Cooling solar panels using saturated activated alumina with saline water: Experimental study
solar energy • 2020
Publication Information
Authors
Saber Abdo, Hind Saidani-Scott, Bernardo Borges, and M. A. Abdelrahman
Keywords
Solar panels
Cooling
Activated alumina
Saturated
Seawater
Salinity
Journal
solar energy
Publisher
Not Available
Volume
208
Issue
Not Available
Pages
345–356
publication.type
International
Paper Link
Not Available
Supplementary Materials
Not Available
Abstract
This paper is one of the first to propose seawater for cooling PV panels. It presents and describes a novel
experimental investigation for cooling solar panels using saturated activated alumina with saline water. Six
different water salinities of (0, 5, 10, 35, 80, and 337) particles per thousands (PPT) saltwater were used at
different radiation intensities. Additionally, new internal and external configuration of materials’ containers are
suggested. Two radiation intensities of 800 W/m2 and 1000 W/m2 were selected and applied for the complete
test period of 6 h. Experiments were repeated for a periodic cycle of four months to monitor the salt effect on the
activated alumina tablets; This was done by using an optical microscope to look at the microscopical state.
Results showed that saturated activated alumina tablets with saline water gives the same cooling performance as
using pure water. At salinities higher than 35 PPT, the tablets depreciation rate and porosity increase, hence
limiting the usability to systems with salinities less than 35 PPT. The proposed modifications for the internal and
external configuration enhanced the cooling effect of the system by (3–4) ◦C, compared with the old
configurations.
experimental investigation for cooling solar panels using saturated activated alumina with saline water. Six
different water salinities of (0, 5, 10, 35, 80, and 337) particles per thousands (PPT) saltwater were used at
different radiation intensities. Additionally, new internal and external configuration of materials’ containers are
suggested. Two radiation intensities of 800 W/m2 and 1000 W/m2 were selected and applied for the complete
test period of 6 h. Experiments were repeated for a periodic cycle of four months to monitor the salt effect on the
activated alumina tablets; This was done by using an optical microscope to look at the microscopical state.
Results showed that saturated activated alumina tablets with saline water gives the same cooling performance as
using pure water. At salinities higher than 35 PPT, the tablets depreciation rate and porosity increase, hence
limiting the usability to systems with salinities less than 35 PPT. The proposed modifications for the internal and
external configuration enhanced the cooling effect of the system by (3–4) ◦C, compared with the old
configurations.
Staff Members - Benha University