模拟低温热处理热增强反应区的空间范围

IF 1.8 4区 环境科学与生态学 Q3 WATER RESOURCES
Qianli Xie, Kevin G. Mumford, Bernard H. Kueper
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引用次数: 0

摘要

低温热处理(LTTT)是一种可以加强地下水中有机成分水相降解反应的技术。了解地下水中的热传递对于低温热处理应用的设计非常重要。本研究通过数值建模研究了渗透性异质性对加热过程中和加热后温度分布的影响。考虑到加热期间和加热后的温度历史,利用平均半衰期确定了 1,1,1- 三氯乙烷(1,1,1-TCA)水解的增强反应区。对于水解反应,由于其反应速率随温度升高呈指数增长,因此短时间内达到高温可大幅缩短平均半衰期。结果表明,在地下水流速较高的情况下,增强反应区被转移到了加热器井区的下游。这表明,加热器应移至目标处理区的上游,以充分利用所施加的热量。此外,渗透性异质性会导致在流速较高时出现更大的宏观分散。与同质渗透性条件相比,这导致在异质渗透性条件下的模拟中热量扩散更快,散热更快。因此,在平均速度为 0.3 米/天时,渗透率异质性较高的模拟中,增强反应区较小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulating the Spatial Extent of Thermally Enhanced Reaction Zones for Low Temperature Thermal Treatment

Low temperature thermal treatment (LTTT) is a technology that can enhance aqueous-phase degradation reactions for organic constituents in groundwater. Understanding heat transfer in groundwater is important for the design of LTTT applications. In this study, the effect of permeability heterogeneity on temperature distributions during and after the application of heat was investigated by numerical modeling. An enhanced reaction zone was determined for the hydrolysis of 1,1,1-trichloroethane (1,1,1-TCA) using an average half-life considering the temperature history during and after heating. For hydrolysis reactions, the average half-life could be reduced substantially by reaching a high temperature for a short period of time because their reaction rates increase exponentially with increased temperatures. Results showed that the enhanced reaction zone was shifted downstream of the heater well zone at high groundwater velocities. This suggests that heaters should be shifted upstream of the target treatment zone to fully utilize the applied heat. In addition, permeability heterogeneity leads to greater macroscopic dispersion at higher velocities. This resulted in higher spreading of heat and faster heat dissipation in the simulations with a heterogeneous permeability condition compared with a homogenous permeability condition. As a result, the enhanced reaction zone was smaller in simulations with higher levels of permeability heterogeneity at a mean velocity of 0.3 m/day.

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来源期刊
CiteScore
3.30
自引率
10.50%
发文量
60
审稿时长
>36 weeks
期刊介绍: Since its inception in 1981, Groundwater Monitoring & Remediation® has been a resource for researchers and practitioners in the field. It is a quarterly journal that offers the best in application oriented, peer-reviewed papers together with insightful articles from the practitioner''s perspective. Each issue features papers containing cutting-edge information on treatment technology, columns by industry experts, news briefs, and equipment news. GWMR plays a unique role in advancing the practice of the groundwater monitoring and remediation field by providing forward-thinking research with practical solutions.
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