水动力空化对高级氧化过程和传质的影响:概念模型

IF 5.5 Q1 ENGINEERING, CHEMICAL
S.N. Fleite , M.A. Ayude , V.V. Ranade , M.C. Cassanello
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引用次数: 0

摘要

由于处理难处理废水的需要,高级氧化工艺(AOPs)技术成为人们热衷研究的课题。其中,流体动力空化(HC)的研究尤为深入,因为它具有作为 AOP 和其他工艺(包括其他 AOP)强化手段的潜力。了解 HC 及其影响对于 HC 的开发和实际应用至关重要。本研究介绍了一个概念模型,该模型结合了超临界水 (SCW) 的存在来解释碳氢化合物的结果。该模型通过选定的实验方案进行了验证,重点探索了碳氢化合物对可溶性聚合物溶液粘度的影响、不饱和溶液中离子盐的沉淀以及挥发性有机化合物(VOC)的剥离。使用概念模型对结果进行了分析和解释,并指出了无法用普遍接受的自由基形成或热解机制来解释的情况。此外,该模型还被用于分析现有文献中有关应用碳氢化合物作为 AOP 和强化方法的趋势。作为碳氢化合物化学和物理效应的关键驱动力,SCW 的出现代表了一种新方法,有可能增强碳氢化合物系统的设计和运行,特别是在调整操作条件以最大限度地提高 SCW 出现率时。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hydrodynamic cavitation effects on advanced oxidation processes and mass transfer: A conceptual model

Advanced oxidation process (AOPs) technologies are the subject of intense research due to the need for treating refractory wastewaters. Among them, hydrodynamic cavitation (HC) is particularly well-studied because of its potential as an AOP and as a means of intensification for other processes, including other AOPs. Understanding HC and its effects is crucial for its development and practical application. This study introduces a conceptual model that integrates the presence of supercritical water (SCW) to interpret HC results. The model was validated by selected experimental scenarios focused on exploring the impact of HC on the viscosity of a soluble polymer solution, the precipitation of an ionic salt from an unsaturated solution, and the stripping of volatile organic compounds (VOCs). The results were analyzed and interpreted using the conceptual model, remarking the scenarios that cannot be explained by the generally accepted mechanisms of radicals’ formation or pyrolysis. Furthermore, the model was then applied to analyze the trends reported in the existing literature regarding the application of HC as an AOP and as a method of intensification. The occurrence of SCW as a key driving force for HC chemical and physical effects represents a novel approach with the potential to enhance the design and operation of HC systems, particularly when tailoring operating conditions to maximize SCW occurrence.

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来源期刊
Chemical Engineering Journal Advances
Chemical Engineering Journal Advances Engineering-Industrial and Manufacturing Engineering
CiteScore
8.30
自引率
0.00%
发文量
213
审稿时长
26 days
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