Abstract
In room–corridor building geometry, the corridor smoke temperature is of great importance to fire protection engineering as indoor fires occur. Theoretical analysis and a set of reduced-scale model experiments were performed, and a virtual fire model was proposed, to investigate the correlations between the maximum smoke temperature in corridors and the smoke temperature in rooms. The results show that the dimensionless virtual fire heat release rate (HRR) is characterized by quadratic-polynomial of the dimensionless smoke temperature in fire rooms. The dimensionless distance from a virtual fire source to the corridor ceiling varies linearly with the dimensionless smoke temperature in a room. Results of multiple regression indicate that, at the impingement area of virtual fire, the dimensionless maximum smoke temperature in corridors is only related to the dimensionless virtual fire HRR; in the non-impingement area of a virtual fire, the dimensionless maximum smoke temperature in corridors is a function of the dimensionless virtual fire HRR and dimensionless longitude distance. The viscosity and conduction exhibit an insignificant impact on the maximum temperature in the corridor. Through replacing the parameters of virtual fire with the dimensionless smoke temperature in fire rooms, the correlations between dimensionless maximum temperature in corridors and the dimensionless smoke temperature in fire rooms were proposed.
Highlights
The hot smoke of building fires is a critical problem for fire protection engineering
The virtual fire heat release rate (HRR) and the distance from the virtual fire source to the corridor ceiling could be obtained by Equations (10) and (11), respectively
This work provides a theoretical analysis of the relationships between maximum smoke temperature beneath the corridor ceiling and the smoke temperature in the fire room
Summary
The hot smoke of building fires is a critical problem for fire protection engineering. Toxic smoke has led to about 85% of deaths in building fires [1]. The hot smoke can directly burn people, even resulting in death [2]. The detectors and sprinklers are activated by the maximum smoke temperature beneath the building ceiling. It is very important to study the maximum smoke temperature under the corridor ceiling to attain the safety level of the building. Simple correlations to obtain a first estimate of smoke temperatures are still highly desirable. McCaffrey et al [4] developed classic MQH correlation based on simple conservation of energy expression, through over 100 experiments, which could and rapidly estimate the average hot smoke temperature in compartment fires. Chen et al [6] investigated the correlations of peak hot gas temperature with first and second order gradients during fire growth, and the results of one full-scale test were in good agreement with the critical conditions indicated by the small-scale tests
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