Simulation of Fire Evacuation in a Naturally Ventilated Bifurcated Tunnel

Chen, Jianhong; Hu, Zekun; Yang, Shan

doi:10.3390/fire7060202

Fire

2024

DOI: 10.3390/fire7060202

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Simulation of Fire Evacuation in a Naturally Ventilated Bifurcated Tunnel

Jianhong Chen,

Zekun Hu,

Shan Yang

Abstract: The natural wind velocities in tunnels under different natural conditions are distinct, and the longitudinal ventilation velocity significantly impacts the evacuation environment. This paper examines the evacuation conditions and strategies under varying wind velocities in bifurcated tunnels. Using Fire Dynamics Simulator (FDS) and Pathfinder software, the fire development and evacuation of three distinct longitudinal positions in a bifurcated tunnel are simulated. The simulation results demonstrate that the e… Show more

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Cited by 2 publications

References 33 publications

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Experimental and Numerical Study of Air Flow Reversal Induced by Fire in an Inclined Mine Working

Levin,

Popov,

Semin

et al. 2024

Applied Sciences

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Effective fire prevention in mine workings and tunnels requires a thorough theoretical analysis of the heat and mass transfer processes within these structures. This involves using established models to calculate non-isothermal air flow dynamics in long tunnels and mine workings. While the ventilation of tunnels has been extensively studied, significant challenges persist regarding mine ventilation systems, particularly due to their complex and branched topology. This study aimed to address these challenges and gaps in mine ventilation. We designed a laboratory bench to simulate an inclined mine working with a heat source (fire) and validated a mathematical model of heat and mass transfer in such settings. Using experimental measurements, we verified the model’s accuracy. It is important to note that our experimental and theoretical analyses focused solely on the thermal effects of a fire, without considering the release of harmful impurities. Using the validated model, we conducted multiparameter simulations to identify the conditions leading to the formation of a thermal slug in an inclined mine working and the subsequent reversal of air flow. The simulation data enabled us to determine the dependency of the critical heat release rate on the aerodynamic parameters of the mine working. Additionally, we evaluated the changes in average air density within a mine working at the critical heat release rate. These findings are crucial for the further development of a network-based method to analyze air flow stability in mine ventilation networks during fires.

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Experimental and Numerical Study of Air Flow Reversal Induced by Fire in an Inclined Mine Working

Levin,

Popov,

Semin

et al. 2024

Applied Sciences

View full text Add to dashboard Cite

show abstract

Study on Smoke Characteristics in Cavern Complexes of Pumped-Storage Power Stations

Hu,

Xu,

Liu

et al. 2024

Fire

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The underground power houses of pumped-storage power stations (PSPSs) are highly complex, with interconnected and multidimensional structures, including various tunnels, such as the main and auxiliary power houses (MAPH), main transformer tunnel (MTT), tailrace gate tunnel (TGT), access tunnels (ATs), cable tunnels (CTs) etc. During intensive civil construction and electromechanical installation, fire risk becomes particularly prominent. Current research mainly examines fire incidents within individual tunnels, lacking comprehensive analyses of smoke spread across the entire cavern network. Therefore, in this study, a numerical model of a cavern complex in a PSPS was established to analyze smoke behavior and temperature distribution under various fire scenarios. The results indicated that when a fire occurred in the MAPH, the fire risk was relatively higher compared to fires in other places. Using the example of smoke spread from the MAPH to the MTT, the smoke spread process through key connecting caverns was analyzed. Initially, the temperature and velocity were stable, and the CTs and traffic cable tunnel in the auxiliary powerhouse (TCTAP) were the main smoke paths. After 7 min, the heat release rate (HRR) became stable, and CTs and ATs became the main paths for smoke spread, which could provide a reference for improving fire design in underground cavern systems.

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Simulation of Fire Evacuation in a Naturally Ventilated Bifurcated Tunnel

Cited by 2 publications

References 33 publications

Experimental and Numerical Study of Air Flow Reversal Induced by Fire in an Inclined Mine Working

Experimental and Numerical Study of Air Flow Reversal Induced by Fire in an Inclined Mine Working

Study on Smoke Characteristics in Cavern Complexes of Pumped-Storage Power Stations

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