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煤矿废弃物特性及除氟性能。

Coal mine waste characterization and defluoridation property.

作者信息

Behera Bidyutprava, Sahu Himanshu Bhushan

机构信息

Department of Mining Engineering, NIT, Rourkela, India.

出版信息

Heliyon. 2023 Jan 26;9(2):e13244. doi: 10.1016/j.heliyon.2023.e13244. eCollection 2023 Feb.

DOI:10.1016/j.heliyon.2023.e13244
PMID:36798783
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9925952/
Abstract

Fluoride contamination has been addressed as a major problem worldwide, along with the scarcity of water. This attracts researchers to do more research in the field of fluoride contamination and mitigation of high fluoride content in water. There are various studies, that used a variety of adsorbents for the removal of fluoride from contaminated water. But none of them utilized the vast number of waste, that is generated from the coal mining industries. In this paper, Shale, which is a common coal mine waste, has been used as an adsorbent for fluoride removal from aqueous solution. Along with the defluoridation property of shale, the effect of weathering on the adsorption property of shale was also analyzed using different characterization tests, such as XRD (X-ray powder diffraction), SEM (Scanning Electron Microscope), and FTIR (Fourier Transform Infrared spectroscopy). Two types of shale samples were collected, crushed, and used in the adsorption process in the lab using synthetic fluoride solution. The maximum efficiency of type I () shale was obtained as 47.05% compared to type II () shale as 40.02% for 3 ppm initial fluoride solution for 60 min of contact time in pH range 5-7 using batch adsorption process. Other parameters such as shale particle size, pH, and total suspended solid present before and after the adsorption process were also taken into consideration. The adsorption followed pseudo-second kinetics and Freundlich isotherm with an adsorption capacity of 23.66 mg/g, and 21.33 mg/g for weathered and fresh shale respectively. The characterization test showed more clayey content in the weathered shale compared to fresh shale, making it more porous and suitable as a fluoride adsorbent. XRD showed the F containing minerals such as Villiaumite (5.1%) and Fluorite (4.3%) in F loaded weathered shale, confirming the F adsorption onto the shale surface. The major advantage of shale over other existing adsorbents is, it removes the fluoride without significant change in pH, and there are no or very less suspended ions that can be found in treated water. This means the water may not need any secondary treatment after the adsorption process. Shale is a very common and readily available mine waste, that is used for the ceramic industry, building materials, and road construction, making it a no-cost material to be used as an adsorbent for fluoride removal.

摘要

氟污染与水资源短缺一样,已成为全球范围内的一个主要问题。这吸引了研究人员在氟污染及降低水中高氟含量领域开展更多研究。有各种研究使用了多种吸附剂来去除受污染水中的氟。但它们都未利用煤炭开采行业产生的大量废弃物。在本文中,页岩这种常见的煤矿废弃物被用作从水溶液中去除氟的吸附剂。除了页岩的除氟性能外,还通过不同的表征测试,如XRD(X射线粉末衍射)、SEM(扫描电子显微镜)和FTIR(傅里叶变换红外光谱),分析了风化对页岩吸附性能的影响。收集了两种类型的页岩样本,进行粉碎,并在实验室中使用合成氟溶液用于吸附过程。在pH值为5 - 7、接触时间为60分钟、初始氟溶液浓度为3 ppm的条件下,采用间歇吸附法,I型()页岩的最大去除效率为47.05%,而II型()页岩为40.02%。吸附过程前后的其他参数,如页岩粒径、pH值和总悬浮固体也都被考虑在内。吸附过程遵循准二级动力学和弗伦德利希等温线,风化页岩和新鲜页岩的吸附容量分别为23.66 mg/g和21.33 mg/g。表征测试表明,与新鲜页岩相比,风化页岩中的黏土含量更高,使其孔隙更多,更适合作为氟吸附剂。XRD显示在负载氟的风化页岩中含有诸如氟石(5.1%)和萤石(4.3%)等含氟矿物,证实了氟吸附在页岩表面。页岩相对于其他现有吸附剂的主要优势在于,它在去除氟时pH值没有显著变化,并且处理后的水中不存在或仅有极少的悬浮离子。这意味着吸附过程后水可能无需任何二次处理。页岩是一种非常常见且容易获得的煤矿废弃物,用于陶瓷工业、建筑材料和道路建设,使其成为一种无需成本的氟去除吸附剂材料。

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