FRP 보강이 RC 기둥의 내진성능에 미치는 효과를 평가하고자 다양한 실험 연구가 수행되어 왔다. 그 중 많은 연구가 휨지배를 받는 원형 단면 RC 기둥의 거동에 초점을 맞추었다. 단면 형태가 FRP 보강에 의한 구속효과에 영향을 주기 때문에, 단면 형태에 따라 보강효과 및 최종손상 양상이 다를 수 있다. 또한, 기존 RC 기둥 중 일부는 현재의 구조기준을 만족하지 못하는 설계로 인하여 취성적인 파괴 모드인 전단 파괴가 발생할 것으로 여겨진다. 이 두 가지 조건을 고려하여, 현무암 섬유를 함유한 FRP 시트와 복합섬유 패널로 보강한 정사각형 단면을 가진 짧은 RC 기둥의 전단 거동을 살펴보기 위하여 반복하중 실험을 수행하였다. 실험 결과에서 전체적인 전단 거동의 개선을 확인하였으며, 이러한 경향은 모서리 부분에서 심각한 손상이 발생할 때까지 유효하였다.

Numerical behavior of FRP(Fiber Reinforced Polymer) panel in steel frame structure was evaluated through the finite element analysis in this study. In order to numerical analysis, a experimental test results was used to develop a three dimensional finite element model of steel frame specimen. Numerical results of the steel frame specimen was well predicted the experimental behavior of steel frame specimen. Based on the developed three dimensional finite element model of steel frame specimen, the behavior of FRP panel in the steel frame specimen was evaluated. From the numerical analysis results, strength of the steel frame specimen with FRP panel was governed by FRP panel. Also, diagonal compression behavior governed the FRP panel in the steel frame specimen in the numerical analysis results.

A behavior of FRP(Fiber Reinforced Polymer) panel in a steel frame structure was evaluated through the finite element analysis in this study. In order to numerical analysis, a experimental test results was used to develop a three dimensional finite element model of steel frame specimen. Numerical results of the steel frame specimen was well predicted the experimental behavior of steel frame specimen. Based on the developed three dimensional finite element model of steel frame specimen, the behavior of FRP panel in the steel frame specimen was evaluated. From the numerical analysis results, strength of the steel frame specimen with FRP panel was governed by FRP panel. Also, diagonal compression behavior governed the FRP panel in the steel frame specimen in the numerical analysis results.

Since it is impossible to predict earthquakes, they involve more casualties and property damage compared to meteorological disasters such as heavy snow and heat waves, which can be predicted through weather forecasts. This has highlighted the need for seismic design and reinforcement. Recently, the use of composite materials as reinforcement has surged because steel plate reinforcement and section enlargement are likely to result in increased weight and physical damage to structures. This study evaluates the seismic performance of panels created from composite materials, and their guide systems. The specimens were miniature versions of actual steel structures, and displacement loads were applied in the transverse direction. Seismic performance was found to improve when structures were reinforced with seismic panels.

Because earthquakes occur within very little or no warning, they cause significant damage to property and inflict large human casualties. Seismic design and reinforcement has been extensively studied over the years, for the purpose of reducing damage from earthquakes. Composite materials are being widely used as reinforcement because the use of steel plates and section enlargement are time-consuming methods that leave physical damage to structures. This study assessed the guide system performance of FRP panels created from composite materials. Actual steel structures were reproduced in miniature form, and were subjected to transverse displacement loads. The experiments were carried out by applying two types of FRP panel guide systems to the specimens.

Five specimens were planned and conducted the experimental study in order to understand flexural performance of the pre-stressing hybrid FRP panel. As the result of test, The reinforced specimen with hybrid FRP panel and the pre-stressing specimen show the structural behavior comparison with the non-reinforced specimen

에폭시 모르타르의 적정 배합비를 결정하기 위해서 규사의 입도 조정을 통해 적정 입도비를 알아보고, 규사인 60목과 4호의 배합비를 달리한 공시체를 제작하여 각각의 압축 및 인장 실험을 실시한다. 체의 치수(mm)종류체통과 중량 백분율(%)2.51.20.60.30.15모래80-10050-9025-6010-302-102.2 규사의 입도 조정