Clay Minerals Effects for Metal Reclamation from Leached Solution

Clay and Clay Minerals [Working Title] Pub Date : 2021-09-19 DOI:10.5772/intechopen.98368

Murugesan Manikkampatti Palanisamy, Akilamudhan Palaniappan, V. Myneni, K. Kandasamy, Minar Mohamed Lebbai, Padmapriya Veerappan

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Abstract

The recent advancements in technology play a pivotal role in mankind’s life and have a significant stint in the generation of E-waste. The present investigation focuses on the recovery of heavy metals from Printed Circuit boards (PCBs) by applying two efficient techniques viz., leaching and adsorption. A combination of leaching and adsorption is a novel and productive approach to recovering heavy metals from like PCBs. After the phases of chemical leaching, the solution was recovered through adsorption and is eco-friendly. The process is carried out to increase the separation rate, reduce the time spent and reach the limits of incineration and pyrolysis methods. Adsorption provides the recovery of heavy metals with respect to the required adsorbent since it is a surface phenomenon. The optimum condition of process variables was found through response surface methodology (RSM). The maximum recovery of copper ions (97.33%) was obtained at the optimum operating conditions such as adsorbent size of 0.04 mm, adsorbent dosage of 3.5 gm L−1 and the temperature of 80°C with 0.845 desirability. This investigation was found to be an eco-friendly way to recover copper ions and does not cause any environmental issues.

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粘土矿物对浸出液金属回收的影响

最近技术的进步在人类的生活中起着举足轻重的作用，在电子垃圾的产生方面有很大的限制。本文研究了采用浸出和吸附两种高效技术回收印刷电路板中的重金属。浸出和吸附相结合是一种从多氯联苯中回收重金属的新颖而高效的方法。经化学浸出后，溶液经吸附回收，环保。该工艺的实施是为了提高分离率，减少时间，达到焚烧和热解方法的极限。由于吸附是一种表面现象，因此提供了相对于所需吸附剂的重金属回收。通过响应面法(RSM)找到了工艺变量的最佳条件。在吸附剂粒径为0.04 mm、吸附剂用量为3.5 gm L−1、吸附剂温度为80℃、理想度为0.845的条件下，铜离子的最大回收率为97.33%。研究结果表明，该方法是回收铜离子的环保方法，不会产生任何环境问题。

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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Clay and Clay Minerals [Working Title]

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