使用大气等离子体应用器的等离子体辅助水处理

Brandon Byrns, A. Lindsay, D. Knappe, S. Shannon
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引用次数: 2

摘要

等离子体辅助水处理系统为减少对化学物质的依赖而改变水化学提供了一条引人注目的途径。等离子体生产用于化学减排、污染物去除的氧化剂和还原剂,以及生产无化学原料的水化学剂,是水处理领域潜在的变革性技术。工作在162MHz1的大气等离子体源用于形成反应性物质,这些物质入射到下游水源。在研究各种水处理应用的同时,已经确定了实际实施该技术的几个关键挑战,包括改进水/等离子体相互作用的途径和优化特定水处理应用的化学反应。设计一种改进的装置,提高气流和水暴露的效率。重点介绍了初级等离子体放电与水源的相互作用,以及化学成分和化学控制的潜在途径。特别感兴趣的是通过等离子体水相互作用产生和表征羟基自由基。描述等离子体条件(特别是化学)和水化学变化的实验将被呈现。将介绍水处理领域的潜在应用,包括处理供水中的全氟化合物、阿特拉津和二恶烷。
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Plasma assisted water treatment using an atmospheric air plasma applicator
Plasma assisted water treatment systems present a compelling pathway for modification of water chemistry with reduced dependence on chemicals. Plasma production of oxidizing and reducing agents for chemical abatement, contaminant removal, and production of aqueous chemical agents without chemical feedstock present a potential transformative technology in the area of water treatment.An atmospheric plasma source operating at 162MHz1 is used to form reactive species that are incident on a downstream water source. While studying a variety of water treatment applications, several key challenges for practical implementation of this technology have been identified including improved pathways for water/plasma interaction and optimized chemistry for specific water treatment applications. Design of an improved device with increased efficiency in both airflow and water exposure will be presented. The interaction between the primary plasma discharge and water source, with emphasis on chemical composition and potential pathways for chemistry control are highlighted. Of specific interest is production and characterization of hydroxyl radicals through plasma water interaction. Experiments that characterize plasma conditions (specifically chemistry) andchanges to water chemistry will be presented. Potential applications of interest in the area of water treatment including treatment of perfluorinated compounds, atrazine, and dioxane in water supplies will be presented.
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