In this paper, a dynamic centrifuge model test was conducted on a 24.8-meter-deep excavation consisting of a 20 m sand layer and 4.8 m bedrock, classified as S3 by Korean seismic design code KDS 17 10 00. A braced excavation wall supports the hole. From the results, the mechanism of seismically induced earth pressure was investigated, and their distribution and loading points were analyzed. During earthquake loadings, active seismic earth pressure decreases from the at-rest earth pressure since the backfill laterally expands at the movement of the wall toward the active direction. Yet, the passive seismic earth pressure increases from the at-rest earth pressure since the backfill pushes to the wall and laterally compresses at it, moving toward a passive direction and returning to the initial position. The seismic earth pressure distribution shows a half-diamond distribution in the dense sand and a uniform distribution in loose sand. The loading point of dynamic thrust corresponding with seismic earth pressure is at the center of the soil backfill. The dynamic thrust increased differently depending on the backfill's relative density and input motion type. Still, in general, the dynamic thrust increased rapidly when the maximum horizontal displacement of the wall exceeded 0.05 H%.
In this study, centrifuge model tests were performed to evaluate the seismic response of multi-DOF structures with shallow foundations. Also, elastic time history analysis on the fixed-base model was performed and compared with the experimental results. As a result of the centrifuge model test, earthquake amplification at the fundamental vibration frequency of the soil (= 2.44 Hz) affected the third vibration mode frequency (= 2.50 Hz) of the long-period structure and the first vibration mode (= 2.27 Hz) of the short-period structure. The shallow foundation lengthened the periods of the structures by 14-20% compared to the fixed base condition. The response spectrum of acceleration measured at the shallow foundation was smaller than that of free-field motion due to the foundation damping effect. The ultimate moment capacity of the soil-foundation system limited the dynamic responses of the multi-DOF structures. Therefore, the considerations on period lengthening, foundation damping, and ultimate moment capacity of the soil-foundation system might improve the seismic design of the multi-DOF building structures.
Soil-foundation-structure interaction (SFSI) is one of the important issues in the seismic design for evaluating the exact behavior of the system. A seismic design of a structure can be more precise and economical, provided that the effect of SFSI is properly taken into account. In this study, a series of the dynamic centrifuge tests were performed to compare the seismic response of the single degree of freedom(SDOF) structure on the various types of the foundation. The shallow and pile foundations were made up of diverse mass and different conjunctive condition, respectively. The test specimen consisted of dry sand deposit, foundation, and SDOF structure in a centrifuge box. Several types of earthquake motions were sequentially applied to the test specimen from weak to strong intensity of them, which is known as a stage test. Results from the centrifuge tests showed that the seismic responses of the SDOF structure on the shallow foundation and disconnected pile foundation decreased by the foundation rocking. On the other hand, those on the connected pile foundation gradually increased with intensity of input motion. The allowable displacement of the foundation under the strong earthquake, the shallow and the disconnected pile foundation, have an advantage in dissipating the earthquake energy for the seismic design.
To investigate earthquake responses of structures with basements affected by soil deposits, centrifuge tests were performed using an in-flight earthquake simulator. The test specimen was composed of a single-degree-of-freedom structure model, a basement and sub-soil deposits in a centrifuge container. The test parameters were the dynamic period of the structure model, boundary conditions of the basement, existence of soil deposits, centrifugal acceleration level, and type and level of input earthquake accelerations. When soil deposits did not exist, the earthquake responses of the structures with fixed basement were significantly greater than those of the structure without basement. Also, the earthquake responses of the structures with the fixed basement surrounded by soil deposits were amplified, but the amplifications were smaller than those of the structures without basement. The earthquake responses of the structures with the half-embedded basement in the soil deposits were greater than those estimated by the fixed base model using the measured free-field ground motion. The test showed that the basement and the soil deposit should be simultaneously considered in the numerical analysis model, and the stiffness of the half-embedded was not effective.
Domestic urban railway underground station structures, which were built in the 1970s ad 1980s, had been constructed as Cut-and-Cover construction system without seismic design. Because the trends of earthquake occurrence is constantly increasing all over the world as well as the Korean Peninsula, massive human casualties and severe properties and structures damage might be occurred in an non-retrofitted underground station during an earthquake above a certain scale. Therefore, to evaluate the retrofit effect and soil-structure interaction of seismic retrofitted underground station, a centrifugal shaking table test with enhanced stiffness on its structural main member are carried out on 1/60 scaled model using the Kobe and Northridge earthquakes. The seismic retrofitted members, which are columns, side walls, and slabs, are evaluated to comparing with existing non-retrofitted centrifuge test results Also, to simulate the scaled ground using variation of shear velocity according to site conditions such as ground depth and density, resonant column test is performed. From the test results, the relative displacement behavior between ground and structures shows comparatively similar in ground, but is increased on ground surface. The seismic retrofit effects were measured using relative displacements and moment behavior of column and side walls rather than slabs. Additionally, earthquake wave can be used to main design factor due to large structural deformation on Kobe earthquake wave than Norhridge earthquake wave.
우리나라 저수지의 과반수 이상은 축조된지 60년 이상이 경과된 노후 저수지로, 경시적 열화에 의한 내구성 감소 및 붕괴 위험 증가, 퇴적토사 축적에 따른 유효저수량 감소 등 안전 및 기능상의 문제점을 내포하고 있다. 이와 같은 상황에서, 범지구적 이상기후 현상에 의한 집중호우의 빈도가 증가하고 있어 노후 저수지의 재개발이 시급한 실정이다. 저수지의 증고는 이와 같이 재해에 취약한 노후 저수지를 보수하는 유효한 방법이며, 저수량을 제고하여 수자원 확보 및 풍수해 대비능력 강화효과를 기대할 수 있다. 본 연구는 현장응력상태 및 월류를 재현한 원심모형실험을 통하여 증고 및 비증고 제체의 안정성을 평가하였다. 그 결과, 비증고 제체의 월류 발생시 하류측에 대규모의 파괴가 발생하는 반면, 동일 수위에서 증고 제체는 안정성을 확보함을 알 수 있었다. 따라서, 기후변화 대처 및 저수량 증대를 도모하기 위해 증고를 통한 노후 저수지의 재개발이 필요한 것으로 판단된다.
To investigate earthquake responses of structures with basements and soil deposits, centrifuge tests using an in-flight earthquake simulator were performed. The fixed and embedded basements did not reduce the earthquake responses of SDOF structures due to the dynamic behaviors of massive soil deposits.
In order to evaluate earthquake response of structures affected by shallow soft soil deposits, centrifuge tests were performed. The test specimen was composed of a single-degree-of-freedom structure model, a shallow foundation and sub-soil deposits in a centrifuge container. The structure response directly measured from the test showed that a large rocking rotation occurred due to the soil-foundation interaction. Thus, the acceleration of the structure was significantly smaller than the fixed base structure response.
This study seeks to characterize the dynamic behaviour of each section and to understand the performance of the interface using centrifuge model test and numerical analyses. The model test was verified by the comparison of the test results with those of numerical analyses, and the natural frequency for the composite dam with concrete-rockfill was proposed as like the same centrifuge model test and numerical analyses.
본 연구에서는 연약지반에서의 경량콘크리트포장을 적용할때의 안전성 평가를 위해 실제 포장체 사이즈의 1/30으로 축소한 모형을 이용하여 시험을 실시하였다. 연구에서 경량콘크리트 물성을 상사비를 통하여 알류미늄 슬래프 형태로 적용하였으며 슬래브를 지지하는 말뚝 또한 일반 지름 30cm 콘크리트 말뚝을 상사비를 적용하여 알류미늄으로 적용하였다. 연약지반은 카올리나이트를 물과 혼합하여 조성하였으며 연약지반층 하부에는 모래지반을 조성하였다. 시험은 지반조성 후에 포장체를 지반에 관입하고 원심모형실험을 통해 1시간 가량 조성지반에 안정화를 시킨 후 횡방향으로 하중을 가하여 경량콘크리트포장 모형의 안정성를 평가하였다. 시험결과 1G level에서 실험이 끝나는 순간까지 모형의 평균 침하량은 약 4mm의 침하량을 보였으며 30G level에서 안정화하는 1시간동안 1mm의 침하량을 보였다. 또한 횡방향 하중재하시 유한요소 해석을 통한 말뚝이 저항할 수 있는 횡하중 7kg에서 횡방향 변위가 일어나지 않았다.