In recent years the tunnel construction is increasing worldwide because of development of science and technology and increasing of transportation demand. Tunnels are complex structures normally rectangular cross section or semicircular and constructed to connect between different sections of roads. Because of the importance, the construction and extension of road tunnels are also continuously increasing along with the development. According to data from the Korea Expressway Corporation, the number of road tunnels, which was 1,332 in 2010, increased rapidly by about 2.1 times over 10 years to a total of 2,742 in 2020. The extension of road tunnels is also on the trend of increasing, with a total of 945 km in 2010 reaching 2,157 km in 2020. The benefits of a double-deck tunnel are emphasized, particularly in terms of construction cost and convenience. This tunnel design incorporates a central slab, dividing the tunnel into upper and lower spaces. The versatility of a double-decker tunnel is evident in its ability to accommodate various uses for both levels. For instance, the upper level can function as vehicle roads, while the lower level can be designated for train tracks. In this study, the effect of RWS and modified hydrocarbon fire curve was applied to the concrete tunnel bracket through simulation to analyze the temperature after the fire occurrence.

본 연구는 도시철도 터널내 화재시 구조체의 내화성능을 평가하기 위한 기준을 제시하고자 실시하였다. 현재 국내 도심의 지하철 터널 구간은 135㎞로써 그 규모가 세계 4위 이며 대도시들의 도시철도 터널건설의 증가와 그 연장이 길어짐에 따라 터널 내 화재사고가 갈수록 높아지고 있는 상황이다. 하지만 국내에는 도시철도 터널 화재에 대한 내화성능평가에 기본적으로 적용되는 시간-온도 곡선이 없다. 따라서 본 연구에서는 국내 도시철도 터널의 통행량, 차량 종류 등을 고려한 열방출율을 기초로 외국에서 제시된 시간-온도 곡선을 검토하였으며 국내 실정에 맞는 설계화재 모델을 제시하였다. 또한 제시된 설계화재모델에 대해 수치해석을 통하여 화재시 도시철도 터널 구조체의 온도분포를 산정하였다.