Integrated Process for High Phenol Removal from Wastewater Employing a ZnO Nanocatalyst in an Ozonation Reaction in a Packed Bubble Column Reactor

IF 2.8 Q2 ENGINEERING, CHEMICAL ChemEngineering Pub Date : 2023-11-28 DOI:10.3390/chemengineering7060112
Adnan K. Majhool, Khalid A. Sukkar, M. Alsaffar, H. S. Majdi
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Abstract

The use of an ozonized bubble column reactor (OBCR) in wastewater treatment is advantageous due to its efficient mixing and mass transfer characteristics. Among all high-performance features, the ozonation reaction in a BCR undergoes a low dissolution of O3 in the reactor with a limited reaction rate. In this study, the ozonation reaction of phenol in an OBCR was tested using a ZnO nanocatalyst and alumina balls as packing material. Three concentrations of O3 were evaluated (i.e., 10, 15, and 20 ppm), and 20 ppm was found to be the optimum concentration for phenol degradation. Also, two doses (i.e., 0.05 and 0.1 g/L) of ZnO nanocatalysts were applied in the reaction mixture, with the optimal dose found to be 0.1 g/L. Accordingly, three phenol concentrations were investigated in the OBCR (i.e., 15, 20, and 25 ppm) using four treatment methods (i.e., O3 alone, O3/Al2O3, O3/ZnO nanocatalyst, and O3/Al2O3/ZnO nanocatalyst). At a contact time of 60 min and phenol concentration of 15 ppm, the removal rate was 66.2, 73.1, 74.5, and 86.8% for each treatment method, respectively. The treatment experiment that applied the O3/Al2O3/ZnO nanocatalyst produced the highest phenol conversion into CO2 and H2O in the shortest contact time for all phenol concentrations. Thus, the OBCR employed with a ZnO nanocatalyst plus packing material is a promising technology for the rapid and active removal of phenol because it enhances the number of hydroxyl radicals (•OH) generated, which ultimately increases the oxidation activity in the OBCR. Also, the results showed efficient flow characteristics in the OBCR, with channeling problems averted due to appropriate gas movement resulting from the use of packing materials. Finally, it was found that the ozonation process in an OBCR is an efficient method for phenol conversion with good economic feasibility.
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在填料泡柱反应器中的臭氧反应中使用氧化锌纳米催化剂的废水苯酚高去除率综合工艺
在废水处理中使用臭氧气泡塔反应器(OBCR)具有高效的混合和传质特性。在所有高性能特点中,BCR 中的臭氧反应在反应器中的 O3 溶解度较低,反应速率有限。本研究使用 ZnO 纳米催化剂和氧化铝球作为填料,测试了 OBCR 中苯酚的臭氧反应。评估了三种浓度的 O3(即 10、15 和 20 ppm),发现 20 ppm 是苯酚降解的最佳浓度。此外,在反应混合物中使用了两种剂量(即 0.05 和 0.1 g/L)的纳米氧化锌催化剂,发现最佳剂量为 0.1 g/L。因此,使用四种处理方法(即单独使用 O3、O3/Al2O3、O3/ZnO 纳米催化剂和 O3/Al2O3/ZnO 纳米催化剂)研究了 OBCR 中的三种苯酚浓度(即 15、20 和 25 ppm)。在接触时间为 60 分钟、苯酚浓度为 15 ppm 的条件下,每种处理方法的去除率分别为 66.2%、73.1%、74.5% 和 86.8%。在所有苯酚浓度下,使用 O3/Al2O3/ZnO 纳米催化剂的处理实验在最短的接触时间内将苯酚转化为 CO2 和 H2O 的转化率最高。因此,使用 ZnO 纳米催化剂加填料的 OBCR 是一种快速、有效去除苯酚的可行技术,因为它能增加产生的羟基自由基(-OH)的数量,最终提高 OBCR 的氧化活性。此外,研究结果还显示了 OBCR 中的高效流动特性,由于使用了填料,气体运动适当,从而避免了通道问题。最后,研究发现 OBCR 中的臭氧氧化工艺是一种高效的苯酚转化方法,具有良好的经济可行性。
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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来源期刊
ChemEngineering
ChemEngineering Engineering-Engineering (all)
CiteScore
4.00
自引率
4.00%
发文量
88
审稿时长
11 weeks
期刊最新文献
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