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

Q2 Engineering Drinking Water Engineering and Science Pub Date : 2014-06-03 DOI:10.5194/DWES-7-41-2014

A. El‐Kalliny, Sara F. Ahmed, L. Rietveld, P. Appel

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引用次数: 24

Abstract

An immobilized TiO2 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 TiO2 coating films a better homogeneity and adhesion, fewer cracks, and a higher qOH 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.

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固定化光催化剂上的不锈钢编织网，确保有效的光分配在太阳能反应器

在不锈钢编织网上制备了一种具有高比表面积的固定化TiO2光催化剂，用于水的分层包装净化。如此复杂形状的固定需要一种特殊的涂层技术。为此，采用了浸涂和电泳沉积(EPD)技术。与浸镀相比，EPD技术使TiO2涂层具有更好的均匀性和附着力，更少的裂纹和更高的qOH生成率。层叠的编织网结构保证了水处理反应器的高效透光。一个简单的方程模型被用来描述光在吸收介质(例如，带腐植酸的有色水)存在的情况下通过网格层的分布。最多3或4个涂层网足以收获300 nm至400 nm的太阳紫外线，穿透效率高。网层之间的距离对太阳光线穿透涂层网层的效率起着重要的作用，特别是当有色水被高浓度腐植酸污染时。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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