Impact of coagulant type and magnetic ion exchange (MIEX) pre-treatment on floc strength and structure at the Kluizen Water Treatment Plant, Belgium

Ethiopian Journal of Water Science and Technology Pub Date : 2019-12-21 DOI:10.59122/13401d4

Gizeshwork Tadesse Gurmu, A. Verliefde

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Abstract

Drinking water supplied to the community should be free from Disinfection ByProducts (DPB). DPB occurs when organic matter is present in surface water and reacts with chlorine. Conventional coagulation and flocculation processes have been used in water treatment plants to remove organic matters from raw water. Recently, Magnetic Ion Exchange (MIEX) followed by coagulation and flocculation has started to attract attention since it improves natural organic matter removal and decreases coagulant demand. The efficiency of NOM removal and downstream processes not only depends on the prior removal process of organic matter but also on the structure , size and strength of flocs formed in the coagulation process as well. This study aims at comparing (1) floc structures (i.e. floc sizes, floc strength, and fractal dimensions) generated from coagulation of raw water and (2) water pre-treated with magnetic ion exchange obtained from Kluizen water treatment plant (Kluizen, East-Flanders, Belgium). The floc sizes during growth, breakage and re-growth were measured using (laser) light scattering (Malvern Mastersizer 2000), coupled with jar test equipment. The strength of flocs was evaluated by empirically relating the floc size to the increased shear rate applied. The results show that pre-treated water coagulated with all the coagulants produces flocs with larger sizes compared to the flocs generated from raw water. For both water types, FeCl3 gave better recoverability after breakage than PACl and AlCl3. After pre-treatment, the floc size was increased by 19%, 63% and 64% forthe coagulants such as PACl, AlCl3, and FeCl3, respectively. Coagulation process with PACl generated flocs with higher fractal dimension and lower strength constants which indicates that flocs generated is strong and compacted micro-flocs. The floc size measurement techniques and coagulation system were found to have an impact on the resulting floc sizes.

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混凝剂类型和磁离子交换(MIEX)预处理对比利时Kluizen水处理厂絮凝体强度和结构的影响

提供给社区的饮用水应不含消毒副产物。当有机物质存在于地表水中并与氯反应时，DPB就会发生。传统的混凝和絮凝工艺已在水处理厂用于去除原水中的有机物。近年来，磁离子交换(Magnetic Ion Exchange, MIEX)技术以提高天然有机物的去除效率和减少混凝剂的用量而引起了人们的关注。去除率和下游工艺的效率不仅取决于前一阶段有机物的去除率，还取决于混凝过程中形成的絮凝体的结构、大小和强度。本研究旨在比较(1)原水混凝产生的絮凝体结构(即絮凝体大小、絮凝体强度和分形维数)和(2)Kluizen水处理厂(Kluizen, East-Flanders，比利时)经磁离子交换预处理的水。利用(激光)光散射(Malvern Mastersizer 2000)，结合玻璃罐测试设备，测量了生长、破碎和再生长过程中的絮凝体尺寸。通过经验将絮凝体的大小与施加的剪切速率增加联系起来，来评估絮凝体的强度。结果表明，与原水相比，经所有混凝剂混凝的预处理水产生的絮凝体尺寸更大。对于两种水类型，FeCl3在破裂后的恢复能力都优于PACl和AlCl3。混凝剂PACl、AlCl3和FeCl3预处理后，絮凝体粒径分别提高19%、63%和64%。PACl混凝过程生成的絮凝体具有较高的分形维数和较低的强度常数，表明生成的絮凝体是强而致密的微絮凝体。发现絮凝体粒径测量技术和絮凝系统对所得絮凝体粒径有影响。

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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Ethiopian Journal of Water Science and Technology

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