponds to gypsum and the other dust components are insoluble or low-solubility salts such as albite, anhydrite, calcite, quartz, and orthoclase. Scanning electron microscopy and energy dispersive x-ray spectroscopy of the dust on photovoltaic glasses show the presence of gypsum with a monoclinic prismatic structure covered with smaller dust particles. These prismatic crystals are also observed after recrystallization of the soluble sample suggesting that gypsum, as a soluble hygroscopic material, has a key role in the cementation process. Atmospheric parameters of each season were characterized through wind velocity, temperature, and relative humidity. All these parameters show large daily oscillation, which trigger a cementation process in which gypsum crystallization, after being completely or partially solubilized, causes the encapsulation of insoluble material.

Show full item record
Collections
  • Artículos
Files in this item
Thumbnail
Artículo principal" (5.271Mb)
Share
Export to Mendeley
Statistics
Usage statistics
Metrics and citations  
Go to Brújula home

Universidad Loyola

Library

Contact

Facebook Loyola BibliotecaTwitter Loyola Biblioteca

The content of the Repository is protected with a Creative Commons license:

Attribution-NonCommercial-NoDerivatives 4.0 Internacional

Creative Commons Image