하천제방의 월류 붕괴 메커니즘 규명을 위한 모형실험

김진만(Jin-Man Kim),박민철(Min-Cheol Park),문인종(In-Jong Moon),진윤화(Yoon-Hwa, Jin) 한국지반신소재학회 2017 한국지반신소재학회 논문집 Vol.16 No.1

본 연구에서는 월류에 의한 붕괴 메커니즘의 규명을 위해 모형제방(제방고 0.4~0.8m)과 실물제방(제방고 1.0m)을 대상으로 월류 붕괴실험을 수행하였다. 월류에 의한 제방붕괴는 1단계에서는 월류에 의해 비탈표면에서 세굴이 발생되었으며, 월류의 유속은 완만히 증가되었다. 2단계에서는 붕괴단면이 커지고 유속도 급격히 증가되었다. 3단계에서는 월류에 의해 제방 단면이 완전히 붕괴되고 붕괴면적이 넓어져 유속이 상대적으로 감소되었다. 월류에 의한 제방의 붕괴각(θ)은 큰 자중, 감소된 전단저항력 및 월류의 흐름에 의한 추가 소류력으로 인해 랭킨토압의 사면붕괴각보다 크게 나타났다. 제방고(H)가 증가될수록 월류에 의한 제방의 월류 유속(υ)이 증가되었으며, 이로 인해 소류력이 추가로 작용되어 제방의 붕괴각(θ)과 붕괴면적(A)이 함께 증가되었다. 모형실험과 실물실험에 사용된 모래 시료가 동일한 입경크기로 한계세굴유속이 같아 월류 유속변화에 의해 세굴 특성이 지배되는 것으로 나타났다. This research conducted the two types of model tests to examine the failure parameters by levee overflow, those were the pilot-scale levee (model height 0.4∼0.8 m) and real scale levee (model height 1.0 m). The procedure of levee failure by overflow was succeeded to the following three steps: At first step, the local scouring on levee slope was happened and the overflow velocity was increased slowly. At second step, the enlarged scouring surface and the rapid overflow velocity were succeeded. At last, the levee section was broken totally and the overflow velocity was decreased because of the wide failure surface of levee. The levee failure angle (θ) was appeared bigger than slope failure angle of Rankine earth pressure. The enlarged levee height (H) made the faster overflow velocity (υ) of the levees, therefore additional tractive force was applied to it, futhermore the failure angle (θ) and failure surface (A) were enlarged. Because the sand sample for pilot-scale and real scale tests had the same diameter, the critical scouring velocity of each type was also the same, and the scouring properties were governed by variation of overflow velocity.

Mapping Risk of Levee Overtopping Using LiDAR Data: A Case Study in Nakdong River Basins, South Korea

정윤재 대한토목학회 2015 KSCE Journal of Civil Engineering Vol.19 No.2

Overtopping occurs when the flood water’s level is greater than the levee’s height. Mapping risk of levee overtopping is efficientfor assessing levee stability, generating flood hazard maps and planning flooding management. This paper proposes a methodologyfor mapping the risk of levee overtopping using the topographic Light Detection and Ranging (LiDAR) data taken in Nakdong RiverBasins, South Korea. The procedure is as follows: A slope map is generated from the LiDAR data, then the levee crown polygonsand the riverside levee boundaries are extracted from the slope map by using the levee crown detection method. The levee crownsegments with the risk of overtopping are identified using the values of the average height of the levee crown polygon, the designedflood level, and the freeboard. Next, different-colored levee boundaries are generated to show the risk of overtopping on each leveecrown segment. Finally, the areas with the height lower than the designed flood level are shown on the levee crown surfaces as thered points. In this research, the risk of overtopping on the two levees (Jungsan Levee and Daesan Levee) parallel to the NakdongRiver’s mainstream are assessed by using the proposed methodology. This research shows that Jungsan Levee do not have the risk ofovertopping, while Daesan Levee has the risk of overtopping.

기후변화에 따른 제방의 홍수취약성지수 민감도 분석

이후상,이재준 한국수자원학회 2018 한국수자원학회논문집 Vol.51 No.S-1

In this study, a new methodology was proposed to evaluate the flood vulnerability of river levee and to investigate the effect on the levee where the water level changes according to climate change. The stability of levee against seepage was evaluated using SEEP/W model which is two-dimensional groundwater infiltration model. In addition to the infiltration behavior, it is necessary to analyze the vulnerability of the embankment considering the environmental conditions of the river due to climate change. In this study, the levee flood vulnerability index (LFVI) was newly developed by deriving the factors necessary for the analysis of the levee vulnerability. The size of river levee was investigated by selecting the target area. The selected levees were classified into upstream part, midstream part and downstream part at the nearside of Seoul in the Han river, and the safety factor of the levee was analyzed by applying the design flood level of the levee. The safety ratio of the levee was analyzed by applying the design flood level considering the current flood level and the scenario of climate change RCP8.5. The degree of change resulting from climate change was identified for each factor that forms the levee flood vulnerability index. By using the levee flood vulnerability index value utilizing these factors comprehensively, it was finally possible to estimate the vulnerability of levee due to climate change. 본 연구에서는 하천 제방에 대한 홍수취약성을 평가하는 새로운 기법을 제시하고 기후변화에 따라 변화하는 수위에 대하여 제방에 미치는 영향을 분석하였다. 이를 위해 먼저 2차원 지하수침투 모형인 SEEP/W를 이용하여 제방의 침투거동을 분석하여 침투안전성을 평가하였다. 침투거동뿐만 아니라 기후변화에 따른 하천환경여건을 고려하는 제방의 취약성 분석 기술이 필요함으로써 본 연구에서는 추가적으로 제방의 취약성 분석에 필요한 인자를 도출하여 제방의 홍수취약성지수(levee flood vulnerability index; LFVI)에 의한 취약성 평가기법을 새로이 개발 하였다. 대상지역을 한강 본류 서울 구간으로 선정하여 하도별 제방의 크기를 조사하였고 조사한 제방을 상류부, 중류부, 하류부로 구분하여 3개의 대표 제방을 선정하였다. 이들 대표 제방지점에서 현재의 계획홍수위와 기후변화 시나리오 RCP8.5를 고려한 계획홍수위를 적용하여 제방의 활동 안전율과 제방홍수취약성지수를 분석하였다. 그리고 제방홍수취약성지수를 구성하는 각각 인자들에 대하여 기후변화에 따른 변화 정도를 파악하였다. 이들 인자들을 종합적으로 활용한 제방홍수취약성지수 값을 이용하여 최종적으로 기후변화에 따른 제방의 취약성을 추정할 수 있도록 하였다.

Sensitivity analysis of flood vulnerability index of levee according to climate change

Lee Hoo Sang,Lee Jae Joon 한국수자원학회 2018 한국수자원학회논문집 Vol.51 No.11

본 연구에서는 하천 제방에 대한 홍수취약성을 평가하는 새로운 기법을 제시하고 기후변화에 따라 변화하는 수위에 대하여 제방에 미치는 영향을 분석하였다. 이를 위해 먼저 2차원 지하수침투 모형인 SEEP/W를 이용하여 제방의 침투거동을 분석하여 침투안전성을 평가하였다. 침투거동뿐만 아니라 기후변화에 따른 하천환경여건을 고려하는 제방의 취약성 분석 기술이 필요함으로써 본 연구에서는 추가적으로 제방의 취약성 분석에 필요한 인자를 도출하여 제방의 홍수취약성지수(levee flood vulnerability index; LFVI)에 의한 취약성 평가기법을 새로이 개발 하였다. 대상지역을 한강 본류 서울 구간으로 선정하여 하도별 제방의 크기를 조사하였고 조사한 제방을 상류부, 중류부, 하류부로 구분하여 3개의 대표 제방을 선정하였다. 이들 대표 제방지점에서 현재의 계획홍수위와 기후변화 시나리오 RCP8.5를 고려한 계획홍수위를 적용하여 제방의 활동 안전율과 제방 홍수취약성지수를 분석하였다. 그리고 제방홍수취약성지수를 구성하는 각각 인자들에 대하여 기후변화에 따른 변화 정도를 파악하였다. 이들 인자들을 종합적으로 활용한 제방홍수취약성지수 값을 이용하여 최종적으로 기후변화에 따른 제방의 취약성을 추정할 수 있도록 하였다. In this study, a new methodology was proposed to evaluate the flood vulnerability of river levee and to investigate the effect on the levee where the water level changes according to climate change. The stability of levee against seepage was evaluated using SEEP/W model which is two-dimensional groundwater infiltration model. In addition to the infiltration behavior, it is necessary to analyze the vulnerability of the embankment considering the environmental conditions of the river due to climate change. In this study, the levee flood vulnerability index (LFVI) was newly developed by deriving the factors necessary for the analysis of the levee vulnerability. The size of river levee was investigated by selecting the target area. The selected levees were classified into upstream part, midstream part and downstream part at the nearside of Seoul in the Han river, and the safety factor of the levee was analyzed by applying the design flood level of the levee. The safety ratio of the levee was analyzed by applying the design flood level considering the current flood level and the scenario of climate change RCP8.5. The degree of change resulting from climate change was identified for each factor that forms the levee flood vulnerability index. By using the levee flood vulnerability index value utilizing these factors comprehensively, it was finally possible to estimate the vulnerability of levee due to climate change.

Application of Flood Vulnerability Index for analyzing safety change of levee according to climate change

Lee, Hoo Sang,Lee, Jae Joon 한국수자원학회 2018 한국수자원학회논문집 Vol.51 No.4

본 연구에서는 하천 제방에 대한 홍수취약성을 평가하는 새로운 기법을 기후변화에 따라 달라지는 하천의 수위변화를 고려하여 제방의 취약성 변화 정도를 파악해보고자 한다. 이를 위해 미래 기후변화 시나리오를 기반으로 대상유역의 홍수량을 산정하여 홍수위를 구하고 제방의 2차원 지하수침투 모형인 SEEP/W를 이용하여 침투거동을 분석함으로써 침투안정성을 평가하였다. 대상지역은 한강 본류 서울 구간으로 선정하여 대표 제방을 선정한 후, 대표 제방의 현재 계획홍수위와 기후변화를 고려한 홍수위를 고려하여 제방의 안전율을 분석하였다. 제방의 취약성 분석에 필요한 인자를 도출하고 이를 활용하여 기후변화 시나리오에 따른 제방의 수위변화를 고려한 제방의 취약성 분석을 실시하였으며 분석결과를 본 연구자가 기 개발한 제방홍수취약성지수(Levee Flood Vulnerability Index, LFVI) 값을 이용하여 제방의 취약성에 미치는 영향을 분석하였다. In this study, a new technique for evaluating the flood vulnerability of river banks is proposed. For this purpose, flood quantities of the basin were estimated based on the future climate change scenarios and the infiltration stability was evaluated by analyzing the infiltration behavior using SEEP/W which is a 2D groundwater infiltration model of the levee. The size of the river levee was investigated. The size of river levee was investigated by selecting the target area. The safety factor of the levee was analyzed considering the current flood level of the levee and the flood level considering the climate change. The factor needed to analyze the levee vulnerability was derived. We analyzed the vulnerability of the levee considering the change of the levee level according to the climate change scenarios. Levee Flood Vulnerability Index (LFVI) were used to evaluate the vulnerability of the levee.

Automated Levee height estimation in Urban River Using a Unmanned Aerial System LiDAR

이지상,손홍규 한국측량학회 2023 한국측량학회지 Vol.41 No.5

Levee shape information plays a critical role in identifying early signs of levee collapse, making it a vital component of levee safety management. This importance is particularly pronounced in today's climate, characterized by recurrent episodes of short yet intense rainfall. Obtaining accurate levee shape information across the entire levee system rapidly is essential. In the research, we propose a system for estimating levee shape information using ULS (Unmanned Aerial System LiDAR). This system captures a detailed point cloud of the urban river levee using ULS technology, automatically extracts relevant levee data points, and calculates the levee height. The flight plan was established to efficiently capture the levee's point cloud data. To assess the accuracy of our automatically extracted levee elevation, the result was compared it with values obtained from total station easurements. The results of the study indicate an error of 0.39 m when compared to total station data, and a 0.20 m when compared to manually measured values.

하천 제방의 취약성 분석 지수 개발 및 적용

이후상,이재준 한국습지학회 2019 한국습지학회지 Vol.21 No.5

In this study, we propose a new method for evaluating the vulnerability to flooding river levee. The purpose of this study is to examine how to apply the factors necessary to calculate the proposed levee flood index. To do this, the safety flood level was analyzed by applying the planned flood level. The levee flood vulnerabilities index was calculated based on seven factors such as freeboard, levee crown section, levee section ratio, safety factor, raised spot length, Seepage line change degree, and critical velocity. The Levee Flood Vulnerability Index(LFVI) of the levee developed in this study was used to levee vulnerability analysis. The results of the analysis were divided into 1 to 7 grades using Levee Flood Vulnerability Index(LFVI). 본 연구에서는 하천 제방에 대한 홍수취약성을 평가하는 새로운 기법으로 제방홍수취약성지수를 제안하였고 제방홍수취약성지수를 산정하는데 있어 필요한 인자를 적용하는 방법에 대하여 알아보고자 한다. 이를 위해 먼저 대상 제방의 계획홍수위를적용하여 제방의 안전율을 분석하였고, 제방의 인자들로는 여유고, 둑마루폭, 제방단면의 비, 활동안전율, 턱(소단)의 길이, 침윤선 길이 비, 한계유속으로 7가지의 인자들을 바탕으로 제방홍수취약성지수를 산출하였다. 이를 활용하여 제방의 취약성분석을 실시하고 분석결과를 제방홍수취약성지수(Levee Flood Vulnerability Index, LFVI) 값을 이용하여 1~7등급으로 나누어 제방의 취약성을 평가하였다.

A Study to Determine the Location of Perforated Drainpipe in a Levee for Controlling the Seepage Line

Hyeongyu Seo,강태욱,Micah Lourdes Felix,이상호 대한토목학회 2018 KSCE JOURNAL OF CIVIL ENGINEERING Vol.22 No.1

Levees are facilities constructed along river to protect floodplains against flooding. However, levee failures are also possible if seepage reaches landside surface of the levee. The seepage on the surface of the landside slope can be prevented by efficient design of levee drainage systems. This study aims to show the seepage control potential on levees by installation of perforated drainpipes, which was verified through hydraulic experiments. Scenarios were performed with four different water stages at riverside. For each scenario, the piezometric heads located at the bottom of the experimental levee were measured. The results of the hydraulic experiments showed that the precise positioning of perforated drainpipes is vital since it greatly affects the amount of seepage in the levee. The SEEP/W model that was calibrated and verified with the experiment results was used to suggest appropriate installation location range of the perforated drainpipe. From the numerical simulation, as the central location of perforated drainpipe is closer to landside levee toe horizontally and to foundation surface vertically, the safety of levee was increased from the seepage failure.

3차원 포인트 클라우드 모델링 기법을 활용한 바이오폴리머 기반 제방 보강공법의 성능 평가

고동우,강준구,강우철 한국수자원학회 2021 한국수자원학회논문집 Vol.54 No.3

In this study, a large-scale levee breach experiment from lateral overflow was conducted to verify the effect of the new reinforcement method applied to the levee’s surface. The new method could prevent levee failure and minimize damage caused by overflow in rivers. The levee was designed at the height of 2.5 m, a length of 12 m, and a slope of 1:2. A new material mixed with biopolymer powder, water, weathered granite, and loess in an appropriate ratio was sprayed on the levee body’s surface at a thickness of about 5 cm, and vegetation recruitment was also monitored. At the Andong River Experiment Center, a flow (4 m3/s) was introduced from the upstream of the A3 channel to induce the lateral overflow. The change of lateral overflow was measured using an acoustic doppler current profiler in the upstream and downstream. Additionally, cameras and drones were used to analyze the process of the levee breach. Also, a new method using 3D point cloud for calculating the surface loss rate of the levee over time was suggested to evaluate the performance of the levee reinforcement method. It was compared to existing method based on image analysis and the result was reasonable. The proposed 3D point cloud methodology could be a solution for evaluating the performance of levee reinforcement methods. 본 연구에서는 하천에서의 월류 발생에 따른 제방의 붕괴를 방지하거나 피해를 최소화하기 위한 신소재 보강공법을 제체 표면에 적용하여 그 효과를 검증하기 위한 실규모 횡월류 붕괴 실험을 수행하였다. 본 실험을 위해 제방 모형은 높이 2.5 m, 길이 12 m, 사면경사 1:2로 구성하였다. 또한 제방의 경우 습식 공법을 이용하여 바이오폴리머 분말, 물, 화강풍화토, 황토를 적정 비율로 혼합한 신소재를 제체 표면에 약 5 cm 두께로 분사한 뒤 식생활착 모니터링을 거쳐 최종 실험모형을 완성하였다. 안동하천연구센터 A3 수로 상류에서 4 m3/s 의 유량을 유입시켜 횡월류 흐름을 유도하였으며, 음향 도플러 유속계를 이용하여 상·하류의 유량 및 횡월류량의 변동을 측정하였다. 또한, 제방보강공법의 성능을 평가하기 위해 이미지 픽셀 기법 및 3차원 포인트 클라우드 모델링 기법을 활용한 시간에 따른 제방의 표면손실률을 산정함으로써 영상분석 기반의 새로운 평가 도구를 제시하였다. 본 연구결과를 적절하게 활용하게 되면 제방보강공법의 성능을 평가하는데 기초 자료로 활용될 수 있을 것으로 사료된다.

액상화 가능 지수의 국내 하천제방 지진취약도 평가 적용성 검토

하익수(Iksoo Ha),문인종(Injong Moon),윤정원(Jungwon Yun),한진태(Jintae Han) 한국지반환경공학회 2017 한국지반환경공학회논문집 Vol.18 No.4

본 연구에서는 하천제방이 홍수 때를 대비한 임시적인 기능이 크나 영구구조물이라는 기능적 특성과 길이가 매우 길다는 구조적 특성을 감안하여, 제방의 지진취약도를 간편하게 평가할 수 있는 방안을 검토하였다. 제방의 지진 시 주된 파괴모드가 제체 및 기초지반의 과잉간극수압 증가로 야기되는 지반의 강도감소 및 액상화로 인한 제체 침하인 점에 착안하여, 2차원 형태의 제방단면을 1차원으로 간주하고 액상화 가능 지수를 산정한 후, 그 결과를 지진 시 하천제방의 취약도와 연관시키는 방안을 검토하였다. 지진으로 야기된 제방 정상부의 변위와 제방의 지진취약도와의 관계를 기존 연구결과로부터 획득하였고, 2차원 동적 유효응력해석을 수행하여 산정한 제방 정상부 변위와 1차원 지진응답해석 결과를 기초로 산정한 액상화 가능 지수와의 상관관계를 검토하였다. 이러한 상관관계와 연계하여, 궁극적으로 액상화 가능 지수와 제방 지진취약도와의 연관성을 검토한 결과, 액상화 가능 지수를 이용한 국내 하천제방의 지진취약도를 평가하는 방법이 적용성이 있는 것으로 판단되었다. In this study, a simple method to evaluate the seismic vulnerability of river levees was examined considering the structural characteristic of river levee, that is long, and the functional characteristic of river levee that performs temporary function against flood but is a permanent structure in the ordinary way. Considering the fact that one of the main failure modes of the levee during the earthquake are the settlement due to the strength reduction of the ground caused by the increase of the excess pore pressure in the levee body and foundation and the settlement due to liquefaction, the 2-dimensional section of the levee was regarded as the 1-dimensional section and the liquefaction potential index (LPI) for the regarded section was estimated. The estimated LPI was correlated with the seismic vulnerability of river levees. The relationship between the displacement of the levee crest caused by the earthquake and the seismic vulnerability of the levees was obtained from the results of previous researches and the correlation between the displacements of the levee crest computed by 2-dimensional dynamic coupled analyses and LPIs based on the results of 1-dimensional seismic response analyses was investigated. In connection with this correlation, as a result of examination of the correlation between LPI and the seismic vulnerability of the levee, it was concluded that the method for evaluation of the seismic vulnerability of the Korean river levee using LPI is applicable.