PURPOSES : This study provides fundamental information on the temperature variations in tunnel structures during severe fire events. A fire event in a tunnel can drastically increase the internal temperature, which can significantly affect its structural safety. METHODS : Numerical simulations that consider various fire conditions are more efficient than experimental tests. The fire dynamic simulator (FDS) software, based on computational fluid dynamics (CFD) and developed by the National Institute of Standards and Technology, was used for the simulations. The variables included single and multiple accidents involving heavy goods vehicles carrying 27,000 liters of diesel fuel. Additionally, the concrete material characteristics of heat conductivity and specific heat were included in the analysis. The temperatures of concrete were investigated at various locations, surfaces, and inside the concrete at different depths. The obtained temperatures were verified to determine whether they reached the limits provided by the Fire Resistance Design for Road Tunnel (MOLIT 2021). RESULTS : For a fire caused by 27,000 liters of diesel, the fire intensity, expressed as the heat release rate, was approximately 160 MW. The increase in the carrying capacity of the fire source did not significantly affect the fire intensity; however, it affected the duration of the fire. The maximum temperature of concrete surface in the tunnel was approximately 1400 ℃ at some distance away in a longitudinal direction from the location of fire (not directly above). The temperature inside the concrete was successfully analyzed using FDS. The temperature inside the concrete decreased as the conductivity decreased and the specific heat increased. According to the Fire Resistance Design for Road Tunnel (MOLIT 2021), the internal temperatures should be within 380 ℃ and 250 ℃ for concrete and reinforcing steel, respectively. The temperatures were found to be approximately 380 ℃ and 100 ℃ in mist cases at depths of 5 cm and 10 cm, respectively, inside the concrete. CONCLUSIONS : The fire simulation studies indicated that the location of the maximum temperature was not directly above the fire, possibly because of fire-frame movements. During the final stage of the fire, the location of the highest temperature was immediately above the fire. During the fire in a tunnel with 27,000 liters of diesel, the maximum fire intensity was approximately 160 MW. The capacity of the fire source did not significantly affect the fire intensity, but affected the duration. Provided the concrete cover about 6 cm and 10 cm, both concrete and reinforcing steel can meet the required temperature limits of the Fire Resistance Design for Road Tunnel (MOLIT 2021). However, the results from this study are based on a few assumptions. Therefore, further studies should be conducted to include more specific numerical simulations and experimental tests that consider other variables, including tunnel shapes, fire sources, and locations.

1. 서론
2. 도로터널 화재 특성
    2.1. 도로터널 화재 특성 일반
    2.2. 고온노출 콘크리트의 재료특성
    2.3. 터널 내 차량화재로 인한 온도분포 특성
3. 도로터널 내화 지침(국토교통부, 2021) 분석
4. 터널 화재 모사 수치해석 시뮬레이션
    4.1. 화재 모사 시뮬레이션 모델링
    4.2. 화재 사고 차량 적재용량에 따른 해석 및 결과 분석
    4.3. 콘크리트 열전도도에 따른 해석 및 결과 분석
    4.4. 콘크리트 비열에 따른 해석 및 결과 분석
5. 결론
감사의 글

• 장태진(정회원 · 강원대학교 건설융합공학과 박사과정) | Jang Taejin
• 심재원(정회원 · 한국도로공사 도로교통연구원 안전혁신연구실 선임연구위원) | Shim Jaewon
• 김기현(정회원 · 강원대학교 건설융합공학과 박사과정) | Kim Gihyun
• 하동수(정회원 · 강원대학교 토목건설공학과 석사과정) | Ha Dongsoo
• 박철우(정회원 · 강원대학교 건설융합학부 토목공학전공 교수) | Park Cheolwoo
• 김승원(정회원 · 강원대학교 건설융합학부 토목공학전공 조교수) | Kim Seungwon 교신저자