Pseudo-static approach has been conventionally applied for the design of gravity type quay walls. In this method, seismic coefficient (kh), expressed in terms of acceleration due to gravity, is used to convert the real dynamic behavior to an equivalent pseudo-static inertial force for seismic analysis and design. Therefore, the calculation of an appropriate kh considering frequency characteristics of input earthquake is critical for representing the real dynamic behavior. However, the definitions of kh, which is used for simplified analysis in Korea, focuses only on convenience that is easy to use, and the frequency characteristics of input earthquake are not reflected in the kh definitions. This paper evaluates the influences of the frequency characteristics of input earthquake on kh by initially reviewing the kh definitions in the existing codes of Japan for port structures and then by performing a series of dynamic centrifuge tests on caisson gravity quay walls of different earthquake input motions (Ofunato, Hachinohe). A review of the existing codes and guidelines has shown that the kh values are differently estimated according to the frequency characteristics of input earthquake. On the other hand, based on the centrifuge tests, it was found that the permanent displacements of wall are more induced when long-period-dominant earthquake is applied.

Pseudo-static approach has been conventionally applied for the design of gravity quay walls. In this method, the decision to select an appropriate seismic coefficient (kh) is an important one, since kh is a key variable for computing an equivalent pseudo-static inertia force. Nonetheless, there is no unified standard for defining kh. Likewise, port structure designers in Korea have a difficulty in choosing an appropriate kh definition, as there are conflicts in how kh is defined between the existing seismic code of port structures and the proposed new one. In this research, various seismic design codes for port structures were analyzed to compare the definitions of the seismic coefficient. The results were used for the proposing a unified seismic coefficient definition. Further, two dynamic centrifuge tests were performed with different wall heights (5 m, 15 m) to clarify the reference point of peak acceleration used in determination of kh according to the wall height. Results from dynamic centrifuge experiments showed that correction factors for the peak ground acceleration considering both the wall height and allowable displacement are needed to calculate kh.

On Tuesday, January 17, 1995, an earthquake of magnitude 7.2 struck the Port of Kobe. In effect, the port was practically destroyed. After a hazard investigation, researchers reached a consensus to adopt a performance-based design in port and harbor structures in Japan. A residual displacement of geotechnical structures after an earthquake is one of the most important engineering demands in performance-based earthquake-resistant design. Thus, it is essential to provide reliable responses of geotechnical structures after an earthquake through various techniques. Today, a nonlinear explicit response history analysis(NERHA) of geotechnical structures is the most efficient way to achieve this goal. However, verification of the effective stress analysis, including post liquefaction behavior, is difficult to perform at a laboratory scale. This study aims to rigorously verify the NERHA by using well-defined field measurements, existing numerical tools, and constitutive models. The man-made, Port Island, in Kobe provides intensive hazard investigation data, strong motion records of 1995 Kobe earthquake, and sufficient engineering parameters of the soil. Two dimensional numerical analysis was conducted on the caisson quay wall section at Port Island subjected to the 1995 Kobe earthquake. The analysis result matches very well with the hazard investigation data. The NERHA procedure presented in this paper can be used in further studies to explain and examine the effects of other factors on the seismic behavior of gravity quay walls in liquefiable soil areas.

잔교식 안벽의 수중부는 접근이 쉽지 않아서 손상확인이 어려운 곳인데, 최근들어 태풍과 지진이 빈번하게 발생하고 있어 잔교식안벽 수중부 구조물의 손상 누적으로 인한 붕괴가 우려되는 상황이다. 잔교식 안벽의 붕괴를 방지하고 체계적으로 유지관리하기 위한 방안으로 FBG 센서를 이용한 적용 방법과 안전성 평가 방법을 연구하였다. 잔교식 안벽에 파일로 사용되는 원형 강관에 대한 FBG 센서의 적용 방안을 확인하기 위해 실내실험을 실시하고, 센서를 용접하여 부착하는 방법으로 적용해야 하는 것을 확인하였다. 잔교식 안벽에 대한 구조해석을 수행하여 FBG 센서를 부착하기 위한 최적의 부착위치를 확인하였다. 고정하중에 대한 응력을 구조해석을 하여 계산하고, FBG 센서를 통해 얻은 데이터를 이용하여 활하중에 대한 응력을 계산한 다음에 두 응력을 더해서 파일에 작용하고 있는 응력을 계산하였다. 계산한 응력을 허용응력과 비교하여 파일의 안전성 평가를 수행하였다. 본 연구는 잔교식 안벽의 안전성을 실시간으로 평가하는 방안을 찾기 위한 기초 연구로 수행되었다.

In the case of the port mooring facility, jetties with piles are mainly applied in soft ground conditions. In the three-dimensional modeling for the structural analysis of jetties with piles, the boundary conditions between the pile and the ground are universally applied to the Approximate depth of pile supported method and Elastic subgrade reaction spring method. In this study, p-y curve data for the pile ground condition was generated using the LPILE program, and then the nonlinear spring considering the p-y curve as the pile and ground boundary condition was input and analyzed in the 3D modeling of jetties with piles using the MIDAS civil And the necessity of applying the Nonlinear subgrade reaction spring method by comparison with the result and the analysis result according to the existing analysis method is suggested.

최근 수송선박의 대형화에 따라 기존 항만 시설의 접안 깊이 확보에 대한 필요성이 증가하고 있다. 증심공법은 기존 항만시설의 접 안 깊이를 확보하는 방법으로, 필요 깊이만큼 사석마운드를 굴착한 후 그라우팅을 통해 보강한다. 이 연구에서는 사석마운드 보강을 위한 그라 우팅 재료로 가소성 그라우트를 사용할 경우 보강성능과 충진성능에 대해 검토하고자 하였다. 2가지 가소성 그라우트 배합에 대해 압축강도 실험을 수행하여 지반보강효과를 검토하였고, 직경 400 mm, 높이 530 mm 크기의 실린더형 실험체 5개를 제작해 충진성능을 평가하였다. 구 조물의 안전성 확보를 위해 요구되는 개량체의 소요강도는 6 MPa이며, 이 연구에서 사용한 가소성 그라우트 배합 모두 재령 7일에 9 MPa 이상 으로 소요강도를 만족하는 것으로 확인되었다. 충진성능 평가 실험체의 충진상태를 육안으로 관찰한 결과, 이 연구에서 목표로 설정한 사석 채 움 높이까지 가소성 그라우트가 잘 채워지는 것을 확인하였다.

We have studied the optimum location of the sensor to evaluate the condition of the structure by performing the structural analysis on the landing pier. It is judged that it is appropriate to place the strain sensor of the landing pier at the upper part, the middle part and the upper part of the pile at 30% below the pile.

We have studied the optimum location of the sensor to evaluate the condition of the structure by performing the structural analysis on the landing pier. It is judged that it is appropriate to place the strain sensor of the landing pier at the upper part, the middle part and the upper part of the pile at 30% below the pile.

Based on IoT (Internet of Things) where its concept contains providing convenience to human life by connecting every objects around us, numerous projects have been done in civil engineering field. This paper has conducted the basic study on adopting IoT sensing technology and network system into harbor.

Condition evaluation consists of visual inspection and durability assessment. Visual inspection has weakness such as subjectivity of inspector and qualitative evaluation. So, this study is fundamental research for realtime safety evaluation of landing pier based on safety inspection manual. This study is for safety assessment of pile safety and bearing capacity using realtime occurrence strain of pile.

국내 시설물의 성능저하로 인하여 보수·보강에 투입되는 비용이 매년 증가하고 있으며, 이와 같이 성능저하가 발생된 구조물을 보강하여 공용 사용기간을 연장하거나, 저등급 구조물의 성능을 향상시켜 높은 등급의 구조물로 활용하면 기존 구조물을 교체 또는 개축하는 비용에 비하여 직접경비의 경우 약 80%정도의 비용을 절약할 수 있으며 이러한 직접비용의 절감 이외에도 사회간접적인 비용의 절감분은 수배에 이르게 된다. 본 연구에서는 시설물의 노후화에 따라 보수·보강방안 결정시 가장 중요한 발생된 손상의 종류와 더불어 노출환경, 시간에 따른 진행성 여부를 현장조사를 통하여 분석하였으며 이를 위하여 노후 잔교식 안벽 시설물인 광양항 제품부두 30,000DWT×3선석(L＝720m), 여수항 낙포부두 50,000DWT×2선석(L＝510m)에 대하여 정밀점검과 정밀안전진단을 실시한 결과를 가지고 발생된 손상을 형태별, 등급별 등 결정에 대하여 연구하고자 한다.

본 연구에서는 수직배치형 장치장 블록형태의 자동화 컨테이너 터미널을 대상으로 안벽에서 컨테이너의 양·적하 작업을 수행하는 안벽크레인(Q/C)에 대한 하역생산성을 평가해 보았다. 분석 대상이 되는 안벽크레인의 유형으로 기존의 싱글트롤리 타입외에 차세대 안벽크레인으로 인식되고 있는 듀얼트롤리 더블트롤리, 수직순환식의 하역방식을 가지는 네 가지 장비이다. 이들은 각기 다른 방식으로 선박의 컨테이너를 하역하며, 이들 각각에 대해 기계적 생산성과 순작업 생산성을 산출해 보았다. 특히, 안벽크레인의 순작업 생산성을 산출하기 위해 각 장비에 대한 시뮬레이션 모델을 수립하고 이를 적용한 시뮬레이션 시스템을 개발하였으며, 개발된 시뮬레이션 시스템을 통해 내 가지 안벽크레인에 대한 다양한 시뮬레이션이 수행되었다.

This study aims to analyse the coefficient used to estimate the quay capacity per year at the container terminal. The capacity of the container terminal is composed of the capacity at the quay side and the other working conditions at the back of the quay side. But when we refer the capacity of the container terminal, generally we used capacity as that of the container terminal. To estimate the quay capacity independently of the working conditions at the back of quay side, we calculate the quay capacity as th product of working hours per year, productivity of container crane and relate other coefficients, such that berth utilization, crane utilization and efficiency. So that coefficients are properly defined to reflect the other working conditions. If we calculate the quay capacity by the product of working hours modified by the berth utilization and crane productivity modified by the crane utilization and efficiency, the meaning of that coefficients must be strictly defined. So there could be no confusion to apply that coefficients to calculate the quay capacity. In this study, we exclusively define the meaning of the berth utilization, crane utilization and efficiency according to the internal-meaning of thats in the function to calculate the quay capacity. And compare each coefficients by decomposing the working hours at the terminal.