최근 터널의 정보화 설계시공이 중요시 되어지고 있다. 암반구조의 복잡성으로 인해 사전에 예측 할 수 없었던 암반의 붕락이 발생하여, 붕락대책에 막대한 비용과 시간을 낭비하는 사례가 많다. 암반 불연속면의 복잡성을 사전 조사 단계에서 충분히 파악하거나 대책을 수립하는 것은 어렵다. 본 논문에서는 터널의 신 정보화 설계시공법을 제안하고, 현장에서 관찰한 불연속면 정보를 근거로 하여 극대단면 터널에 적용했다. 터널의 신 정보화 설계시공법을 위한 수치해석 프로그램은 범용성, 정밀성, 신속성, 편리한 사용성을 검토하여 새롭게 개발되었다. 극대단면 터널에서는 표준지보에 의해 지지할 수 없는 불안정 키블럭이 7개 존재하는 것이 판명되었다. 7개의 키블럭에 대해서는 굴착전에 추가 지보를 실시했다. 극대단면 터널에 있어서, 터널의 신 정보화 설계시공법을 위해서 새롭게 개발한 수치해석 프로그램을 사용하여 정확한 키블럭 추출이 가능한 것을 검증하였다. 사용하기 쉬운 사용자 인터페이스를 가지고 있는 본 컴퓨터 시뮬레이션 기법은 키블럭의 안정성 계산뿐만 아니라 추가보강대책공의 설계도 가능하다.
최근 터널의 정보화 설계시공이 중요시 되어지고 있다. 암반구조의 복잡성으로 인해 사전에 예측 할 수 없었던 암반의 붕락이 발생하여, 붕락대책에 막대한 비용과 시간을 낭비하는 사례가 많다. 암반 불연속면의 복잡성을 사전 조사 단계에서 충분히 파악하거나 대책을 수립하는 것은 어렵다. 본 논문에서는 터널의 신 정보화 설계시공법을 제안하고, 현장에서 관찰한 불연속면 정보를 근거로 하여 극대단면 터널에 적용했다. 터널의 신 정보화 설계시공법을 위한 수치해석 프로그램은 범용성, 정밀성, 신속성, 편리한 사용성을 검토하여 새롭게 개발되었다. 극대단면 터널에서는 표준지보에 의해 지지할 수 없는 불안정 키블럭이 7개 존재하는 것이 판명되었다. 7개의 키블럭에 대해서는 굴착전에 추가 지보를 실시했다. 극대단면 터널에 있어서, 터널의 신 정보화 설계시공법을 위해서 새롭게 개발한 수치해석 프로그램을 사용하여 정확한 키블럭 추출이 가능한 것을 검증하였다. 사용하기 쉬운 사용자 인터페이스를 가지고 있는 본 컴퓨터 시뮬레이션 기법은 키블럭의 안정성 계산뿐만 아니라 추가보강대책공의 설계도 가능하다.
The observational design and construction method in tunnels is becoming important recently. In many tunnels, enormous cost and time are consumed to cope with the failing or sliding of rock blocks, which could not be predicted because of the complexity of rock discontinuities. It is difficult to esti...
The observational design and construction method in tunnels is becoming important recently. In many tunnels, enormous cost and time are consumed to cope with the failing or sliding of rock blocks, which could not be predicted because of the complexity of rock discontinuities. It is difficult to estimate the properties of rock masses before the construction. In this paper, a new observational design and construction method in tunnels are proposed, and then applied to the example of the very large cross section tunnel based on actual discontinuity information observed in situ. The items examined in developing a program for the new observational design and construction method are the following ones: generality, precision, high speed, and friendly usability. At the very large cross section tunnel, 7 key blocks were judged to be unstable because they could not be supported by standard supports. Supplementary supports were installed to these 7 key blocks before the excavation. It is possible to detect key blocks all along the tunnel exactly by using the numerical analysis program developed for the new observational design and construction method in the very large cross section tunnel. This computer simulation method with user-friendly interfaces can calculate not only the stability of key blocks but also the design of supplementary supports.
The observational design and construction method in tunnels is becoming important recently. In many tunnels, enormous cost and time are consumed to cope with the failing or sliding of rock blocks, which could not be predicted because of the complexity of rock discontinuities. It is difficult to estimate the properties of rock masses before the construction. In this paper, a new observational design and construction method in tunnels are proposed, and then applied to the example of the very large cross section tunnel based on actual discontinuity information observed in situ. The items examined in developing a program for the new observational design and construction method are the following ones: generality, precision, high speed, and friendly usability. At the very large cross section tunnel, 7 key blocks were judged to be unstable because they could not be supported by standard supports. Supplementary supports were installed to these 7 key blocks before the excavation. It is possible to detect key blocks all along the tunnel exactly by using the numerical analysis program developed for the new observational design and construction method in the very large cross section tunnel. This computer simulation method with user-friendly interfaces can calculate not only the stability of key blocks but also the design of supplementary supports.
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문제 정의
The author is grateful to Prof. Yuzo Ohnishi in the School of Civil Engineering of Kyoto University, who is currently the President of the Japanese Committee of Rock Mechanics (Japanese Committee for International Society for Rock Mechanics), for his help and encouragement in the study.
This paper describes the development of a computer simulation method with user friendly interfaces to apply the key block analysis on site to investigate the stability of tunnels based on the behaviors of discontinuous rock masses and to design supplementary supports when detected blocks are unstable. A new observational design and construction method using key block analysis is suggested, then applied to the example of the very large cross section tunnel based on actual discontinuity information observed in situ.
제안 방법
On the other hand, cohesion C is 0 KPa and an angle of internal friction $ is 37° in the case of no existence of clay filling. Further, the strength of discontinuities to get more accurate C and $ by simple shear test was re-examined.
Connectable Swellex, because they had large resistance for shearing along discontinuities and adhesive strength to rock mass was strong in comparison with ordinary rock bolts. In addition, the most suitable position, number and length of rock bolts were calculated in this method in order to anchor the rock mass outside the key blocks and to maintain the stability.
The actual example site selected in this paper is the very large cross section tunnel in the New Second Tomei-Meishin Expressway between Tokyo and Kobe. The new observational design and construction method using key block analysis is applied to the large tunnel with a very large cross section of about 200 m2. The very large cross section tunnel in the New Second Tomei- Meishin Expressway is now under construction examining standard support system for large rock tunnel in Japan.
대상 데이터
The very large cross section tunnel is now under construction. The 5 m diameter Tunnel Boring Machine (TBM) pilot tunnel is at the center in the proposed tunnel. After the TBM pilot tunnel was excavated, the main tunnel is enlarged by New Austrian Tumeling Method (NATM).
The actual example site selected in this paper is the very large cross section tunnel in the New Second Tomei-Meishin Expressway between Tokyo and Kobe. The new observational design and construction method using key block analysis is applied to the large tunnel with a very large cross section of about 200 m2.
참고문헌 (12)
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