• Determination of Optimum Operating Parameters for Enhanced Alkaline Hydrolysis of Soils Contaminated with TNT
  • Lee, Hwan;Choi, Jae-Heon;Lee, Cheol-Hyo;Kim, Ju-Yup;
  • Daeil Engineering and Construction Co., Ltd.;Daeil Engineering and Construction Co., Ltd.;Daeil Engineering and Construction Co., Ltd.;Daeil Engineering and Construction Co., Ltd.;
  • TNT 오염토의 염기성 가수분해 효율 향상을 위한 최적 운전인자 도출
  • 이환;최재헌;이철효;김주엽;
  • (주)대일이앤씨;(주)대일이앤씨;(주)대일이앤씨;(주)대일이앤씨;
Abstract
Nitro-aromatic Compounds (NACs) of explosives are structurally non-degradable materials that have an adverse effect to humans and ecosystems in case of emissions in natural due to the strong toxicity. In this study, batch test in the laboratory-scale has been conducted to find some process parameters of alkaline hydrolysis by considering the characteristics of NACs which are unstable in a base status and field application evaluation have been performed on the batch test results. Based on the experimental results of both laboratory and pilot-scale test, the optimum conditions of parameters for the alkaline hydrolysis of soils contaminated with explosives were pH 12.5, above the solid-liquid ratio 1 : 3, above the room temperature and 30 minute reaction time. In these four process parameters, the most important influencing factor was pH, and the condition of above pH 12.0 was necessary for high contaminated soils (more than 60 mg/kg). In the case of above pH 12.5, the efficiency of alkaline hydrolysis was very high regardless of the concentrations of contaminated soils. At pH 11.5, the removal efficiency of TNT was increased from 76.5% to 97.5% when the temperature in reactor was elevated from room temperature to 80℃. This result shows that it is possible to operate the alkaline hydrolysis at even pH 11.5 due to increased reaction rate depending on temperature adjustment. The results found in above experiments will be able to be used in alkaline hydrolysis for process improvement considering the economy.

Keywords: Nitroaromatic compounds;TNT(2,4,6-trinitrotoluene);Alkaline hydrolysis;Contaminated soil;

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This Article

  • 2015; 20(6): 103-110

    Published on Nov 30, 2015

  • 10.7857/JSGE.2015.20.6.103
  • Received on Oct 1, 2015
  • Revised on Nov 11, 2015
  • Accepted on Nov 26, 2015