• 한국철도학회논문집
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• 제16권1호
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• pp.47-51
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• 2013

본 논문은 연약지반 쉴드 TBM 축소 모형실험을 통하여 슬러리에 의해 가해지는 막장 지보압의 변화에 따른 터널 막장면 안정성 변화 양상을 파악하고자 토피고에 따라 0.5D, 0.75D, 1.0D, 1.25D, 1.5D의 총 5개 Case에 대하여 모형실험을 수행하였으며, 이론적인 터널 막장면 지보압 및 모형실험으로 선정된 적정 지보압 값을 상호 비교하였다. 암반 쉴드 TBM과 달리 연약지반 쉴드 TBM의 경우 균질한 지반조건임에 따라 모형실험으로부터 산정된 적정 지보압이 터널 심도에 따른 막장면 토압 및 수압으로부터 이론적으로 산정된 막장압 범위($P_{min}{\leq}P_{slurry\;pressure}{\leq}P_{max}$)와 잘 일치하고 있음을 확인하였다.

• 터널과지하공간
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• 제17권6호
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• pp.453-463
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• 2007

Terzaghi터널토압 이론은 shield 및 도심 NATM터널의 설계토압으로 현재까지도 사용되고 있다. 본 논문에서 지반의 변형거동과 한계상태를 가정한 Terzaghi 토압과의 상호 관계에 관한 조사를 위해 Terzaghi 터널토압이론, 2차원 실내 터널 모형 실험과 변형률 연화모델을 기본으로한 비선형 수치해석을 실시하였다. 굴착에 따른 터널 토압와 지반 변형거동의 폭넓은 이해와 그들의 상호작용에 대한 효율적인 활용은 경제적인 터널 지보설계와 안정한 시공을 이끌 수 있다.

• Geomechanics and Engineering
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• 제33권5호
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• pp.439-451
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• 2023

The construction of shield tunnelling in urban sites is facing serious risks from complex and changeable underground conditions. Construction problems in the sand-clay mixed ground have been more reported in recent decades for its poor control of soil loss in tunnel face, ground settlement and supporting pressure. Since the limitations of observation methods, the conventional physical modelling experiments normally simplify the tunnelling to a plane strain situation whose results are not reliable in mixed ground cases which exhibit more complicated responses. We propose a new method for the study of the mixed ground tunnel through which mixed lays are simulated with transparent soil surrogates exhibiting different mechanical properties. An experimental framework for the transparent soil modelling of the mixed ground tunnel was established incorporated with the self-developed digital image correlation system (PhotoInfor). To understand better the response of face stability, ground deformation, settlement and supporting phenomenon to tunnelling excavation in the sand-clay mixed ground, a series of case studies were carried out comparing the results from cases subjected to different buried depths and mixed phenomenon. The results indicate that the deformation mode, settlement and supporting phenomenon vary with the mixed phenomenon and buried depth. Moreover, a stratigraphic effect exists that the ground movement around mixed face reveals a notable difference.

• 터널과지하공간
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• 제34권3호
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• pp.185-195
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• 2024

인천도시철도 1호선 검단연장선 1공구 건설공사는 국내 최초로 로드헤더와 TBM 장비가 함께 적용되었다. 쉴드TBM 터널 구간은 1,057 m이며, 대부분 암반으로 구성 되어있으며 공항철도 및 경인아라뱃길 하부 터널 구간 공사를 포함하고 있다. 굴진을 위해 7.8 m 토압식 쉴드TBM 장비가 투입되었으며, 상·하선 구간의 평균 월굴진율은 239.1 m이고, 최대 월굴진율은 334.5 m이다. 본 기술기사에서는 인천도시철도 1호선 검단연장선 1공구 쉴드TBM 터널 굴진 실적을 중심으로 쉴드TBM의 생산성을 종합적으로 평가해 보았으며, 성공적인 쉴드TBM 터널 공사 수행에 있어서 유용한 자료를 제공하고자 한다.

• 한국철도학회논문집
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• 제9권2호
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• pp.174-179
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• 2006

Recently, the crossing tunnel has been constructed frequently to connect the separated area by highway and railroad. The construction of crossing tunnel must be progressed while maintaining the existing traffic of the highway as well as railroad. There are many cross funnelling methods such as NTR, TRCM, Messer Shield, Front Jacking, and Pipe Roof Method. The advantages of adopting RPS(Roof Panel Shield) method in crossing tunnel construction with comparing other existing cross funnelling methods are needed a little volume of concrete and easy to change the direction of cutting shoe during the construction of pipe roof, The 3-dimensional numerical analysis of RPS to consider the arching effect was performed for the application in the crossing tunnel under railroad. The earth pressure distribution and settlement were predicted when the RPS method was applied during the excavation for crossing railroad tunnel construction.

• Geomechanics and Engineering
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• 제23권6호
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• pp.513-521
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• 2020

In this paper, due to the need for cutting cement-soil group pile composite foundation under the 7-story masonry structure of Zhenghe District and the shield tunnel of Zhengzhou Metro Line 5, a field test was conducted to directly cut cement-soil single pile composite foundation with diameter Ф=500 mm. Research results showed that the load transfer mechanism of composite foundation was not changed before and after shield tunnel cut the pile, and pile body and the soil between piles was still responsible for overburden load. The construction disturbance of shield cutting pile is a complicated mechanical process. The load carried by the original pile body was affected by the disturbance effect of pile cutting construction. Also, the fraction of the load carried by the original pile body was transferred to the soil between the piles and therefore, the bearing capacity of composite foundation was not decreased. Only the fractions of the load carried by pile and the soil between piles were distributed. On-site monitoring results showed that the settlement of pressure-bearing plates produced during shield cutting stage accounted for about 7% of total settlement. After the completion of pile cutting, the settlements of bearing plates generated by shield machine during residual pile composite foundation stage and shield machine tail were far away from residual pile composite foundation stage which accounted for about 15% and 74% of total settlement, respectively. In order to reduce the impact of shield cutting pile construction on the settlement of upper composite foundation, it was recommended to take measures such as optimization of shield construction parameters, radial grouting reinforcement and "clay shock" grouting within the disturbance range of shield cutting pile construction. Before pile cutting, the pile-soil stress ratio n of composite foundation was 2.437. After the shield cut pile is completed, the soil around the lining structure is gradually consolidated and reshaped, and residual pile composite foundation reaches a new state of force balance. This was because the condensation of grouting layer could increase the resistance of remaining pile end and friction resistance of the side of the pile.

• 한국터널지하공간학회 논문집
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• 제16권6호
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• pp.599-614
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• 2014

TBM으로 시공되는 터널은 기계에 의해 전단면 굴착(full face tunnelling)이 이루어지므로, 굴착면에 접근하는 것이 매우 제한적이다. 이러한 한계를 극복하고 TBM 터널에서 굴착면 전방의 지반상태를 정확히 예측할 수 있는 기술은 매우 드물다. 본 연구는 TBM에서 전기비저항을 사용하여 굴착면 전방의 이상지반을 예측할 수 있는 TBM 비저항 예측(TRP)시스템을 개발하고, TBM 현장에서의 적용성과 예측 정확성을 검증하기 위해 EPB 쉴드 TBM으로 시공 중인 지하철 터널에서 현장 실험을 수행하였다. TBM 비저항 예측 시스템은 전극을 사용하여 지반의 전기비저항을 측정하고, 이를 바탕으로 역해석을 수행하여, 이상지반의 위치와 두께 및 전기적 특성을 예측한다. 전극이 부착된 강관을 유압으로 굴착면에 압입하여, 전극이 지반과 완전히 접촉하도록 장치를 제작하였다. 또한, 전극이 챔버 내부를 관통하여 나아가도록 하는 동시에 토사유출을 방지하도록 설계하여 현장에서의 전방예측을 가능하게 하였다. 1차 실험 결과, 굴착면 근접 지반과 굴착면 전방 지반의 전기비저항 및 유전율이 동일하게 나타나 이상지반이 존재하지 않음을 예측하였다. 2차 실험 결과, 굴착면 전방 약 1 m 지점부터 상대적으로 낮은 유전율 비를 가지는 이상지반 구간이 약 5 m 길이로 존재함을 예측하였다. 이는 각각 지표에서 물리탐사 또는 시추를 통해 조사된 지반상태 및 TBM 굴착 중 예측 구간에서 반출되었던 버력을 관찰한 기록과 잘 일치하였다.

• 한국지반공학회:학술대회논문집
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• 한국지반공학회 1999년도 봄 학술발표회 논문집
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• pp.177-184
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• 1999

In soft ground tunneling, shield method is very good for safety of neighboring structures. Although shield tunnel method has the merits to minimize the deformation of ground around tunnel, ground deformations occurred until the material grouted in tail void hardens are inevitable. In this study, the effects of micropile used as one method to restrain the settlement of neighboring structures by the tail void are studied by laboratory model tests. As a basic test result, the effective direction of micropile and the restraint rate of settlement by micropile reinforcement are known.

• 한국지반공학회:학술대회논문집
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• 한국지반공학회 2005년도 지반공학 공동 학술발표회
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• pp.556-563
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• 2005

Recently, it is used to join an building to an underground shopping-area in urban. When we construct Seo-Cho Complex building which is in Seoul, we also construct an underground passage to the Gangnam underground shopping-area. But it is difficult to excavate in the downtown area, because excavations induce traffic jam and public discontent. Considering safety, a confined area, settlements, we decided to use DSM(Divided Shield Method) which is based on messer shield. This paper will produce our experience and the results provide a useful guide in a connection tunnel

• 한국암반공학회:학술대회논문집
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• 한국암반공학회 2001년도 추계공동학술발표회 논문집
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• pp.115-120
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• 2001

In No. 1 tunnel for Kwnagju urban subway construction, net penetration rate of the shield TBM was analyzed. This tunnel of 540 m length is located in soil layers at starting and in hard rocks such as amphibolite and granitic gneiss at ending with 84 m length. The net penetration rate was dropped down to 2∼11 cm/hr in rock while 50∼80 cm/hr in soil. Theoretical penetration rate is analyzed in conditions of machine and rock in order to compare the actual net penetration rate. The relationships between net penetration rate and thrust force is also investigated in this report.