Earthquakes of magnitude 3.0 or greater occur in Korea about 10 times on average yearly, and the number of earthquakes occurring in Korea is increasing. As many earthquakes have recently occurred, interest in the safety of nuclear power plants has increased. Nuclear power plants are equipped with many cabinet-type control facilities to regulate safety facilities, and function maintenance is required during an earthquake. The seismic performance of the cabinet is divided into structural and functional performances. Structural performance can be secured during the design procedure. Functional performance depends on the vibration performance of the component. Therefore, it is necessary to confirm the seismic performance of the components. Generally, seismic performance is confirmed through seismic simulation tests. When checking seismic performance through seismic simulation tests, it is difficult to determine the effect of frequency and maximum acceleration on an element. In this paper, shaking table tests were performed using various frequencies and various maximum accelerations. The seismic performance characteristics of the functions of electrical equipment components were confirmed through tests.

Unlike the CFT retrofit method, The EPFT retrofit method, which fills the steel tube with engineering plastic, does not require a separate concrete forming work and is a lightweight seismic Retrofit Method. In this study, an prototype model of the EPFT was proposed, and to analyze the seismic performance, an independent specimens and a reinforced concrete column were fabricated to conduct a seismic performance test. As a result of loading test of the independent specimens, the strength was increased compared to the steel tube column without internal filling, and the ductility ratio did not significantly increase due to the falling off of the weld. As a result of loading test of the concrete reinforcement specimen, the strength, ductility ratio, and energy dissipation were increased, and the number of cracks by loading step decreased compared to the non-reinforced specimen.

배관시스템은 대표적인 사회기반시설이다. 지진으로 인한 배관 손상은 심각한 피해를 초래할 수 있으므로 배관시스 템은 지진으로부터 반드시 보호되어야 할 필요가 있다. 지진은 설계기준을 초과하는 상대변위를 동반할 수 있다. 이러한 지진의 거동은 배관 이음부에 손상을 줄 수 있다. 배관시스템에서 과도한 변형이 발생할 수 있는 위치에 지진분리이음을 적용하면 내 진성능을 향상시킬 수 있다. 적층형 금속 벨로우즈는 지진과 같은 저주기 피로 하중에 대한 내구성이 우수하다. 따라서 다중 적층 형 금속 벨로우즈는 파이프의 면진 이음새로 사용할 수 있을 것으로 판단된다. 본 연구에서는 지진분리이음의 하나인 다중 적 층형 금속 벨로우즈에 대한 실험적 연구를 수행하였다. 2종류의 다중 적층형 벨로우즈 신축관이음에 대하여 단조하중 및 반복 하중재하시험을 수행하고 손상모드와 한계상태를 추정하였다. 그리고 단조재하시험과 반복재하시험의 결과를 비교 분석하였다.

최근 경주, 포항에 연이은 지진 발생으로 인하여 내진설계에 관심이 높아지고 있다. 다가구주택 필로티기둥은 수직 비정형 시스템으로 상,하부층의 강성 차이로 인하여 지진 발생 시 막대한 피해가 예상되기 때문에 다가구주택 필로티기둥의 내 진보강이 필요하다. 그러나 민간 소유인 다가구주택의 경우 막대한 비용과 시간으로 인하여 보강이 어려운 실정이다. 이에 따 라, 복합섬유패널로 에폭시 접착제 미사용으로 건식시공이 가능한 전단보강공법을 제안하고자 한다. 본 연구에서는 복합섬유패 널 보강 유무에 따른 내진보강공법의 전단내력을 실험을 통하여 검증하였고, 에폭시를 사용하지 않아 일체화 거동을 하지는 않 지만 복합섬유패널의 영향으로 전단내력은 1.46∼1.49배 증가하는 것으로 평가되었다. 따라서 다가구주택 필로티기둥의 내진보 강효과가 있을 것으로 판단된다.

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.

In this study, the seismic safety of nuclear power plant structures is evaluated and verified by performing a vibration test on a relatively simple shear wall structure. The shear walls are the prominent members of nuclear power plants and resist the seismic load. The shear wall structure is designed and manufactured to perform shaking table tests and is used to increase the accuracy of the analytical method by comparing them with the numerical analysis results. Different results will be checked and more efficient application methods will be studied depending on the method of designing reinforced concrete structures.

Recently, studies have been actively conducted on seismic design and improvement of the seismic performance of bridges, buildings, factories, and plants. In particular, heavy items that are being manufactured or waiting to be shipped from factories (such as generators, engines, and boilers) must be equipped with seismic stoppers to prevent them from moving or falling during an earthquake. Seismic stoppers should be suitably determined by the size and weight of these heavy items; however, they have no general design standard. In this study, structural analyses and seismic tests were conducted to evaluate the performance of newly designed seismic stoppers. Structural analysis was performed on three stopper models to estimate the external load at which the yield stress of the material was not exceeded. Based on the analysis results, a seismic test of the stopper was carried out in accordance with the AC156 test method. Finally, product specifications for all three seismic stopper models were determined and their static/dynamic load performance was evaluated.

This study aims to optimize the cochlea-inspired artificial filter bank (CAFB) using El-Centro seismic waveforms and test its performance through a shaking table test on a two-span bridge model. In the process of optimizing the CAFB, El-Centro seismic waveforms were used for the purpose of evaluating how they would affect the optimizing process. Next, the optimized CAFB was embedded in the developed wireless-based intelligent data acquisition (IDAQ) system to enable response measurement in real-time. For its performance evaluation to obtain a seismic response in real-time using the optimized CAFB, a two-span bridge (model structures) was installed in a large shaking table, and a seismic response experiment was carried out on it with El-Centro seismic waveforms. The CAFB optimized in this experiment was able to obtain the seismic response in real-time by compressing it using the embedded wireless-based IDAQ system while the obtained compressed signals were compared with the original signal (un-compressed signal). The results of the experiment showed that the compressed signals were superior to the raw signal in response performance, as well as in data compression effect. They also proved that the CAFB was able to compress response signals effectively in real-time even under seismic conditions. Therefore, this paper established that the CAFB optimized by being embedded in the wireless-based IDAQ system was an economical and efficient data compression sensing technology for measuring and monitoring the seismic response in real-time from structures based on the wireless sensor networks (WSNs).

기존 내진보강시스템의 문제점을 개선하기 위한 듀얼프레임형 내진보강시스템은 기존구조체, 외부보강체, 댐퍼로 구성된다. 듀얼시스템은 지진발생시 주기차이로 인하여 기존구조체와 외부보강체 사이에서 상대변형이 발생되고 이를 댐퍼가 대응하여 안정적으로 지진에너지를 흡수하여 내진성능을 확보한다. 본 논문에서는 듀얼시스템의 구조성능을 분석하기 위하여 정적반복가력실험을 수행한다. 실험결과, 듀얼시스템 실험체는 비보강 실험체와 유사한 손상상태를 나타내었다. 이와 같이 나타난 이유는 정적실험 시 기존구조체를 강제 이력 시켰기 때문이다. 하지만 하중-변형관계곡선에서 핀칭현상이 완화되는 것으로 나타났고, 안정적인 이력거동을 통하여 비보강 실험체에 비해 5.3배 더 많은 에너지를 흡수하였다. 또한 동일한 층간변형각 및 누적 변형에 대해서도 더 많은 에너지를 흡수할 수 있음에 따라 듀얼시스템을 적용할 경우 내진성능을 향상시킬 것으로 판단된다. 또한 듀얼시스템을 실무에 적용하기 위해서는 설계프로세스 등에 대한 연구가 필요하며, 본 논문을 추후 연구의 기초자료로 제시하고자 한다.

A conventional lumped-mass stick model is based on the tributary area method to determine the masses lumped at each node and used in earthquake engineering due to its simplicity in the modeling of structures. However the natural frequencies of the conventional model are normally not identical to those of the actual structure. To solve this problem, recently an updated lumped-mass stick model is developed to provide the natural frequencies identical to actual structure. The present study is to investigate the seismic response accuracy of the updated lumped-mass stick model, comparing with the response results of the shaking table test. For the test, a small size four-story steel frame structure is prepared and tested on shaking table applying five earthquake ground motions. From the comparison with shaking table test results, the updated model shows an average error of 3.65% in the peak displacement response and 9.68% in the peak acceleration response. On the other hand, the conventional model shows an average error of 5.15% and 27.41% for each response.

In this study, the effectiveness of a multi-action hybrid damper (MHD) composed of lead rubber bearing (LRB) and friction pad was verified in terms of seismic performance improvement of a frame structure. The LRB and the friction elements are connected in series, so the LRB governs the intial small deformation and the friction determines large deformation behavior. Cyclic loading tests were conducted by using a half scale steel frame structure with the MHD, and the results indicated that the structure became to have the stable trilinear hysteresis with large initial stiffness and first yielding due to the LRB, and the second yielding due to the friction. The MHD could significantly increase the energy dissipation capacity of the structure and the hysteresis curves obtained by tests were almost identical to the analytically estimated ones.

In the current research, a seismic ceiling system as one of non-structural elements in buildings has been developed by applying newly designed vertical hanger clips combined with M-bar channel clips. In order to evaluate the seismic performance of the developed system, full-scale shaking table tests of one story frame structure with the conventional ceiling system or the developed seismic ceiling system were performed with time-history responses under earthquake loads. The developed system was also evaluated by the time-history dynamic analysis. From seismic test and analysis, it was shown that the developed seismic ceiling system could give improved seismic performances to minimize displacements and damages of ceiling systems as well as enhance seismic safety of the ceiling system.

In this study, we conducted a shake table test to verify the seismic performance of the paneling system with steel truss composed of bolt connections. The control group was set to the traditional paneling system with steel truss connected by spot welding method. Test results showed that the bolted connection type paneling system has excellent deformation capacity without cracking or brittle fracture of the steel truss connection parts compared to the welding type paneling system. Furthermore, in the bolted connection type, slight damage occurred at the time of occurrence of the same story drift angle as compared with the existing method, it is considered that it has excellent seismic performance. In compliance with the performance-based design recommended for the current code (ASCE 41-13) on non-structural components, it is judged that in the case of the bolted connection type paneling system, it can be applied to all risk category structures without restriction. However, in the case of traditional paneling system with spot welding method, it is considered that it can be applied limitedly.

In order to verify the reliability of numerical site response analysis program, both soil free-field and base rock input motions should be provided. Beside the field earthquake motion records, the most effective testing method for obtaining the above motions is the dynamic geotechnical centrifuge test. However, need is to verify if the motion recorded at the base of the soil model container in the centrifuge facility is the true base rock input motion or not. In this paper, the appropriate input motion measurement method for the verification of seismic response analysis is examined by dynamic geotechnical centrifuge test and using three-dimensional finite difference analysis results. From the results, it appears that the ESB (equivalent shear beam) model container distorts downward the propagating wave with larger magnitude of centrifugal acceleration and base rock input motion. Thus, the distortion makes the measurement of the base rock outcrop motion difficult which is essential for extracting the base rock incident motion. However, the base rock outcrop motion generated by using deconvolution method is free from the distortion effect of centrifugal acceleration.

In this study, dynamic characteristics and seismic capacity of the nuclear power plant piping system are evaluated by model test results using multi-platform shake table. The model is 21.2 m long and consists of straight pipes, elbows, and reducers. The stainless steel pipe diameters are 60.3 mm (2 in.) and 88.9 mm (3 in.) and the system was assembled in accordance with ASME code criteria. The dynamic characteristics such as natural frequency, damping and acceleration responses of the piping system were estimated using the measured acceleration, displacement and strain data. The natural frequencies of the specimen were not changed significantly before and after the testing and the failure and leakage of the piping system was not observed until the final excitation. The damping ratio was estimated in the range of 3.13 ~ 4.98 % and it is found that the allowable stress(345 MPa) according to ASME criteria is 2.5 times larger than the measured maximum stress(138 MPa) of the piping system even under the maximum excitation level of this test.

본 연구에서는 지진시 앵커기초의 파괴한계성능을 평가하기 위하여 진동대 실험을 수행하였다. 앵커기초에 발생 가능한 열화현상인 균열의 영향을 평가하기 위하여 균열이 없는 시편, 관통균열 시편 그리고 파괴예상면 내에 측면균열이 있는 시편을 제작하여 각각의 파괴한계성능을 평가하였다. 우선적으로 임팩트 해머에 의한 가진 실험을 통하여 동특성분석실험을 수행하여 실험모형의 동특성을 분석하였으며, 앵커기초의 파괴 시까지 진동대 실험을 수행하여 극한거동을 평가하였다. 최종적으로 앵커기초의 설계기준과 비교하여 거동특성을 분석하였다.

합성 교각의 설계에서 요구 내진성능을 만족하기 위한 철근상세 규정이 명확하지 않은 측면이 있다. 합성 교각은 단면치수를 감소시키고 지진하중하에서 기둥의 연성을 개선하기 위해 제안되었다. 이 논문에서는 400mm 직경을 가진 단일 강재를 콘크리트에 매입한 합성기둥 부재를 5기 제작하여 합성기둥의 내진성능을 연구하였다. 진동대 실험과 유사동적 실험이 수행되었는데 근단층지반운동을 고려한 축소모형의 구조적 거동이 평가되었다. 실험 변수는 횡철근의 간격, 주철근의 겹침이음, 매입 강재 단면으로 설정하였다. 진동대 실험에 의해 평가된 변위연성도가 유사동적 실험에 비해 적게 나타났고 한정연성설계, 주철근의 겹침 이음 50%를 가진 부재가 기준 부재에 비해서 낮은 연성도를 보였다. 강재비는 극한강도에 영향을 미치고 겹침이음과 횡철근 비의 감소는 변위능력을 감소시켰다. 합성 교각의 상세에 따른 에너지 소산능력의 차이는 뚜렷하게 나타나지 않았다.

본 연구에서는 교량의 내진보강을 위하여 기존 교량에 지진격리장치를 추가하는 접근법을 제안하였다. 기존 받침을 지진 격리받침으로 완전히 대체하는 접근법도 이미 제안되어 있지만 본 연구에서는 경제성과 안전성을 고려하여 기존 받침을 제거하지 않고 활용하도록 하였다. 이는 지진격리받침이 상부 수직하중을 분담하지 않고, 수평방향의 지진운동에 대한 주기 이동과 감쇠 역할만 한다. 이 접근법의 실험적 검증을 위해 실제 교량을 대상으로 납-적층고무받침(LRB)을 설계하고 실물크기로 기존 받침과 LRB를 제작하였다. 이 지진격리시스템의 가상 지진입력에 대한 응답은 유사동적실험으로 구하였다. 아울러 범용해석프로그램을 통한 지진응답해석과 비교하여 실험결과의 신뢰성을 확인하였다. 실험결과 제안된 지진격리시스템은 지진시 안정적인 거동을 보였다.