TY - JOUR
T1 - Combustion characteristics and flame morphological evolution of double-layer cable fires in urban utility tunnels with various laying spacings
AU - Xu, Desheng
AU - Li, Yanfeng
AU - Li, Junmei
AU - Zhong, Hua
AU - Li, Jiaxin
AU - Huang, Youbo
N1 - Publisher Copyright:
© 2025 The Authors
PY - 2025/1/15
Y1 - 2025/1/15
N2 - Utility tunnels serve as critical infrastructure for urban energy and electricity transport systems, housing multi-layered cable arrangements that pose significant fire hazards. This study investigates the effects of cable arrangement and layer spacing on the combustion parameters and flame evolution of double-layer cable fires, emphasising their implications for energy infrastructure safety. Using a reduced-scale utility tunnel model, we conducted fire experiments to measure the heat release rate (HRR), oxygen consumption, and fuel energy of cable combustion. The key parameters evaluated were the cable fuel energy, surface temperature, pyrolysis efficiency, and flame morphology. Our findings indicate that both total combustion time and HRR decrease with increasing layer spacing. Notably, the pyrolysis efficiency of double-layer cable fires can exceed 100 %, reaching up to 110 % at a spacing of 1 cm due to the mutual fuel effect created by the close proximity of the layers. This effect enhances the fire intensity, illustrating how the layer spacing critically influences the combustion dynamics. When the layer spacing exceeds the critical threshold, the lower cable cannot ignite the upper cable, resulting in a single-layer fire scenario. Additionally, the flame characteristics are positively correlated with increased HRR and reduced layer spacing. We analytically delineated the critical layer spacing into three distinct regions and proposed novel mathematical models to quantify the relationships between pyrolysis efficiency, flame height, and layer spacing. These insights are vital for the design of safer cable layouts and fire prevention strategies in urban utility tunnels, thereby enhancing the operational safety of energy transport systems. This study provides essential knowledge for improving fire protection measures in energy infrastructures.
AB - Utility tunnels serve as critical infrastructure for urban energy and electricity transport systems, housing multi-layered cable arrangements that pose significant fire hazards. This study investigates the effects of cable arrangement and layer spacing on the combustion parameters and flame evolution of double-layer cable fires, emphasising their implications for energy infrastructure safety. Using a reduced-scale utility tunnel model, we conducted fire experiments to measure the heat release rate (HRR), oxygen consumption, and fuel energy of cable combustion. The key parameters evaluated were the cable fuel energy, surface temperature, pyrolysis efficiency, and flame morphology. Our findings indicate that both total combustion time and HRR decrease with increasing layer spacing. Notably, the pyrolysis efficiency of double-layer cable fires can exceed 100 %, reaching up to 110 % at a spacing of 1 cm due to the mutual fuel effect created by the close proximity of the layers. This effect enhances the fire intensity, illustrating how the layer spacing critically influences the combustion dynamics. When the layer spacing exceeds the critical threshold, the lower cable cannot ignite the upper cable, resulting in a single-layer fire scenario. Additionally, the flame characteristics are positively correlated with increased HRR and reduced layer spacing. We analytically delineated the critical layer spacing into three distinct regions and proposed novel mathematical models to quantify the relationships between pyrolysis efficiency, flame height, and layer spacing. These insights are vital for the design of safer cable layouts and fire prevention strategies in urban utility tunnels, thereby enhancing the operational safety of energy transport systems. This study provides essential knowledge for improving fire protection measures in energy infrastructures.
KW - Combustion characteristics
KW - Double-layer cable fire
KW - Flame evolution
KW - Fuel energy
KW - Utility tunnel
UR - http://www.scopus.com/inward/record.url?scp=85213829275&partnerID=8YFLogxK
U2 - 10.1016/j.energy.2024.134324
DO - 10.1016/j.energy.2024.134324
M3 - Article
AN - SCOPUS:85213829275
SN - 0360-5442
VL - 315
JO - Energy
JF - Energy
M1 - 134324
ER -