한국환경과학회지 (Journal of Environmental Science International)

  • 제33권4호
  • /
  • Pages.269-277
  • /
  • 2024
  • /
  • 1225-4517(pISSN)
  • /
  • 2287-3503(eISSN)
한국환경과학회 (The Korean Environmental Sciences Society)
권호 표지
DOI QR코드

DOI QR Code

수리지질학적 과학수사 기법에 의한 도로 터널이 지하수 변화에 미치는 영향

Influence of Road Tunnel on Groundwater Change Determined Using Forensic Hydrogeological Technique

  • 윤설민 (한국건설기술연구원 수자원하천연구본부) ;
  • 함세영 (부산대학교 지질환경과학과)
  • Sul-Min Yun (Department of Hydro Science and Engineering Research, Korea Institute of Civil Engineering and Building Technology) ;
  • Se-Yeong Hamm (Department of Geological Sciences, Pusan National University)
  • 투고 : 2024.03.15
  • 심사 : 2024.04.22
  • 발행 : 2024.04.30
PDF 다운로드
⟨ 이전 논문 다음 논문 ⟩

초록

Scientific forensic techniques are used to verify environmental impact of groundwater pollution, surface water pollution, air pollution, noise, and vibration according to residents' complaints in connection with construction and civil engineering works. In this study, we investigated the contamination of groundwater and the lowering of the groundwater level in an area surrounding a tunnel excavation site for the Andong-Yeongdeok national road, using a forensic hydrogeological technique. We reviewed the groundwater level and water quality of well GW1 in the area surrounding the tunnel excavation site as well as tunnel construction information and then we analyzed the correlations among the obtained data. Before tunnel excavation, the water level of well GW1 was lower than the tunnel elevation. Considering the relationship between the precipitation, tunnel discharge, tunnel depth, and groundwater level of well GW1, the groundwater flowed from the tunnel to well GW1. Moreover, the tunnel discharge and groundwater levels were not related to each other. The pH of well GW1 was 8.4 before tunnel excavation. During excavation, the pH declined to 8.1-8.2 at the beginning, and increased to 8.8 at the end of the excavation. The fluorine concentration in well GW1 was 2.49 mg/L, 1.91-3.22 mg/L, and 1.7-2.67 mg/L, respectively, before, during, and after the excavation. The sulfate ion concentration was very high, over 2,000 mg/L, before and during the excavation; after the excavation, it was between 200 and 323 mg/L. Turbidity was 1.47, 10.5, and 4.51 NTU before, during, and after tunnel excavation, respectively. Therefore, the excavation of this tunnel is not related to the groundwater quality of well GW1.

키워드

참고문헌

  1. Cheong, J. Y., Hamm, S. Y., Yu, I. R., Whang, H. S., Kim S. H., Kim, M. S., 2015, Analysis of groundwater discharge into the Geumjeong tunnel and baseflow using groundwater modeling and long-term monitoring, J. Environ. Sci. Int., 24, 1691-1703. https://doi.org/10.5322/JESI.2015.24.12.1691
  2. Chiocchini, U., Castaldi, F., 2011, The impact of groundwater on the excavation of tunnels in two different hydrogeological settings in central Italy, Hydrogeol. J., 19, 651-669. https://doi.org/10.1007/s10040-010-0702-1
  3. Jeon, H. T., Hamm, S. Y., Lee, C. M., Lim, W. R., Yun, S. M., Park, H. J., 2018, Analyzing the change of surface water and groundwater systems caused by tunnel construction in northern Ulsan City, The J. Eng. Geol., 28, 81-99.
  4. Lee, B. D., Hamm, S. Y., Lee, C. O., Cho, B. W., Sung, I. H., 2001, Relation of groundwater flow rate and fracture system associated with waterway tunnel excavation The J. Eng. Geol, 11, 327-337.
  5. Lee, H. G., Hong, S. H., 1973, Geological report of the Cheongsong sheet (1: 50,000), Geological and Mineral Institute of Korea, 23.
  6. Ministry of Environment, K-water, 2019, Report on groundwater basic survey of Cheonsong area, 11-1480000-001615-01.
  7. Moon, J., Fernandez, G., 2010, Effect of excavation-induced groundwater level drawdown on tunnel inflow in a jointed rock mass, Eng. Geol., 110, 33-42. https://doi.org/10.1016/j.enggeo.2009.09.002
  8. Park, J. J. Kim, H. J., 2018, Use of a forensic geochemical technique and a hydrogeological assessment to determine the source of petroleum hydrocarbon contamination at a foreshore site in Korea, Environ. Earth Sci., 77, 742.
  9. Ramirez, A. I., Herrera, A., 2016, Forensic Hydrology, http://dx.doi.org/10.5772/64616.
  10. Shim, H. B., Hwang, J. P., Ann, K. Y., 2014, Leaching capacity and rate of alkali Ions from hardened cement paste, J. the Korea Inst. Struct. Maint. Insp., 18, 111-118. https://doi.org/10.11112/jksmi.2014.18.1.111
  11. Sutliff-Johansson, S., Ponter, S., Maki, A., Engstrom, E., Rodushkin, I., Peltola, P., Widerlund, A., 2020, Groundwater environmental forensic investigation combining multivariate statistical techniques and screening analyses, Environ. Forensics, 1-15.
  12. Witte, J. P. M., Zaadnoordijk, W. J., Buyse, J. J., 2019, Forensic hydrology reveals why groundwater tables in the Province of Noord Brabant (The Netherlands) dropped more than expected, Water, 11, 478.
  13. Woodhoud, B., 2007, From the publisher, Southwest Hydrol., 6, 4.