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A platform for research: civil engineering, architecture and urbanism
Numerical simulations on fire spread and smoke movement in an underground car park
AbstractThe Fire Dynamic Simulator code is used to investigate fire spread and smoke movement in a large underground car park under different fire scenarios. Initially, by comparing with experimental results of heat release rate of a single car fire, the development of car fire is designed by letting surface densities of the fuel over the car. Fire spread and movement of smoke are then investigated under different ventilation conditions. Simulated results show that the development of car fire in the underground car park can be classified into four stages; namely an initial stage, a developed stage, an extinction and re-burning stage and another fast-developed stage. Affected by ventilation systems, fire develops rapidly resulting in consuming most oxygen quickly followed by early extinction of the fire. After extinction of the fire, with more ambient air drawn into the car park due to ventilation, re-ignition takes place with accelerated development. In addition, detailed field distributions of temperature and velocity vectors are given. It is found that the smoke layer decent to the top of the car after 15min and the hot smoke flows in a disorderly manner resulting in the spread of fire more rapidly.
Numerical simulations on fire spread and smoke movement in an underground car park
AbstractThe Fire Dynamic Simulator code is used to investigate fire spread and smoke movement in a large underground car park under different fire scenarios. Initially, by comparing with experimental results of heat release rate of a single car fire, the development of car fire is designed by letting surface densities of the fuel over the car. Fire spread and movement of smoke are then investigated under different ventilation conditions. Simulated results show that the development of car fire in the underground car park can be classified into four stages; namely an initial stage, a developed stage, an extinction and re-burning stage and another fast-developed stage. Affected by ventilation systems, fire develops rapidly resulting in consuming most oxygen quickly followed by early extinction of the fire. After extinction of the fire, with more ambient air drawn into the car park due to ventilation, re-ignition takes place with accelerated development. In addition, detailed field distributions of temperature and velocity vectors are given. It is found that the smoke layer decent to the top of the car after 15min and the hot smoke flows in a disorderly manner resulting in the spread of fire more rapidly.
Numerical simulations on fire spread and smoke movement in an underground car park
Zhang, X.G. (author) / Guo, Y.C. (author) / Chan, C.K. (author) / Lin, W.Y. (author)
Building and Environment ; 42 ; 3466-3475
2006-11-06
10 pages
Article (Journal)
Electronic Resource
English
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