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http://dx.doi.org/10.9720/kseg.2014.4.631

Classification of Groundwater Level Variation Types Near the Excavated Area of the Temporary Gulpocheon Discharge Channel  

Kim, Chang-Hoon (Department of Civil Engineering, The University of Seoul)
Lee, Su-Gon (Department of Civil Engineering, The University of Seoul)
Hahn, Jeong-Sang (nexGeo Inc.)
Kim, Nam-Ju (GEO engineering Co., Ltd.)
Jeon, Byeong-Chu (Dongbu Engineering Co., Ltd.)
Publication Information
The Journal of Engineering Geology / v.24, no.4, 2014 , pp. 631-641 More about this Journal
Abstract
Characteristics of water-level changes in the Temporary Gulpocheon Discharge Channel were identified by observing and analyzing changes in the subterranean water level induced by hydrological stresses the underground aquifer. The subterranean water level refers to the level at which the pressure of subterranean water passing through the corresponding position has an equipotential value that is in equilibrium with the atmospheric pressure at that location. This water level is not fixed but changes in response to hydrological stress. It can be identified by repeatedly measuring the distance from the observation point to the surface of the subterranean water. The subterranean water-level change equation and the variance range of the hydrological curve of subterranean water over 24 hours at the Gimpo-Gimpo National Groundwater Monitoring Network (NGMN) were used as assessment factors. The variance characteristics of the subterranean water at the 18 monitoring system locations were classified into three impact, observational wish, and non-impact. The impact type accounted for 50% of the subterranean water of and accurately reflected the water-level changes due to hydrological stress, showing that distance is the major controlling factor. The observational wish type accounted for 27.8% of the subterranean water, and one of the two assessment factors did not meet the assessment factors. The nonimpact type accounted for 22.2% of the subterranean water. This type satisfied the two assessment factors and represents subterranean water-level changes response to precipitation.
Keywords
hydrological stress; equipotential value; hydrological curve; national groundwater monitoring network (NGMN); assessment factors;
Citations & Related Records
Times Cited By KSCI : 3  (Citation Analysis)
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