The Integrated Water Infrastructures Safety Management Platform(WINS+) provides safety information of water infrastructures such as dams, weirs, bridges, cut slopes, retaining walls and levees designated as the first class infrastructures to be maintained according to the nations’s safety law. The WINS+ is incorporated with a computerized Standard Operating Procedure (SOP) system that provides crisis warning level (green/blue/yellow/orange/red) to central and individual disaster response managers of waterside structures. Thus it is expected that by using the WINS+ we may strengthen disaster responsiveness and reduce the time for recovery and response at emergency.

The river levees along the state owned rivers or local rivers are a major infrastructure of the nation, and it is necessary to be able to quickly and accurately evaluate the safety of each structure in case of a disaster such as flood or earthquake, so as to enable preemptive disaster response. In this study, a “real-time safety assessment method of river levees” was developed to understand the safety of river levee in real time and cope with disaster situations preemptively and effectively, and its applicability was examined. The real-time safety evaluation method of the river embankment developed in this study is based on two systems; ① real-time monitoring system by instruments and ② safety evaluation DB system of river embankment based on fragility curves using numerical analysis results. In order to validate its applicability, the safety of Munsan levee located in the upstream area of Kangjeong-Goryeong Weir was evaluated by applying the proposed method.

A series of disaster response drill was conducted using a robust and integrated safety management platform (WINS+) which can provide multi-functions of safety evaluation in realtime, disaster information provision and recovery actions for major water infrastructures, which are designated as nation’s first class infrastructures, under natural disasters such as floods or earthquakes. It is believed that the experience of disaster response drills using the new integrated safety management system (WINS+) enhances our capability of preparedness and response against disasters, and that the validity of WINS+ can be clearly confirmed.

As the frequency and period of earthquakes are increasing compared to the past, interest in the safety of rescue facilities including bridges a lot of. The correlation between the statistical index and the surrounding environment was analyzed by using the seismic acceleration measurement data of the bridge.

Numerical behavior of reinforced concrete(RC) column with GFRP seismic reinforcement was evaluated through the finite element analysis in this study. For the numerical analysis, a experimental test results was used to develop a nonlinear three dimensional finite element model of RC column with GFRP seismic reinforcement. The developed the nonlinear three dimensional finite element model of RC column with GFRP seismic reinforcement was well predicted the behavior, maximum strength and initial stiffness, of RC column with GFRP seismic reinforcement.

Numerical behavior of GFRP(Fiber Reinforced Polymer) infill 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. Based on the developed three dimensional finite element model of steel frame specimen, the behavior of GFRP infill panel in the steel frame specimen was evaluated. From the numerical analysis results, strength of the steel frame specimen with GFRP infill panel was governed by GFRP infill panel. Also, diagonal compression behavior governed the GFRP infill panel in the steel frame specimen in the numerical analysis results.

A finite element analysis modeling is proposed to evaluate welding joint part of steel-frame. Based on the experimental results, A finite element analysis model was proposed to analyze the welding joint of steel-frame specimens. The numerical results predicted the experimental behavior of the welding joint of steel-frame specimens well. Therefore, it is possible to use the proposed finite element analysis model to evaluate middleand low-rise steel-frame buildings constructed in South Korea.

It's effective further to use an easy modeling to reduce an numerical analysis cost. There are three kinds for the way to model a RC(Reinforced Concrete) pier by a FE(Finite Element) modeling, using a Solid element, Plane stress element and Beam element. Pushover analysis was executed to three kinds of modeling and a model was improved to raise the validity to the modeling.

In the past, criteria and procedures for the design of concrete structures were primarily based on allowable stresses for structural components. However, it is now well recognized that the limit state approach is a better basis for design since it is difficult to determine the real safety margin of submerged structure.

현대의 구조물은 고층화, 대형화 되어가는 추세이다. 보통중량 콘크리트는 강도에 비해 질량이 크기 때문에 구조물의 자중을 증가시킨다는 단점이 있다. 그러므로, 추세에 맞는 콘크리트의 경량화가 필요한 실정이다. 콘크리트의 경량화 방법 중 하나가 경량골재를 사용한 경량골재 콘크리트이다. 하지만, 국내에서는 경량골재 콘크리트에 대한 인식부족으로 인하여 구조용 경량골재 콘크리트에 대한 연구가 부족한 실정이다. 경량골재 콘크리트에 사용되는 경량골재의 품질에 따라 콘크리트의 물성 및 강도에 대한 검증이 필요하다. 본 연구에서는 보통골재와 경량골재를 사용한 콘크리트를 제작하고 인장균열파괴실험을 통해 하중－CMOD곡선은 얻고, 이를 역해석하여 파괴에너지를 도출하였다.

This paper is developed the viscoelastic dumpers whose multilayer system absorbs weight transmitted to framed structure sliding down along specific layer elements. Experiments with and without viscoelastic dumpers were carried out. According to the results, I could confirm that interstory drift ratio of steel frame structure has effectively decreased on both 1st and 2nd floor compared to that of before.

This study is to evaluate compressive behavior of confined concrete cylinders using various materials. Materials are tape, velcro, fishline, frp and scratch film. At compressive strength test result, load of confined concrete cylinder using velcro and fishline was slowly decreased after ultimate strength. Also, confined concrete cylinder using tape and frp seem to increase the compressive strength.

강교의 정확한 피로균열의 발생원인 또는 교량의 피로안전성을 검토하기 위해서는 적합한 응력이력 측정이 요구된다. 그러나 실제 현장에서의 응력이력 측정은 현장 여건과 경제성, 작업성 등의 이유로 1개소의 스트레인게이지를 설치하여 계측을 실시한다. 이는 특정 구조물의 실제 치수와 게이지 길이 용접부 응력집중 등의 영향을 고려하지 못하고, 구조 모델링을 통한 응력해석에도 많은 어려움이 있다. 그러므로 본 연구에서는 용접단부에 다수의 게이지 설치, 최소 길이 게이지 사용, 설치 위치 등의 개선된 방법을 적용하여 용접단부와 스트레인게이지 설치 거리에 따른 변형률 진폭에 대한 상관식을 도출하고 국제용접협회 (IIW)의 제안식과 비교하였다. 또한 적합한 피로등급 상세범주 선정을 통해 공용중인 교량의 피로손상도 평가 및 잔존수명을 예측하고 분석하였다. 그 결과 피로균열 발생빈도가 높은 부재파악, 용접단부와 게이지 설치 거리에 따른 변형률의 정량적 파악으로 정확한 피로손상도 평가 및 잔존수명 예측이 가능하므로 향후 교량의 응력이력계측 시 개선된 방법을 적용해야 할 것이다.

최근 발생한 대규모 지진으로 구조물의 내진보강에 대한 사회적 관심도가 높아지고 있다. 특히 내진설계가 반영되지 않은 기둥의 경우 지진에 의한 횡하중을 저항하지 못하고, 취성적인 파괴가 유발되어 구조물 전체적 붕괴를 유발할 수 있다. 따라서 빠른 시간내에 보강이 가능하면서 기둥에 손상을 주지 않는 기존의 보강법과 구별되는 응급 보강법이 필요하다. 과거에는 기둥 보강법으로 단면 증설법과 강판보강법 등이 개발되어 현장에 적용되었지만, 최근에는 FRP (Fiber Reinforced Polymer)의 장점을 활용한 탄소섬유시트공법이 많이 사용되고 있다. 본 연구에서는 긴급시공이 가능한 체결식 FRP 내진보강재를 사용한 구조물의 내진성능보강효과를 검토하고자 하였다. 검토를 위하여 실제 구조물의 축소모델의 철근콘크리트 시험체를 제작하고 횡방향 변위하중을 가력하였다. FRP 내진보강재를 이용한 내진보강시공후 실내시험을 통하여 내진성능을 평가하였다. 그 결과 개발된 보강재의 철근콘크리트 구조물에 보강 시, 내진성능이 향상됨을 확인하였다.

In this study, pure torsion tests were performed for a square cross-section reinforced concrete beams. Stirrup spacing and yield strength of the material was used to the experimental variables. From the test results, large torsional strength were occurred in specimens, which have small stirrup spacing. when, stirrup spacing was greater than the cross-sectional depth, regardless of the stirrup strength, maximum torsional strengths were nearly the same. Contrary, stirrup spacing was less than the cross-sectional depth, according to the stirrup strength, maximum torsional moment were largely. Lastly, the cracks of the beam much occurred in smaller stirrup spacing specimens.

Post-installed anchor is installed in non-cracked concrete after corrosion to investigate pullout strength of the anchor. Pullout test was conducted diameter, insertion depth of the anchor of a couple of variables. If it receive pullout load, performance of corroded anchor is degraded by the reduction of the cross-section of the anchor body.

In this study, we model the pillars was actually performed finite element analysis while changing the amount of reinforcement in the top and bottom of the column the FRP sheet. The behavior of reinforced concrete structures and reinforced by examining the optimal amount of FRP reinforcement decided.

Social interest in the seismic retrofit of the structure is growing massive earthquake that occurred recently. The brittle fracture of Non-seismically designed Columns lead to full collapse of the building. In the past, cross-sectional expansion method, a steel plate reinforcing method is applied mainly in recent years, fiber-reinforced method utilizing the advantages of the composite material are preferred. However, the reinforcement methods such as this, there is a drawback to induce physical damage to structures, and time consuming work space is large. IIn this study, FRP seismic reinforcement was developed using the Aluminum connector and the composite material (Glass Fiber Reinforced Polymer). Then, the optimum quantities of FRP seismic reinforcement was determined using a nonlinear finite element analysis program. Finally, the quantity decision process through the design and analysis of FRP reinforcement was suggested.

In this study, performance of the post-installed anchor system was evaluated with reduced strength of concrete and anchor. One of the post-installed anchors was selected to performance evaluation. Concrete strength was reduced by freeze-thawing test, and the post-installed anchor strength was reduced by corrosion test. The post-installed Anchor was installed in concrete of freezing and thawing and original concrete, and corroded anchor was installed in original concrete only. Anchor diameter and installation depth of the anchor were the variable for each specimen. Performance of post-installed anchor system of each specimen was evaluated by pullout test. Anchor diameter and installation depth of anchor, it may affect the performance of the post-installed anchor system from the experimental test results. Fracture mode of each post-installed anchor system had occurred differently depending on the durability of concrete and anchor. The anchor pullout strength from the experimental test results was used in order to compare with the results of CCD (Concrete Capacity Design) method, and CCD equation was modified. Modified equation was able to predict the anchor pullout strength of post-installed anchor system in Original concrete and freezing and thawing of concrete.

In this study, thickness of FRP sheet on Connector, which did not cause any physical damage to concrete column, was decided by using nonlinear finite element analysis. Through this analysis, the optimal thickness was determined by a thickness of the Glass Fiber sheet