坡度和通风区间长度对综合管廊电缆火蔓延的影响研究OA
Study on the influence of slope and ventilation compartment length on cable fire development in utility tunnels
管廊纵向坡度产生的诱导气流与通风气流形成的特殊环境,对火蔓延和灾后排烟会产生很大影响.该文采用FDS(fire dynamics simulator)仿真软件,以实际综合管廊项目为工程依托,研究不同纵向坡度、通风区间长度和日常通风换气次数条件下电缆火灾发展规律.研究发现:10%坡度下右侧管廊最大火蔓延速度可达到 0.183 m/s,相较于无坡度工况提高了 22%;增加日常通风换气次数可有效抑制大坡度下的电缆火蔓延,但对于长通风区间综合管廊电缆火灾的发展影响较小.研究结果为综合管廊的消防安全设计和防护需求提供数据和技术支撑.
[Objective]The continuous expansion and intensification of urban underground space utilization are leading to increasingly complex utility tunnel designs,including structures with significant longitudinal slopes and extended ventilation compartments.In contrast to cable fires in conventional utility tunnels,the interaction between slope-induced airflow and ventilation airflow path creates a unique underground environment that significantly affects fire spread and post-fire smoke exhaust.The development of fires in these complex utility tunnels must be investigated to provide robust,evidence-based guidelines for designing safer energy infrastructure and developing more effective fire protection strategies,thereby enhancing the resilience and safety of urban underground infrastructures.This study aims to quantify the impact of tunnel slope on fire spread behavior and to evaluate how daily operational ventilation strategies affect both sloped and long-ventilation-compartment tunnels.[Methods]This study employs the numerical simulation software Fire Dynamics Simulator using an actual utility tunnel project as the engineering basis to investigate the development patterns of cable fires in utility tunnels under varying longitudinal slopes(0%,1%,3%,5%,and 10%),ventilation compartment lengths(200,400,and 600 m),and daily air exchange rates(2,4,and 6 h-1).[Results]The findings show that for utility tunnels with longitudinal slopes,the natural airflow generated by the stack effect of a cable fire interferes with combustion,flame spread,and smoke propagation,resulting in accelerated fire spread on the right side of the tunnel.At a 10%slope,the maximum flame spread rate on the right side is 0.183 m/s,a 22% increase over the zero-slope conditions.Increasing the daily air exchange rate has a greater effect on suppressing fire spread in areas with large slopes.At an air exchange rate of 6 h-1,the right-side spread range of a cable fire reduced by 9 m under a 10%slope,while it reduced only by 7 m under a 3%slope.For utility tunnels with long ventilation compartments,extending the compartment length increases the airflow travel distance,reducing airflow pressure along the tunnel and weakening the influence of the airflow on fire development.Increasing the air exchange rate has a limited impact on the development of cable fires in long ventilation compartments of utility tunnels.Compared to no-ventilation conditions,air exchange rates of 2,4,and 6 h-1 suppress fire spread only by 0.55%,0.55%,and 1.67%,respectively.[Conclusions]The aforementioned results indicate that increased air exchange rates can effectively constrain fire spread in steeply sloped tunnels by counteracting the stack effect.However,their impact is markedly diminished in long ventilation compartments due to airflow attenuation over distance.The research results provide data and technical support for fire safety design and protection requirements in actual underground utility tunnels.The quantitative data and mechanistic explanations presented in this study can inform the development of enhanced safety standards and operational protocols,ultimately mitigating the risks associated with cable fires in the increasingly complex underground lifelines of modern cities.
许德胜;李炎锋;徐勇
安徽理工大学 公共安全与应急管理学院,安徽 合肥 231131北京工业大学 建筑工程学院,北京 100124哈尔滨工业大学(深圳) 计算机与技术学院,广东 深圳 518000
信息技术与安全科学
地下空间综合管廊电缆火灾火蔓延
underground spaceutility tunnelcable firefire spread
《实验技术与管理》 2026 (1)
44-50,7
安徽理工大学高层次引进人才科研启动基金(2025yjrc0072)广东省深圳市科技计划项目(KCXFZ20211020163402004)
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