微塑料对流过电珀罗酮工艺的影响:计算流体动力学模拟

IF 4.8 Q1 ENVIRONMENTAL SCIENCES ACS ES&T water Pub Date : 2024-08-01 DOI:10.1021/acsestwater.4c0007910.1021/acsestwater.4c00079
Jingjing Yao*, Dong-Sheng Li, Jianbei Qiu, Xuhui Xu, Haipu Li* and Hui Ying Yang*, 
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引用次数: 0

摘要

目前有关高级氧化工艺的研究通常侧重于去除单个有机污染物,有时会忽略微塑料 (MP) 对传质的影响。通过实验测量进行实时、精确的监测具有挑战性。在本研究中,我们使用计算流体动力学模拟来研究 MPs 对流过式电过氧化物酮工艺中传质的影响。我们的研究结果表明,MPs 降低了电化学阴极/溶液界面上羟基自由基的浓度。然而,MPs 对入口气相中的 O3 和电化学阴极表面的过氧化氢的浓度和扩散途径没有明显影响。此外,MPs 的平均粒径从 135.0 μm 增加到 750.0 μm,数量从 7474 个/L 增加到 10,924 个/L。与此同时,平均湍流动能和湍流耗散率分别增加了 0.027 和 0.018 km2/s2,以及 0.041 和 0.702 m2/s3。这些变化表明,MPs 的增大和数量的增加阻碍了液体流动,降低了气态 O3 转化为水态 O3 的效率。因此,这降低了电过氧化物酮工艺中污染物的去除效率。这些见解对于开发同时去除 MPs 和污染物的更高效的高级氧化工艺至关重要。
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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Effect of Microplastics on the Flow-Through Electro-Peroxone Process: A Computational Fluid Dynamics Simulation

Current research on advanced oxidation processes often focuses on removing individual organic contaminants, sometimes overlooking the impact of microplastics (MPs) on mass transfer. Real-time and precise monitoring through experimental measurements is challenging. In this study, we used computational fluid dynamics simulations to examine the effect of MPs on mass transfer in a flow-through electro-peroxone process. Our findings revealed that MPs decreased the concentration of hydroxyl radicals at the electrochemical cathode/solution interface. However, there was no significant impact on the concentrations and diffusion pathways of O3 in the inlet gas phase and hydrogen peroxide on the electrochemical cathode surface. Additionally, the average size of MPs increased from 135.0 to 750.0 μm, and their count rose from 7474 to 10,924 particles/L. This was accompanied by increases in average turbulent kinetic energy and turbulent dissipation rate by 0.027 and 0.018 km2/s2, and 0.041 and 0.702 m2/s3, respectively. These changes suggested that the enlargement and increased count of MPs hindered liquid flow, reducing the efficiency of converting gaseous O3 to aqueous O3. Consequently, this diminished the removal efficiency of pollutants in the electro-peroxone process. These insights are crucial for developing more efficient advanced oxidation processes for the simultaneous removal of MPs and pollutants.

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