Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor

Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor

An immobilized TiO<sub>2</sub> photocatalyst with a high specific surface area was prepared on stainless steel woven meshes in order to be used packed in layers for water purification. Immobilization of such a complex shape needs a special coating technique. For this purpose, dip coating...

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Main Authors: A. S. El-Kalliny, S. F. Ahmed, L. C. Rietveld, P. W. Appel
Format: Article
Language:English
Published: Copernicus Publications 2014-06-01
Series:Drinking Water Engineering and Science
Online Access:http://www.drink-water-eng-sci.net/7/41/2014/dwes-7-41-2014.pdf
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spelling doaj-57c8b602ea6c4709baf13f1cb8ed564b2021-02-02T04:08:03ZengCopernicus PublicationsDrinking Water Engineering and Science1996-94571996-94652014-06-0171415210.5194/dwes-7-41-2014Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactorA. S. El-Kalliny0S. F. Ahmed1L. C. Rietveld2P. W. Appel3Product and Process Engineering, ChemE, Delft University of Technology, Julianalaan 136, 2628 BL Delft, the NetherlandsProduct and Process Engineering, ChemE, Delft University of Technology, Julianalaan 136, 2628 BL Delft, the NetherlandsSanitary Engineering, Faculty of Civil Engineering and Geosciences, Delft University of Technology, Stevinweg 1, 2628 CN Delft, the NetherlandsProduct and Process Engineering, ChemE, Delft University of Technology, Julianalaan 136, 2628 BL Delft, the NetherlandsAn immobilized TiO<sub>2</sub> photocatalyst with a high specific surface area was prepared on stainless steel woven meshes in order to be used packed in layers for water purification. Immobilization of such a complex shape needs a special coating technique. For this purpose, dip coating and electrophoretic deposition (EPD) techniques were used. The EPD technique gave the TiO<sub>2</sub> coating films a better homogeneity and adhesion, fewer cracks, and a higher <sup>·</sup>OH formation than the dip coating technique. The woven mesh structure packed in layers guaranteed an efficient light-penetration in water treatment reactor. A simple equation model was used to describe the distribution of light through the mesh layers in the presence of absorbing medium (e.g., colored water with humic acids). Maximum three or four coated meshes were enough to harvest the solar UV light from 300 nm to 400 nm with a high penetration efficiency. The separation distance between the mesh layers played an important role in the efficiency of solar light penetration through the coated mesh layers, especially in case of colored water contaminated with high concentrations of humic acid.http://www.drink-water-eng-sci.net/7/41/2014/dwes-7-41-2014.pdf
collection DOAJ
language English
format Article
sources DOAJ
author A. S. El-Kalliny
S. F. Ahmed
L. C. Rietveld
P. W. Appel
spellingShingle A. S. El-Kalliny
S. F. Ahmed
L. C. Rietveld
P. W. Appel
Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor
Drinking Water Engineering and Science
author_facet A. S. El-Kalliny
S. F. Ahmed
L. C. Rietveld
P. W. Appel
author_sort A. S. El-Kalliny
title Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor
title_short Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor
title_full Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor
title_fullStr Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor
title_full_unstemmed Immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor
title_sort immobilized photocatalyst on stainless steel woven meshes assuring efficient light distribution in a solar reactor
publisher Copernicus Publications
series Drinking Water Engineering and Science
issn 1996-9457
1996-9465
publishDate 2014-06-01
description An immobilized TiO<sub>2</sub> photocatalyst with a high specific surface area was prepared on stainless steel woven meshes in order to be used packed in layers for water purification. Immobilization of such a complex shape needs a special coating technique. For this purpose, dip coating and electrophoretic deposition (EPD) techniques were used. The EPD technique gave the TiO<sub>2</sub> coating films a better homogeneity and adhesion, fewer cracks, and a higher <sup>·</sup>OH formation than the dip coating technique. The woven mesh structure packed in layers guaranteed an efficient light-penetration in water treatment reactor. A simple equation model was used to describe the distribution of light through the mesh layers in the presence of absorbing medium (e.g., colored water with humic acids). Maximum three or four coated meshes were enough to harvest the solar UV light from 300 nm to 400 nm with a high penetration efficiency. The separation distance between the mesh layers played an important role in the efficiency of solar light penetration through the coated mesh layers, especially in case of colored water contaminated with high concentrations of humic acid.
url http://www.drink-water-eng-sci.net/7/41/2014/dwes-7-41-2014.pdf
work_keys_str_mv AT aselkalliny immobilizedphotocatalystonstainlesssteelwovenmeshesassuringefficientlightdistributioninasolarreactor
AT sfahmed immobilizedphotocatalystonstainlesssteelwovenmeshesassuringefficientlightdistributioninasolarreactor
AT lcrietveld immobilizedphotocatalystonstainlesssteelwovenmeshesassuringefficientlightdistributioninasolarreactor
AT pwappel immobilizedphotocatalystonstainlesssteelwovenmeshesassuringefficientlightdistributioninasolarreactor
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