• Proceedings of the Korea Water Resources Association Conference
• /
• 2012.05a
• /
• pp.165-169
• /
• 2012

하천에서의 골재 채취는 일시적으로 홍수위를 낮추는 순기능도 있지만 하천형태학적으로 좋지 않은 영향을 줄 수도 있다. 하천에서 골재 채취로 인한 준설웅덩이의 회복에 필요한 시간 혹은 과정은 공학적으로 매우 중요하다. 본 연구에서는 시간에 따른 준설 웅덩이의 발달 과정을 모의할 수 있는 수치모형을 제시하였다. 제시된 수치모형은 준정류 가정에 기초하는데, 이는 흐름은 정상류이고 하도가 변하는 특성시간이 흐름에 비해 길다고 가정하는 것이다. 총유사량 공식으로 Engelund and Hansen (1967) 공식과 Ackers and White (1973) 공식을 이용하여 수치실험을 실시하였다. Engelund and Hansen 공식을 사용하였을 때, Parker (2004)에 제시된 준설 웅덩이의 되메움 과정을 정량적으로 유사하게 모의하는 것으로 나타났다. 제시된 모형의 적용성을 검토하기 위하여 선행 실내실험에 적용하였다. 전반적으로 준정류모형이 준설 웅덩이의 되메움과 전파과정을 잘 모의하는 것으로 확인되었다. 그러나 수치모형이 두부침식 현상을 잘 재현하지 못하여 재퇴적 이후의 하상파를 과소 산정하는 것으로 나타났다.

• Proceedings of the Korea Water Resources Association Conference
• /
• 2010.05a
• /
• pp.1716-1720
• /
• 2010

최근에 하천에 대한 체계적인 조사 및 연구가 수행되지 않은 상태에서 골재채취 및 하천준설이 무분별하게 이루어져 왔다. 이로 인하여 하천의 급격한 하상 및 지형변화가 나타났다. 또한 하천의 안정성, 홍수범람, 수리구조물의 안정성, 하천수를 취수하는 취수장의 취수장애 발생 등 많은 문제점이 야기되고 있다. 따라서 본 연구에서는 하안침식을 고려하여 골재채취 및 하도준설에 의한 교란하천의 적응과정을 정량적으로 파악하기 위하여 이동상 실내실험을 수행하였으며, 골재채취를 위한 준설 규모의 변화에 따른 하도의 응답 특성을 분석하였다. 실험 수로에서 초기에 유사의 이동이 시작되면서 하안침식이 발달하며, 교호사주가 발달한다. 하상에서 이동하는 유사는 웅덩이(pit)에 포착되면서 하류로 유사의 공급이 차단되며, 웅덩이 하류에서는 사주의 발달이 없으며, 평탄하상을 유지한다.웅덩이가 완전히 되메우기가 완료되며, 유사의 공급에 의해 웅덩이 하류에서도 사주가 발달한다. 시간이 지나면서 사주의 파장은 증가하고, 하상은 새로운 평형상태를 유지한다. 웅덩이 상류에서는 하폭이 크게 증가하고 있으나, 웅덩이 하류에서는 하폭의 증가율이 크지 않다. 또한 웅덩이 하류에서는 상류에서 공급되는 유사가 웅덩이에 의해 차단되고 사주의 발달이 거의 없다. 웅덩이의 되메우기가 진행되고 있는 동안에 웅덩이의 이동속도는 일정하게 유지되나, 되메우기가 완료되면서 웅덩이의 이동속도가 느려진다. 웅덩이의 규모가 증가함에 따라 웅덩이의 되메우기 시간은 증가하고 하안의 침식이 증가한다. 웅덩이의 상류와 하류의 하폭의 차이가 증가하며, 새로운 평형상태에 도달하는 시간이 증가하는 것을 보여 준다.

• Journal of Korea Water Resources Association
• /
• v.43 no.7
• /
• pp.657-666
• /
• 2010

The adjustment processes of mining pits in the disturbed channels by sand or gravel mining were investigated by laboratory experiments in this study. The pit migrated with speed when the river bed was steep. The pit migrated slow and steady when the pit was filling with sand, but the pit migrated with speed after the filling processes was finished. The submerged angle of repose in the pit was nearly constant during the pit was filling. The pit was filled with sand with speed as the channel slope was increased. It took time for the pit to be filled with sand as the pit dimension was increased. This meant that the disturbed channels by sand or gravel mining to adjust the new environment was dependent on the slope of the channels and the dimension of the pits. The dimensionless pit length was short and the dimensionless pit depth was shallow as the time was increased. The dimensionless pit depth was shallow, but the dimensionless pit migration speed was increased as the dimensionless shear velocity and the migration speed of the pit were increased. The dimensionless pit depth was increased with the dimensionless bar migration speed. The shape of the pit was deformed and migrated downstream in accordance with the location and shape of the biased bar front which was developed upstream.

• Korean Journal of Ecology and Environment
• /
• v.44 no.4
• /
• pp.385-395
• /
• 2011

The adjustment processes and responses of a series of mining pits by sand or gravel mining were investigated by laboratory experiments. The filling processes of the two pits were affected by the bars developed in the upstream of the channel. However, the bars were not developed and the bed was degradated in the downstream of the pits due to little sediment flow, which was trapped in the pits. The submerged angle of repose in the pits was nearly constant when the pits were being filled. After the filling processes of the pits were finished, the pit was speedily filled with sediment, and the bed was aggradated and migrated with speed. However, the angle of repose decreased. As the distance between the upstream pit and the downstream pit increased, the bed of the pit downstream was tailcutted and degradated. The migration speed of the pit decreased. However, the dimensionless pit depth increased as the distance between the pits increased. The dimensionless pit depth increased with time.

• KSCE Journal of Civil and Environmental Engineering Research
• /
• v.32 no.1B
• /
• pp.53-57
• /
• 2012

This study presents a numerical model that is capable of simulating the evolution of mining pit in a stream. The numerical model is based on the quasi-steady assumption that the flow is steady with time-dependent morphological change. This hypothesis is valid due to the fact that the stream morphology changes over a long period compared with the time of flow change. Before applications, numerical experiments are carried out with two total load formulas such as Engelund and Hansen's (1967) and Ackers and White's (1973). It is found that the use of Engelund and Hansen's formula reproduces evolution of mining pit best compared with simulated profiles in Parker (2004). Then, the model is applied to two laboratory experiments in the literature. In general, the numerical model simulates properly the evolution of mining pit in laboratory open-channels. However, it is found that the model does not reproduce head-cutting, propagating upstream, and under-estimates the wave of the bed, propagating downstream, after finishing the re-fill of the mining pit.

• Journal of Korea Water Resources Association
• /
• v.43 no.10
• /
• pp.921-932
• /
• 2010

In this study, the adjustment processes of the disturbed channels by sand or gravel mining were investigated by a two dimensional numerical model in the generalized coordinate system. As a numerical scheme, the CIP (cubic interpolated pseudoparticle method) method was used to calculate the advection term in the flow field and central difference method was used to the diffusion term in it. The pit of the channel was partially filled with sediment at the toe of the pit upstream. As time increased, the headcut erosion upstream in the pit was decreased due to the sediment inflow. The almost inflow sediment upstream was trapped into the pit and the sediment deposit wedge migrated downstream in the pit with the steep submerged angle of repose. The numerical model was reproduced well the evolution processes of the channel. The mining pit migrated with speed as the channel was steep, and the numerical results were in overall agreement with the experimental results.