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复合井修复地下水硝酸盐污染的效果
引用本文:刘佩贵, 曾康辉, 尚熳廷, 刘湘伟, 阳辉. 复合井修复地下水硝酸盐污染的效果[J]. 农业工程学报, 2021, 37(6): 214-219. DOI: 10.11975/j.issn.1002-6819.2021.06.026
作者姓名:刘佩贵  曾康辉  尚熳廷  刘湘伟  阳辉
作者单位:1.合肥工业大学土木与水利工程学院,合肥230009;2.合肥工业大学汽车与交通工程学院,合肥 230009;3.西藏自治区水文水资源勘测局,拉萨850000
基金项目:水文水资源与水利工程科学国家重点实验室"一带一路"水与可持续发展科技基金(2018nkms06)
摘    要:为探寻更适用于农田周边硝酸盐污染地下水的原位生物修复技术,该研究构建了A、B、C3套试验装置,分别刻画管井(A)、大口井与管井组成的复合井(B、C).基于3套物理试验模型,定量对比分析了管井与复合井修复地下水硝酸盐污染的效果.结果表明:受水力停留时间的影响,相同流速条件下,A、B、C三套修复系统的硝酸盐负荷分别介于75...

关 键 词:地下水  污染  硝酸盐去除  反硝化作用  复合井  水力停留时间
收稿时间:2020-01-21
修稿时间:2021-03-01

Remediation effects of compound well on nitrate pollution in groundwater
Liu Peigui, Zeng Kanghui, Shang Manting, Liu Xiangwei, Yang Hui. Remediation effects of compound well on nitrate pollution in groundwater[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2021, 37(6): 214-219. DOI: 10.11975/j.issn.1002-6819.2021.06.026
Authors:Liu Peigui  Zeng Kanghui  Shang Manting  Liu Xiangwei  Yang Hui
Affiliation:1.College of Civil Engineering, Hefei University of Technology, Hefei 230009, China;2.School of Automobile and Transportation Engineering, Hefei University of Technology, Hefei 230009, China;3.Reconnaissance Bureau of Hydrology and Water Resource, Tibet Autonomous Region, Lasa 850000, China
Abstract:Abstract: Nitrate pollution has posed a great threat to groundwater near farmlands, due mainly to the long-term agricultural fertilization and soil microorganisms. Nitrates with strong migration ability have entered the zone of saturation along with water movement. High concentrations of nitrates are directly detrimental to the safety of groundwater source areas. In this study, three systems A, B, and C were constructed to explore an in-situ bioremediation technology for the detection of nitrate-contaminated groundwater around farmland. Every system consisted of wells, storage tanks, and peristaltic pumps. System A was used to simulate a tube well with a diameter of 7 cm. System B and C were used to simulate compound wells, where there were a large well with a diameter of 14 cm and a tube well with a diameter of 7 cm. Every tube well was filled with fine sand in the same volume and height, where the height of fine sand was 12cm. The large diameter wells in system B and C were filled with fine sand with the heights of 4 cm and 8 cm, respectively. Both tube wells and large wells were used to simulate the complete penetration wells. The bottom of the wells was sealed, where water flowed in from the side walls. The peristaltic pumps were installed on the top of wells to simulate water pumping. The volume ratio of the reaction medium was 1:2:3 in three systems. The ratio of hydraulic retention time was also 1:2:4 under the same flow rate. The biofilm was naturally domesticated. Ethanol was used as the carbon source. A total of 6 groups were set in the reaction stage, including 25, 50, 75, 100, 125, and 150 mg/L, according to the concentration gradients of nitrate nitrogen. The test results showed that the microorganisms in the reaction medium could basically select the dominant strains within one day when the nitrate concentration increased instantaneously, leading to match the changes in nitrate loading conditions for the better denitrification capacity. In-situ bioremediation systems were also constructed with compound wells including tube wells and large diameter wells, in order to repair nitrate-contaminated groundwater and the nitrate loading of every system. The nitrate loadings of three remediation systems A-C were 75-100 mg/L, 100-125 mg/L, and 125-150 mg/L at the flow rate of 0.26 m/d. The removal rate of remediation systems reached more than 95% within nitrate loading. There was no accumulation of nitrite and excessive ammonia nitrogen, indicating the feasibility of repair systems with compound wells. Groundwater mining and remediation were carried out simultaneously without the need to cut off agricultural non-point source pollution, indicating high security for groundwater source area. In addition, a combination of tube wells and large diameter wells can be installed to compound wells with a relatively simple well drilling (including phreatic water and confined water). The diameter of wells and height of the reaction medium can be adjusted for better removal of nitrates, according to the thickness of the aquifer, the amount of water demand, and the level of nitrate-contaminated groundwater. Physical test models were used to determine the nitrate loading intervals of three remediation systems. In the future work, the hydrogeochemical model will be established to accurately determine the maximum nitrate loadings of repair systems with compound wells, together with the influence of medium heterogeneity on the remediation performance.
Keywords:groundwater   pollution   nitrate removal   denitrification   compound wells   hydraulic retention time
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