Journal of Korean Society of Forest Science (한국산림과학회지)

Korean Society of Forest Science (한국산림과학회)
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Estimation of Sediment Discharge Controlled by Sediment-filled Check-dam in a Forested Catchment

산림유역의 만사 사방댐에 의한 토사유출 조절 효과 추정

  • Received : 2016.08.16
  • Accepted : 2016.09.05
  • Published : 2016.09.30
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Abstract

To estimate the sediment discharge controlled by sediment-filled check-dam and thereby enhancing factor for check-dam design and dredging criteria, we surveyed slope failures and stream-bed fluctuation caused by geomorphic disturbances (i.e., landslides and debris flows) in Inje, Gangwondo. In general, check-dams play roles for restraining and controlling sediment discharge within a section under the design equilibrium gradient and a section under the design flood gradient, respectively. The results in this study showed same pattern: that is, the closed type check-dam, which has a design restraint sediment discharge of $2,111m^3$, estimated to control a sediment discharge of $3,996m^3$ in the stream section within 250 m right upper area immediately after the disturbances occurred in 2006. As a result, a design control sediment discharge of the check-dam was larger than its design restraint sediment discharge. This represents that the check-dam is still having an own function for controlling sediment discharge although it exceeded the designed capacity by the sediment discharged from upstream during the disturbances. Our finding suggests that the sediment discharge controlling of check-dam may need to be evaluated separately from its sediment discharge restraint. Currently, the country, however, does not consider the design control (or restraint) sediment discharges, based on the actual field survey, as criteria for check-dam design and/or dredging work. Therefore, the accumulation of the quantitative data is required to support that check-dam has functions for both restraining and controlling sediment discharge. This would be a way to develop our erosion control technology to the scientific technology equipped with a more objective and systematic aspects.

이 연구에서는 2006년 집중호우 시 산사태 및 토석류가 발생한 강원도 인제군의 기룡산 유역을 대상으로 사면붕괴 및 계상변동을 추정하여 만사 상태에 도달한 불투과형 사방댐이 토사유출 조절에 미치는 영향을 정량적으로 해석하고, 이를 토대로 사방댐의 설계 및 준설기준을 고도화하는 데에 필요한 새로운 인자를 제안하였다. 일반적으로 사방댐은 계획평형기울기 구간과 계획홍수기울기 구간에서 각각 토사유출의 억제와 조절 기능을 발휘하고 있다. 연구대상유역에 시공된 불투과형 사방댐은 계획억제토사량에 해당하는 저사량이 $2,111m^3$로 설계되었지만, 2006년 집중호우로 인한 산지교란 발생 시에는 해당 사방댐 직상부로부터 250 m의 계류구간에 걸쳐 $3,996m^3$의 유출토사를 조절한 것으로 관측되었다. 결과적으로 해당 사방댐은 유출토사 억제를 위한 계획억제토사량보다 큰 규모의 계획조절토사량을 나타내어 만사된 이후에도 유출토사의 조절이라는 사방댐의 기능을 발휘하고 있었다. 이와 같이 사방댐의 토사유출 조절기능은 토사유출 억제기능과 구분하여 평가하여야 하지만, 현재 우리나라에서는 현지에서 유역 특성을 실측한 자료를 기반으로 한 계획억제토사량 또는 계획조절토사량을 사방댐의 설계 및 준설기준 인자로서 고려하고 있지 않다. 따라서 합리적인 사방댐의 설계 및 유지관리 기준을 마련하기 위해서는 사방댐의 토사유출 억제기능과 조절기능을 정량적으로 해석한 현장자료가 축적되어야 하며, 이는 우리의 사방기술이 보다 객관적이고도 체계적인 면모를 갖춘 과학적 기술로 발전할 수 있는 방안일 것이다.

Keywords

References

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