• 화약ㆍ발파
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• 제30권2호
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• pp.21-28
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• 2012

사면 절취 및 도심지 터파기 등 인공적으로 사면을 형성하는 경우 경제적이고 효율적인 공법으로 화약을 이용한 발파공법이 많이 사용되고 있다. 절취면 보호를 위해 대상 암반에 손상을 주지 않고 암반이 가지고 있는 자연적인 강도를 그대로 유지할 수 있도록 발파하는 것이 중요하며 사회적으로 문제 시 되는 발파공해를 고려하여 발파진동을 저감할 수 있는 공법이 필요하다. 본 연구에서는 평활한 절취면 형성을 위하여 도폭선에 폭약을 등간격으로 배치하고 장약의 방법과 전색의 방법을 달리하여 발파를 진행하였다. 4가지 패턴을 사용하여 총 60공에서 20회 발파를 실시하였으며 발파원으로부터 15~120m 거리에서 발파진동소음측정기를 사용하여 진동속도를 측정하여 310개의 데이터를 획득하였다. 측정된 진동속도 데이터를 분석하여 발파진동을 저감하고 효율적이고 경제적으로 절취면을 보호할 수 있는 방법을 연구해 보았다.

• 한국터널지하공간학회 논문집
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• 제8권2호
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• pp.115-128
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• 2006

불연속면 또는 연약대로 인해 야기되는 암반의 구조적 이방성과 비균질성은 터널의 변형 거동에 큰 영향을 미친다. 아무리 우수한 지반조사가 이루어진다 하더라도, 지역적 불확실성은 여전히 남아 있으므로 복잡한 지반 조건에서의 터널 굴착은 매우 어려운 작업이다. 이러한 불확실한 환경에서 터널 막장 전방의 지반 상태를 정확히 예측하는 것은 안전하고 경제적인 터널 건설에 필요불가결하다 할 수 있다. 따라서 본 논문은 3차원 수치해석을 통하여 암반의 이방성 및 비균질성의 영향을 평가하였다. 즉 터널 굴착으로 인해 야기되는 지반 거동을 분석하고 이에 대한 연약대의 폭과 강성 그리고 방향성의 영향을 정량적으로 평가하였다.

• 지질공학
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• 제17권4호
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• pp.555-566
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• 2007

일반적으로 국내에서 터널의 지보 설계를 위한 암반분류법으로는 RMR 분류가 사용된다. 터널 시공 중 예비조사계획을 보온하고 노선을 따른 연속적인 지반 정보를 획득하기 위해 막장관찰과 동시에 RMR을 통한 암반분류가 시행된다. 하지만 국내 터널 시공 여건 상 조사를 위한 충분한 시간이 보장되지 않으며, 때로는 막장에서의 직접 관찰이 불가능 한 경우가 많다. 따라서 본 연구에서는 RMR 항목 중 상대적으로 조사 시간이 길며 세밀한 관찰이 요구되는 RQD와 불연속면 상태 항목의 배점을 추정하기 위한 선형회귀분석을 수행하였으며, 그 결과 최적 회귀식을 산정 하였다. 또한 기존 연구에서 고려하지 않은 지질조건을 반영하기 위해, 퇴적암, 천매암, 화강암을 기반으로 하는 터널의 데이터를 각각 구분하여 분석하였다. 추정을 위한 변수로는 다른 RMR 항목을 대상으로 선정하였으며, 이들 간의 선형회귀분석을 통해 최종 회귀식을 산정하였다.

• 지질공학
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• 제17권2호
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• pp.197-204
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• 2007

터널은 굴착에 의해 지반의 변형을 일으키며, 지보를 설치하고 시간이 지남에 따라 점차 안정화된다. 터널 굴착이 지반 거동에 미치는 영향은 계측지점과 막장간의 거리가 증가함에 따라 감소한다. 터널의 변위가 수렴하여 안정화되는 시점을 예측할 수 있다면, 안정화 이후 이루어지는 여러 공정들을 앞당김으로써 시간적, 경제적 손실을 줄일 수 있다. 따라서 본 연구에서는 변위 수렴 시점을 예측하기 위하여 관리도 기법을 적용하였다. 퇴적암을 기반으로 하는 터널에 대한 관리도 판정 결과, 막장에서부터의 거리가 최대 100 m 이내에서 변위가 수렴하였다.

• Geomechanics and Engineering
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• 제19권3호
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• pp.269-282
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• 2019

Due to top-coal and immediate roof as cushion layer connecting with support and overlying strata, it can make significant influence on strata behaviors in fully mechanical top-coal caving working face (TCCWF). Taking Qingdong 828 working face as engineering background, $FLAC^{3D}$ and $UDEC^{2D}$ were adopted to explore the influence of top-coal thickness (TCT), immediate roof thickness (IRT), top-coal elastic modulus (TCEM) and immediate roof elastic modulus (IREM) on the vertical stress and vertical subsidence of roof, caving distance, and support resistance. The results show that the maximum roof subsidence increases with the increase of TCT and IRT as well as the decrease of TCEM and IREM, which is totally opposite to vertical stress in roof-control distance. Moreover, although the increase of TCEM and IREM leading to the increase of peak value of abutment pressure, the position and distribution range have no significant change. Under the condition of initial weighting occurrence, support resistance has negative and positive relationship with physical parameters (e.g., TCT and IRT) and mechanical properties (e.g., TCEM and IREM), respectively.

• Geomechanics and Engineering
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• 제17권4호
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• pp.333-342
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• 2019

Geological dynamic hazards during coal mining can be caused by the failure of a composite system consisting of roof rock and coal layers, subject to different loading rates due to different advancing velocities in the working face. In this paper, the uniaxial compression test simulations on the composite rock-coal layers were performed using $PFC^{2D}$ software and especially the effects of loading rate on the stress-strain behavior, strength characteristics and crack nucleation, propagation and coalescence in a composite layer were analyzed. In addition, considering the composite layer, the mechanisms for the advanced bore decompression in coal to prevent the geological dynamic hazards at a rapid advancing velocity of working face were explored. The uniaxial compressive strength and peak strain are found to increase with the increase of loading rate. After post-peak point, the stress-strain curve shows a steep stepped drop at a low loading rate, while the stress-strain curve exhibits a slowly progressive decrease at a high loading rate. The cracking mainly occurs within coal, and no apparent cracking is observed for rock. While at a high loading rate, the rock near the bedding plane is damaged by rapid crack propagation in coal. The cracking pattern is not a single shear zone, but exhibits as two simultaneously propagating shear zones in a "X" shape. Following this, the coal breaks into many pieces and the fragment size and number increase with loading rate. Whereas a low loading rate promotes the development of tensile crack, the failure pattern shows a V-shaped hybrid shear and tensile failure. The shear failure becomes dominant with an increasing loading rate. Meanwhile, with the increase of loading rate, the width of the main shear failure zone increases. Moreover, the advanced bore decompression changes the physical property and energy accumulation conditions of the composite layer, which increases the strain energy dissipation, and the occurrence possibility of geological dynamic hazards is reduced at a rapid advancing velocity of working face.

• 대한전자공학회:학술대회논문집
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• 대한전자공학회 2008년도 하계종합학술대회
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• pp.929-930
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• 2008

To develop reliable 3D face recognition system, many researchers also have focused on 3D face data acquisition system. Previous many 3D face acquisition systems use visible patterns to solve corresponding problem, and this pattern made anyone who wants to be verified uncomfortable. In this paper, we propose a new invisible infrared line-laser pattern for 3D face data acquisition.

• Geomechanics and Engineering
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• 제32권4호
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• pp.375-385
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• 2023

There are many joint fissures distributed in the engineering rock mass. In the process of geological history, the underground rock mass undergoes strong geological processes, and undergoes complex geological processes such as fracture breeding, expansion, recementation, and re-expansion. In this paper, the damage-stick-slip process (DSSP), an analysis model used for rock mass failure slip, was established to examine the master control and time-dependent mechanical properties of the new and primary fractures of a multi-fractured rock mass under the action of stress loading. The experimental system for the recemented multi-fractured rock mass was developed to validate the above theory. First, a rock mass failure test was conducted. Then, the failure stress state was kept constant, and the fractured rock mass was grouted and cemented. A secondary loading was applied until the grouted mass reached the intended strength to investigate the bearing capacity of the recemented multi-fractured rock mass, and an acoustic emission (AE) system was used to monitor AE events and the update of damage energy. The results show that the initial fracture angle and direction had a significant effect on the re-failure process of the cement rock mass; Compared with the monitoring results of the acoustic emission (AE) measurements, the master control surface, key blocks and other control factors in the multi-fractured rock mass were obtained; The triangular shaped block in rock mass plays an important role in the stress and displacement change of multi-fracture rock mass and the long fissure and the fractures with close fracture tip are easier to activate, and the position where the longer fractures intersect with the smaller fractures is easier to generate new fractures. The results are of great significance to a multi-block structure, which affects the safety of underground coal mining.

• 대한치과보철학회:학술대회논문집
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• 대한치과보철학회 2001년도 추계학술대회
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• pp.36-36
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• 2001

• 한국해양공학회지
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• 제16권6호
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• pp.7-17
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• 2002

Recently, artificial rocks, instead of buoys, have been placed on the submerged breakwater to indicate its location. The accurate estimation of wave forces on these rocks is deemed necessary for their stability design. Characteristics of the wave force, however, are expected . to be very complicated because of the occurrence of breaking or post-breaking waves. In this regard, wave forces exerted on an artificial rock have been investigated in this paper. The maximum wave force has been found to strongly dependent on the location and shape of the artificial rock that is placed on the submerged breakwater. The plunging breaker occurs near the loading cram edge of a submerged breakwater, which cause impulsive breaking wave force on the rock. Using the Morison equation, with the velocity and acceleration at the front face of the artificial rock and varying water surface level, it is possible to estimate wave forces, even impulsive breaking wave forces, that are acting on the rock installed on a submerged breakwater. The vertical wave force is also found to depend, significantly, on the buoyant force.