• 터널과지하공간
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• 제15권1호
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• pp.71-79
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• 2005

지표로부터 터널까지의 토피가 얇고 지반이 풍화토 혹은 풍화암으로 연약한 곳에서 두 터널이 교차되도록 굴찰할 때 교차부의 역학적 안정성을 계측으로 확인하였다. 터널의 시공방법은 주로 12 m의 강관 다단그라우팅 3열로 막장전방을 선보강한 후 터널상반부를 굴착하였고 두 터널의 교차부는 자천공 록볼트로 추가 보강하였다. 터널 굴착 후 교차부 주변 지반의 변위가 수렴되어 역학적인 안정을 확인 할 수 있었다. 최종적으로 수렴된 변위는 천단침하와 내공변위가 각각 약 6-7 mm. 약 5 mm로 터널의 심도와 연약한 지반조건을 고려할 때 작은 값이었다. 따라서 길이 12 m의 강관 다단그라우팅 3열로 막장전방을 보강한 후 터널 교차부 주변을 굴착한 것은 변위를 억제하고 터널의 안정화에 효과적인 것으로 분석되었다.

• 터널과지하공간
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• 제9권3호
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• pp.185-193
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• 1999

본 연구에서는 2개 터널의 교차부에 설치된 교량에 이동차량하중이 작용될 때 동적해석결과를 제시하였다. 이와 같은 터널내에 위치한 교량은 매우 회귀한 사례로서 구조물의 동적특성은 통상적인 것으로 가정할 수 없을 것이다. 본 연구에서 조사한 교량은 서울 남산1호터널과 남산2호터널의 교차부에 설치된 철근콘크리트교이다. 교차부는 강구조물로된 가시설구조물에 의해 지지되며 이는 2호터널내의 라이닝이 교체되는 기간 동안에 설치될 것이다. 동적해석은 범용유한요소해석 프로그램인 SAP2000을 이용하였다. 이때 구조물, 터널의 라이닝 그리고 주변 암반은 3차원입체요소에 의해 표현되었으며 터널에서 방사되는 탄성파에너지를 모의하기 위하여 외부경계에 점성감쇠장치를 설치하였다. 주행속도에 따른 몇 가지 차량형태를 해석에서 고려하였다. 차량하중을 포함한 유한요소모델은 계측된 속도와 계산된 최대질점속도를 비교하여 검증되었다. 해석으로부터 이 교량에 대한 충격계수는 0.21로 추정되었다. 그러므로 이와 같은 교량구조물의 설계시 충격계수는 설계시방서에서 정한 상한값을 사용할 경우 안전측일 것으로 판단되었다.

• 한국지반공학회논문집
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• 제37권11호
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• pp.107-118
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• 2021

Scan-to-BIM은 라이다(Light Detection And Ranging, LiDAR)로 구조물을 계측하고 이를 바탕으로 3D BIM(Building Information Modeling) 모델을 구축하는 방법으로 정밀한 모델링이 가능하지만 많은 인력과 시간, 비용이 소모된다는 한계를 가진다. 이러한 한계를 극복하기 위해 포인트 클라우드 데이터를 대상으로 딥러닝(Deep learning) 알고리즘을 적용하여 구조물의 객체 분할(Semantic segmentation)을 수행하는 연구들이 진행되고 있으나 학습 데이터에 따라 객체 분할 정확도가 어떻게 변화하는지에 대한 연구는 미흡한 실정이다. 본 연구에서는 딥러닝을 통한 철도 터널의 객체 분할에 학습 데이터를 구성하는 철도 터널의 크기, 선로 유형 등이 어떤 영향을 미치는지 확인하기 위해 매개변수 연구를 수행하였다. 매개변수 연구 결과, 학습과 테스트에 사용한 터널의 크기가 비슷할수록, 단선 터널보다는 복선 터널로 학습하는 경우에 더 높은 객체 분할 성능을 보였다. 또한, 학습 데이터를 두 가지 이상의 터널로 구성하면 전체 정확도(Overall Accuracy, OA)와 MIoU(Mean Intersection over Union)가 적게는 10%에서 많게는 50%가량 증가하였는데 이로부터 학습 데이터를 다양하게 구성하는 것이 효율적인 학습에 기여할 수 있음을 확인하였다.

• Geomechanics and Engineering
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• 제14권5호
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• pp.407-419
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• 2018

In order to investigate flow characteristics after water inrush from the working face in process of karst tunnel construction, numerical calculation for two class case studies of water inrush is carried out by using the FLUENT software on the background of Qiyueshan tunnel. For each class water inrush from the tunnel face, five cases under different water-inrush velocity are simulated and researched. Three probing lines are selected respectively in the left tunnel, cross passage, right tunnel and in the height direction of the tunnel centerline. The variation characteristics of velocity and pressure on each probing line under the five water-inrush velocities are analyzed. As for the selected four groups probing lines in the tunnels, the change rules of velocity and pressure on each group probing lines under the same water-inrush velocity are discussed. Finally, the water flow characteristics after inrush from the tunnel face are summarized by comparing the case studies. The results indicate that: (1) The velocity and pressure change greatly at the intersection area of the cross passage and the tunnels. (2) The velocity nearby the tunnel side wall is the minimum, while it is the maximum in the middle position. (3) The pressure value of every cross section in the tunnels is basically fixed. (4) As water-inrush velocity increases, the flow velocity and pressure in the tunnels also increase. The former is approximately proportional to their respective water-inrush velocity, while the latter is not. The research results provide a theoretical basis for making scientific and rational escape routes.

• 설비공학논문집
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• 제30권3호
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• pp.123-129
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• 2018

In this study, CFD is used to compare and analyze the flow characteristics using reflected pressure wave during the intersection of two trains in straight tunnel. Two tunnels of different lengths; 600 m and 3,400 m were designed and numerical analysis of the flow characteristics of two tunnels carried out by setting the crossing state of the two trains at a constant velocity of 27 m/s form the center of the tunnel. The simulation model was designed using the actual tunnel and subway dimensions The train motion was achieved by using the moving mesh method. For the numerical analysis, $k-{\omega}$ standard turbulence model and an ideal gas were used to set the flow conditions of three-dimensional, compressible and unsteady state. In the analysis results, it was observed that the inside of the long tunnel without interference of the reflected pressure wave was maintained at a pressure lower than the atmospheric pressure and that the flow direction was determined by the pressure gradient and shear flow. On the other hand, the flow velocity in the short tunnel was faster and the pressure fluctuation was noted to have increased due to the reflected pressure wave, with more vortices formed. In addition, the flow velocity was noted to have changed more irregularly.

• Geomechanics and Engineering
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• 제35권1호
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• pp.29-39
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• 2023

As the intensity of urban underground space development increases, more and more tunnels are planned and constructed, and sometimes it is inevitable to encounter situations where tunnels have to underpass the river embankments. Most previous studies involved tunnels passing river embankments perpendicularly or with large intersection angle. In this study, a project case where two EPB shield tunnels with 8.82 m diameter run parallelly underneath a river embankment was reported. The parallel length is 380 m and tunnel were mainly buried in the moderate / slightly weathered clastic rock layer. The field monitoring result was presented and discussed. Three-dimensional back-analysis were then carried out to gain a better understanding the interaction mechanisms between shield tunnel and embankment and further to predict the ultimate settlement of embankment due to twin-tunnel excavation. Parametrical studies considering effect of tunnel face pressure, tail grouting pressure and volume loss were also conducted. The measured embankment settlement after the single tunnel excavation was 4.53 mm ~ 7.43 mm. Neither new crack on the pavement or cavity under the roadbed was observed. It is found that the more degree of weathering of the rock around the tunnel, the greater the embankment settlement and wider the settlement trough. Besides, the latter tunnel excavation might cause larger deformation than the former tunnel excavation if the mobilized plastic zone overlapped. With given geometry and stratigraphic condition in this study, the safety or serviceability of the river embankment would hardly be affected since the ultimate settlement of the embankment after the twin-tunnel excavation is within the allowable limit. Reasonable tunnel face pressure and tail grouting pressure can to some extent suppress the settlement of the embankment. The recommended tunnel face pressure and tail grouting pressure are 300 kPa and 550 kPa in this study, respectively. However, the volume loss plays the crucial role in the tunnel-embankment interaction. Controlling and compensating the tunneling induced volume loss is the most effective measure for river embankment protection. Additionally, reinforcing the embankment with cement mixing pile in advance is an alternative option in case the predicted settlement exceeds allowable limit.