Modification of bentonite with black cotton soil and carboxyl methyl cellulose for the enhancement of hydraulic performance of geosynthetic clay liners

Water Science & Technology Pub Date : 2024-03-25 DOI:10.2166/wst.2024.093

S. Syed Masoodhu, N. Natarajan, M. Vasudevan

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Abstract

Geosynthetic clay liners (GCLs) are mostly used as flow barriers in landfills and waste containments due to their low hydraulic conductivity to prevent the leachate from reaching the environment. The self-healing and swell-shrink properties of soft clays (expansive soils) such as bentonite enable them as promising materials for the GCL core layers. However, it is important to modify their physico-chemical properties in order to overcome the functional limitations of GCL under different hydraulic conditions. In the present study, locally available black cotton soil (BCS) is introduced in the presence of an anionic polymer named carboxymethyl cellulose (CMC) as an alternative to bentonite to enhance the hydraulic properties of GCL under different compositions. The modified GCL is prepared by stitching the liner with an optimum percentage of CMC along with various percentages of BCS mixed with bentonite. Hydraulic conductivity tests were performed on the modified GCL using the flexi-wall permeameter. The results suggest that the lowest hydraulic conductivity of 4.58 × 10−10 m/s is obtained when 25% of BCS is blended with bentonite and an optimum 8% CMC and further addition of BCS results in the reduction of the hydraulic conductivity.

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用黑棉土和羧甲基纤维素改性膨润土以提高土工合成粘土衬里的水力性能

土工合成粘土衬里（GCL）因其导水性低，可防止渗滤液进入环境，因此大多被用作垃圾填埋场和废物容器的阻流层。膨润土等软粘土（膨胀土）具有自愈合和膨胀收缩特性，因此很有希望成为 GCL 核心层的材料。然而，重要的是要改变它们的物理化学特性，以克服 GCL 在不同水力条件下的功能限制。在本研究中，当地可用的黑棉土（BCS）被引入到名为羧甲基纤维素（CMC）的阴离子聚合物中，作为膨润土的替代品，以提高 GCL 在不同成分下的水力特性。改性 GCL 的制备方法是将最佳比例的 CMC 与不同比例的 BCS 和膨润土混合，缝合衬垫。使用柔性壁渗透仪对改性 GCL 进行了水力传导测试。结果表明，当 25% 的 BCS 与膨润土和最佳 8% 的 CMC 混合时，水力传导率最低，为 4.58 × 10-10 m/s。

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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Water Science & Technology

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