应用电凝技术和响应面法建立头孢氨苄抗生素可持续去污系统

Maliheh Arab, S. Danesh
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引用次数: 0

摘要

由于生活和工业用途,废水中出现了合成微污染物,这给处理工艺带来了新的挑战。在这些污染物中,药品和个人护理产品被认为是新出现的污染物,因为它们有可能进入饮用水源。尤其是抗生素,由于其在兽医和人类应用中的高消耗量,引起了人们的极大关注。在本研究中,电絮凝(EC)工艺是一种从制药废水中去除头孢氨苄(CFX)的有效技术。本研究旨在探索EC工艺去除CFX的能力,并使用基于中央复合材料设计(RSM-CCD)的响应面方法优化其性能。在优化过程中考虑了初始CFX浓度、电解时间、初始pH和电极类型(非绝缘和绝缘)的影响。这项研究与众不同,因为它考察了关键因素对消除CFX的影响。结果表明,电解时间对EC工艺去除CFX的效果最为显著。方差分析(ANOVA)检验用于评估自变量的重要性及其相互作用。最大去除效率(86.53%)的最佳操作条件是头孢氨苄的初始浓度、反应时间和34的初始pH mg/L,34.35 min和6.5。在这些最佳条件下,预测的头孢氨苄去除率为93.54%。这些发现表明,RSM-CCD是优化废水中CFX等微污染物电化学去除工艺的有用工具。该研究强调了在优化EC工艺去除废水中微量污染物时考虑电极类型的重要性。
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A sustainable system for decontamination of cephalexin antibiotic using electrocoagulation technology and response surface methodology
The emergence of synthetic micropollutants in wastewater due to domestic and industrial use has presented new challenges for treatment processes. Among these pollutants, pharmaceutical and personal care products (PPCPs) are considered emerging contaminants due to their potential to enter drinking water sources. Antibiotics, in particular, are of significant concern due to their high consumption in veterinary and human applications. In this study, the electrocoagulation (EC) process is used as an efficient technique for the removal of cephalexin (CFX) from pharmaceutical wastewater. The study aims to explore the ability of the EC process to remove CFX and optimize its performance using the response surface method based on Central Composite Design (RSM‐CCD). The effects of initial CFX concentration, electrolysis time, initial pH, and electrode type (non‐insulated and insulated) were considered in the optimization process. This research is distinct as it examines the influence of key factors on the elimination of CFX. The results showed that electrolysis time had the most significant effect on CFX removal using the EC process. The analysis of variance (ANOVA) test was used to evaluate the importance of independent variables and their interaction. The optimal operating conditions for maximum removal efficiency (86.53%) were an initial cephalexin concentration, reaction time, and initial pH of 34 mg/L, 34.35 min, and 6.5, respectively, using an insulated electrode. Under these optimal conditions, predicted cephalexin removal was 93.54%. These findings demonstrate that RSM‐CCD is a useful tool for optimizing electrochemical removal processes for micropollutants such as CFX from wastewater streams. The study highlights the importance of considering electrode type in optimizing EC processes for micropollutant removal from wastewater.
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CiteScore
3.50
自引率
21.10%
发文量
37
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