This paper presents an analytical approach to evaluate a possibility of progressive collapse of reinforced concrete frame structure. In order to simulate adequate behavior of the structure, we considered the bond failure of lap spliced bars due to concrete crack in a plastic hinge region. Bond characteristic was modeled in the analysis by using previous bond-slip relation and the effect of it was evaluated. Analysis result gave that there was additional deflection due to the bond failure of bar in beams at the node where the increasing displacement load was applied.

The objective of this research is to investigate the inelastic behaviour, failure mode and depth of neutral axis of square reinforced concrete bridge piers with hollow cross section under constant axial load. The nonlinear analysis computer program, named RCCOL, for the analysis of reinforced concrete column was used.

횡방향으로 프리스트레스가 도입된 장지간 PSC 바닥판의 정적 거동을 예측하기 위한 유한요소해석 모델을 구성하고, 해석결과를 선행연구에 의한 실험결과와 비교하였다. 유한요소해석에 의하여 서로 다른 콘크리트 강도와 프리스트레스 크기를 변수로 갖는 각각의 실험체에 대한 하중-처짐 관계 곡선을 비교적 근접하게 추정할 수 있었다. 또한, 변형률 분포와 변수에 따른 극한강도 변화로부터 펀칭전단에 의한 파괴형태와 손상범위 등을 간접적으로 예측할 수 있었다. 이 연구에서 활용된 유한요소해석 모델은 펀칭전단파괴에 의한 펀칭콘의 분리를 사실적으로 재현하기 위한 목적이 아니며, 실험연구를 위한 보조적 수단으로서 정적거동예측과 실험결과의 보완 등에 효과적으로 활용될 수 있을 것으로 판단된다.

This study aims at the analyze of unsteady downstream flow due to dam failure along dam failure scenario and applied to Yeoncheon Dam which was collapsed August 1st 1999, using HEC-RAS simulation model. The boundary conditions of this unsteady flow simulation are that dam failure arrival time could be at 02:45 a.m. August 1st 1999 and failure duration time could be also 30 minutes. Downstream 19.5 km from dam site was simulated for unsteady flow analysis in terms of dam failure and non-failure cases. For the parameter calibration, observed data of Jeonkok station were used and roughness coefficient was applied to simulation model. The result of the peak discharge difference was 2,696 to 1,745 m³/sec along the downstream between dam failure and non-failure and also peak elevation of water level showed meanly 0.6m difference. Those results of these studies show that dam failure scenarios for the unknown failure time and duration were rational because most results were coincident with observed records. And also those results and procedure could suggest how and when dam failure occurs and downstream unsteady flow analyzes.

This study aims at the estimation of dam failure time and dam failure scenario analysis of and applied to Yeoncheon Dam which was collapsed August 1st 1999, using HEC-HMS, DAMBRK-FLDWAV simulation model. As the result of the rainfall-runoff simulation, the lancet flood amount of the Yeoncheon Dam site was 10,324 m3/sec and the total outflow was 1,263.90 million m3. For the dam failure time estimation, 13 scenarios were assumed including dam failure duration time and starting time, which reviewed to the runoff results. The simulation time was established with 30 minutes intervals between one o'clock to 4 o'clock in the morning on August 1, 1999 for the setup standard for each case of the dam failure time estimation, considering the arrival time of the flood, when the actually measured water level was sharply raising at Jeongok station area of the Yeoncheon Dam downstream, As results, dam failure arrival time could be estimated at 02:45 a.m., August 1st 1999 and duration time could be also 30 minutes. Those results and procedure could suggest how and when dam failure occurs and analyzes.

In this study is analysis which dams breach shapes are effect on peak discharge of dam-failure. The dam breach shapes and failure time are important peak discharge when dam failure. When dam failure times are 1hr, 2hr and 3hr condition for the ECRD and 0.1hr and 0.2hr for the CG and CFRD that breach shapes changed base length Bb=1Hd, Bb=2Hd and Bb=3Hd. As the results from DAMBRK(Dam Break model) peak discharge are increase base widths lengthen. As failure time is longer then peak discharge is decrease. So peak discharge is increase more short of dam failure time. Also peak discharge is increase become larger dam breach shapes.

본 논문에서는 복합재료로 만들어진 단순지지된 샌드위치 슬래브 교량의 설계 방법을 제시하고자 한다. 거더나 가로보를 포함한 대부분의 교량시스템에서 교량 상판은 특별직교이방성판으로 거동한다. 이러한 단면을 갖는 시스템은 Navier 해법이나 Levy 해법 형태와는 다른 경계조건 또는 불규칙한 단면을 갖게 되어 해석적 해법을 얻기가 쉽지 않다. 이러한 문제를 해석하기 위하여 유한차분법이 이용되었다. 복합재료로 이루어진 교량을 설계하기위하여, 단면은 가장 경제적이면서 응력에 유리한 폼코어 형태를 채택하였고, 응력을 산출함에 있어서는 유한차분법 프로그램을 이용하였다. 복합신소재 특수기술자의 실험을 기초로 질량이 증가에 따른 파이버의 인장강도 감소를 나타내는 공식을 도출하였다. 이 공식으로부터 치수 증가에 따른 인장강도 감소량을 구 할 수 있다. 파괴강도는 Tasi-Wu의 파괴강도이론을 이용하였다. 파괴강도해석은 본 논문에서 제시하고 있는 인장강도의 감소를 고려하여 제시하였다.