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Abstract

Sealing shaft vents is an effective method of controlling fires in utility tunnels. A sealing strategy was scientifically developed in order to investigate the impact of varying sealing ratios on cable fires in utility tunnel shaft vents. In this paper, cable compartment fires with different sealing ratios were simulated by using Fire Dynamics Software (FDS). And the influence of the sealing strategy on the temperature, smoke dispersion and flow field characteristics of the cable compartment ceiling were analyzed. The results showed that the degree of the shaft sealing significantly impacts the temperature gradient and smoke dispersal patterns within the utility tunnel. When the sealing rate exceeds 75%, due to the accumulation of high-temperature smoke in utility tunnels and the continuous consumption of oxygen, fires are more prone to self-extinguishment. A ceiling temperature prediction model was developed that provides reasonable predictions for fire scenarios considering different sealing ratios. Under different sealing conditions, high concentrations of smoke may accumulate in utility tunnels, which should be considered in firefighting and rescue operations.

Practical Application

This study provides valuable insights into the practical implications of controlling and mitigating the impact of fires in the cable compartment of utility tunnel. By understanding the sealing effect role of cable compartment of utility tunnel and providing a quantitative tool for smoke spread law assessment, this study contributes to the enhancement of safety measures and the protection of lives in utility tunnels during fire incidents.

Keywords

Sealing ratio flow field distribution natural ventilation stack effect

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References

Wang

Tan

Xie

, et al. Development and applications of common utility tunnels in China. Tunn Undergr Space Technol 2018; 76: 92–106.

Broere

. Urban underground space: solving the problems of today’s cities. Tunn Undergr Space Technol 2016; 55: 245–248.

Tang

Liang

, et al. Study on temperature distribution and CO diffusion induced by cable fire in L-shaped utility tunnel. Sustain Cities Soc 2020; 62: 102407.

Luan

Bielawski

, et al. Fire and smoke transport dynamics in a dead-end tunnel under heavy rainfall. Int J Heat Mass Tran 2025; 236: 126270.

Wang

Liang

, et al. Effects of interlayer distance and cable spacing on flame characteristics and fire hazard of multilayer cables in utility tunnel. Case Stud Therm Eng 2020; 22: 100784.

Huang

Wang

Zeng

, et al. Compartment temperature estimation of a multiple-layer cable tray fire with different cable arrangements in a closed compartment. J Fire Sci 2019; 37: 303–319.

Wang

. Experimental study on flame spread and extinction over horizontal power cables under longitudinal ventilation in a utility tunnel. Therm Sci Eng Prog 2023; 39: 101752.

, et al. Evaluating the combustion and flame extension characteristics of cable fire in utility tunnels with spontaneous combustion scenarios: an experimental study. Tunn Undergr Space Technol 2023; 140: 105244.

Luan

Bielawski

Fan

, et al. Numerical simulation of the impact of rainfall on tunnel fire. Case Stud Therm Eng 2024; 62: 105186.

10.

Liu

Jiao

, et al. A numerical study on the optimization of ventilation mode during emergency of cable fire in utility tunnel. Tunn Undergr Space Technol 2020; 100: 103403.

11.

Liang

Hao

, et al. Study on cable fire spread and smoke temperature distribution in T-shaped utility tunnel. Case Stud Therm Eng 2019; 14: 100433.

12.

Zhou

Zheng

, et al. Estimating the longitudinal maximum gas temperature attenuation of ceiling jet flows generated by strong fire plumes in an urban utility tunnel. Int J Therm Sci 2019; 142: 434–448.

13.

GB 50838-2015 . Technical code for urban utility tunnel engineering. Beijing: China Planning Press, 2015.

14.

Zhang

Ren

, et al. Experimental and simulation study on cable fire extinguishing by smothering in utility tunnel. Journal of Safety Science and Technology 2023; 19(02): 173–179.

15.

Han

Chen

Tan

, et al. Field investigation of fire and smoke spreading characteristics in the high-altitude tunnel with strongly longitudinal ventilation. Tunn Undergr Space Technol 2025; 155: 106235.

16.

Zhang

Zhao

. Study on underground utility tunnel fire characteristics under sealing and ventilation conditions. Adv Civ Eng 2020; 1: 9128704.

17.

Jia

Xia

Ning

, et al. Research on the fire extinguishing efficiency of low-pressure water mist in urban underground utility tunnel cable fires. Fire 2023; 6(11): 433.

18.

Kang

Wang

, et al. Experimental study on the effect of sealing behavior on smoke temperature characteristics in tunnel fires. Therm Sci Eng Prog 2023; 40: 101784.

19.

Liu

Zhu

Pan

, et al. Experimental investigation of fire temperature distribution and ceiling temperature prediction in closed utility tunnel. Case Stud Therm Eng 2019; 14: 100493.

20.

Huang

Dong

, et al. Numerical investigation on the maximum ceiling temperature and longitudinal decay in a sealing tunnel fire. Tunn Undergr Space Technol 2018; 72: 120–130.

21.

Yao

Cheng

Shi

, et al. Experimental study on the effects of initial sealing time on fire behaviors in channel fires. Int J Therm Sci 2018; 125: 273–282.

22.

Pan

Zhu

Wang

, et al. Experimental investigation of maximum temperature and longitudinal temperature distribution induced by linear fire in portals-sealed tunnel. Case Stud Therm Eng 2021; 23: 100804.

23.

Liu

Zhu

Pan

, et al. Study on fire behavior of cable in utility tunnel under different initial oxygen concentrations. Heat Tran Res 2022; 54: 11–24.

24.

Shi

Zuo

Xiong

, et al. Experimental study of different sealing ratios on the self-extinction of tunnel fires. Tunn Undergr Space Technol 2021; 112: 103894.

25.

Guo

Fan

, et al. Temperature distribution of coal mine tunnel fire during dynamic sealing process: a numerical study. Combust Sci Technol 2024; 196: 55–72.

26.

McGrattan

Forney

Floyd

, et al. Fire dynamics simulator (Version 5): User’s guide. US Department of Commerce, Technology Administration, NIST, 2005.

27.

Wang

Cai

Zhang

, et al. Numerical simulation of fire smoke control methods in subway stations and collaborative control system for emergency rescue. Process Saf. Environ 2021; 147: 146–161.

28.

Chen

Liu

Huang

, et al. Research on the effect of ceiling centralized smoke exhaust system with air curtains on heat confinement and plug-holing phenomenon in tunnel fires. Process Saf. Environ 2023; 169: 646–659.

29.

Zhao

Obadi

, et al. Plug-holing height and complete plug-holing phenomenon in naturally ventilated tunnel fires with vertical shaft. Tunn Undergr Space Technol 2021; 107: 103631.

30.

Tang

Gao

Shan

, et al. Study of the fire behavior of multilayer cables in a mine tunnel. Energies 2022; 15: 2059.

31.

Pan

Hostikka

Zhu

, et al. Experimental investigation and numerical simulation of transverse heat flux attenuation during fire in utility tunnel. Tunn Undergr Space Technol 2023; 142: 105411.

32.

Wang

Shi

Zhai

, et al. Experimental and numerical study on smoke evolution in polyethylene (PE) slabs enclosed compartment fire. Combust Sci Technol 2020; 192: 2238–2258.

33.

Zhong

, et al. Investigation of the fire hazard of underground space fire scenarios in urban metro tunnels under natural ventilation: analysis of the impact of tunnel slope on smoke back-layering length. Build Serv Eng Res Tecnol 2024; 45: 161–184.

34.

Bai

Zhang

, et al. Experimental study on the influence of sealing and ventilation on the fire characteristics near the wall of utility tunnel. IAENG Int J Appl Math 2024; 54(5): 866–870.

Study of fire characteristics affected by sealing in the cable compartment of a utility tunnel

Abstract

Practical Application

Keywords

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References