Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Remediation of Petroleum-Contaminated Gas Station Soil Using High-Pressure Soil Washing Technology
Objectives In this study, high-pressure soil washing was performed on in-situ gas station soils for the remediation of petroleum-contaminated gas station sites. Methods On-site gas station soils (GSS) collected from four different locations were subjected to high-pressure soil washing to analyze the amount of fine soil removal and TPH concentration after washing according to the cut-off size (0.075, 0.105 mm). In addition, the four GSS were evaluated for the relationship between the organic matter content of each soil and TPH removal efficiency. Furthermore, to evaluate the disintegration force of high-pressure soil washing technology to disperse soil aggregates, the particle size distribution of the soil before and after washing was evaluated and XRD analysis was performed. Results and Discussion As the cut-off size increased (0.075 mm → 0.105 mm), the removal rate of fine soil in the GSS increased, and the TPH concentration tended to decrease. With respect to the TPH Soil Contamination Warning Standard for Region 2 (800 mg/kg), only the GSS 3 was in compliance with the standard (630 mg/kg). There were no significant differences in fine soil removal rates among the soils, which was expected since all the soils tested represented the same sandy loam. Washing efficiencies by soil were relatively low for soils with relatively high organic matter content. The particle size distribution showed the largest particle reduction was in the 2-0.850 mm range after remediation, while soil particles increased in the 0.105-0.075 mm and <0.075 mm range. In addition, XRD analysis showed an increase in the peak intensity of Quartz and the removal of clay mineral after washing, confirming the effective breakdown of soil aggregates and removal of fine soil by cavitation. Conclusion If an optimal cut-off size is established, considering the soil texture and economics of the contaminated site after identifying the initial organic content level in the soil prior to washing, it is anticipated that high-pressure soil washing technology will be effectively applied for the remediation of petroleum-contaminated gas station sites.
Remediation of Petroleum-Contaminated Gas Station Soil Using High-Pressure Soil Washing Technology
Objectives In this study, high-pressure soil washing was performed on in-situ gas station soils for the remediation of petroleum-contaminated gas station sites. Methods On-site gas station soils (GSS) collected from four different locations were subjected to high-pressure soil washing to analyze the amount of fine soil removal and TPH concentration after washing according to the cut-off size (0.075, 0.105 mm). In addition, the four GSS were evaluated for the relationship between the organic matter content of each soil and TPH removal efficiency. Furthermore, to evaluate the disintegration force of high-pressure soil washing technology to disperse soil aggregates, the particle size distribution of the soil before and after washing was evaluated and XRD analysis was performed. Results and Discussion As the cut-off size increased (0.075 mm → 0.105 mm), the removal rate of fine soil in the GSS increased, and the TPH concentration tended to decrease. With respect to the TPH Soil Contamination Warning Standard for Region 2 (800 mg/kg), only the GSS 3 was in compliance with the standard (630 mg/kg). There were no significant differences in fine soil removal rates among the soils, which was expected since all the soils tested represented the same sandy loam. Washing efficiencies by soil were relatively low for soils with relatively high organic matter content. The particle size distribution showed the largest particle reduction was in the 2-0.850 mm range after remediation, while soil particles increased in the 0.105-0.075 mm and <0.075 mm range. In addition, XRD analysis showed an increase in the peak intensity of Quartz and the removal of clay mineral after washing, confirming the effective breakdown of soil aggregates and removal of fine soil by cavitation. Conclusion If an optimal cut-off size is established, considering the soil texture and economics of the contaminated site after identifying the initial organic content level in the soil prior to washing, it is anticipated that high-pressure soil washing technology will be effectively applied for the remediation of petroleum-contaminated gas station sites.
Remediation of Petroleum-Contaminated Gas Station Soil Using High-Pressure Soil Washing Technology
Yonghwan Choe (Autor:in) / Sang Hyeop Park (Autor:in) / Deok Hyun Moon (Autor:in)
2023
Aufsatz (Zeitschrift)
Elektronische Ressource
Unbekannt
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