Recently, many people have become interested in seismic stability enhancement and a chain of research and development be proceed for application of nuclear power plant according to increase the frequency and magnitude of earthquake event. Such as seismic isolation system is applied to general structure (architecture, bridge and LNG tank etc.) from ancient times. But the application results is limited for Nuclear power plant. In this paper, we proposed a stability of variable axial load from beyond design basis earthquake in Nuclear power plant. Also, the change of stiffness in isolator from the application of generally design equation is not equal to according to change in axial load compare with the experimental result in variable axial load. Therefore we proposed the empirical formula of design equation from test result of full-scale multi-lead rubber bearing for seismic analysis with real behavior (variable axial load) in the earthquake motion.

Rubber laminated bearings with lead core are highly affected by changes in temperature because key materials which are rubber and lead have temperature dependencies. In this study, two full scale LRB(D800, S=5) are manufactured and temperature dependency tests on shear properties are accomplished. The shear properties at the 3rd cycle are used at -10℃, 0℃, 10℃,20℃, 30℃, 40℃ respectively. The double shear configuration, simultaneously testing two pieces, is applied for compression shear test in order to minimize the friction effects due to the test machine, described in ISO 22762-1:2010. Characteristic strength, post-yield stiffness, effective stiffness, equivalent damping ratio are estimated and presented coefficient due to the temperature changes.

기존의 해상교량 기둥의 외부보강에 따른 연구들은 현재까지 주로 중앙점 재하에 따른 성능을 평가하였다. 하지만, 장대교량의 기둥은 정확한 중심축을 기준으로 축하중을 받는 경우와 편심으로 인한 큰 모멘트가 동시에 작용하는 경우가 많이 발생한다. 이 연구에서는 해상장대교량의 고강도 철근콘크리트 기둥의 하중재하 위치와 2가지의 보강 재료인 탄소섬유 및 고성능 유리섬유를 각각 보강하여 그 효과를 분석하였다. 실험에 사용된 12개의 기둥 실험체는 모두 같은 크기로 제작 및 실험을 하였다. 그 중 6개 실험체의 횡보강 철끈은 띠철근으로 배근하였으며, 그 외 6개의 실험체는 나선철근으로 매끈하였다. 그리고 각각 3겹의 탄소섬유 및 고성능 유리섬유를 적용하여 감싸기 방법으로 보강하였다. 실험변수는 하중재하 위치에 따른 철근의 보강행태 및 보강재료가 고려되었다. 실험결과, 편심축에 따른 하중재하 기둥부재는 중심축 하중재하에 비해 최대 파괴하중이 감소하였지만 고성능 유리섬유를 보강한 기둥부재는 축하중 및 편심하중에서 탄소섬유를 보강한 경우보다 내력과 연성이 우수하였다.

The sliding materials for bridge supports are used to ensure the seismic performance or to absorb thermal deformation of bridge decks. The sliding plates in the bridge-bearings directly transfer vertical loads and horizontal displacements to piers. To construct bridge economically, bridge-bearings are required to endure higher vertical load capacity. Therefore, smaller and stiffer sliding materials have been being developed to improve vertical loading capacity of bearings. In this study, friction coefficient tests were accomplished with the sliding materials applied for bridge bearings. Three different types of friction materials (PTFE, C-Lube, and UHMWPE) were tested with equivalent compressive stress, velocity, and displacement respectively. Based on the experimental results of each material, the horizontal stiffness and energy dissipation capacities of bearings were compared and analyzed through the design of the friction pendulum bearing as well.

Coefficient of friction of PTFE is used as a typical friction material of friction-type seismic isolation devices. Coefficient of friction of PTFE is decreased with increasing the contact stress, and increased with increasing the horizontal movement speed. To understand the caracteristics of new friction material, using EDS, the seismic isolation device, applying new friction material, studying the changes in the friction coefficient with various shear characteristics.

In this study, Lead Rubber Bearing(LRB) characteristics calculated by the design of the seismic isolation system, according to the seismic isolation structure with the application of nuclear power plants. Experiments were carried out to analyze the compression characteristics of prototype LRB under variable shear displacement.

This paper presents an experimental research aimed at developing a new rubber-based seismic isolator called ‘'Ball Rubber Bearing (BRB). The BRB is composed of a conventional steel-reinforced multi-layered rubber bearing with its central hole filled with small diameter steel balls that are used to provide energy dissipation capacity through friction. in this study, the shear test was performed to compare the NRB & LRB & BRB. bearing shear tests were carried out as per ISO22762 for seismic isolation design standard. A test results showed that EDC & effective stiffness of the BRB is lower than LRB.

분사식 FRP 보강 공법은 섬유(Fiber)와 수지(Resin)를 외부에서 혼합하여 요철이 많은 콘크리트 표면에 고속의 압축 공기로 랜덤하게 분사하여 기존 콘크리트 구조물을 보강하는 공법이다. 새로운 분사식 FRP 공법을 이용하여 구조물의 보강 성능을 평가하였다. 콘크리트 보 실험체에 대한 휨강도 실험을 수행하여 분사식 FRP의 최적물성치를 찾고 이 결과를 이용하여 PSC I형 거더 표준단면을 1/5로 축소한 구조물에 적용하여 실험을 하였다. 손상된 프리스트레스트 콘크리트에 적용한 결과 무보강보에 비하여 휨강도가 49.8% 증가하였고 사용상태의 거동이 개선되었으며, 보강에 의해 처짐 및 균열 제어에 효과적이었다. 결론적으로 분사식 FRP 공법의 보강 적용은 구조물의 성능 향상에 효과적이라고 할 수 있다.