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J. Ji, M. Li, Z. H. Gao, Y. F. Li, W. X. Shi and J. H. Sun (2016) Applied Thermal Engineering 101 390-401.
Date: 2017-03-13   Author: SKLFS  ,   Source: SKLFS  ,
 

J. Ji, M. Li, Z. H. Gao, Y. F. Li, W. X. Shi and J. H. Sun (2016) Experimental investigation of combustion characteristics under different ventilation conditions in a compartment connected to a stairwell. Journal/Applied Thermal Engineering 101 390-401. [In English]
Web link: http://dx.doi.org/10.1016/j.applthermaleng.2016.01.117
Keywords: ,High-rise building, Ventilation condition, Ghosting flames, Mass loss, rate, Temperature attenuation coefficient, BEHAVIOR, FIRES, SMOKE, MODEL, FLOW

Abstract: A set of experiments was conducted in a scaled building model with 12 floors to study the effect of different ventilation conditions on combustion characteristics in a compartment connected to a stairwell with single opening. The results show that when the opening was set at the 1st floor, the upper part of thermal plume inclined to doorway while the lower part inclined to the opposite direction, like a crescent. A special phenomenon, ghosting flame, took place in the experiments where the fire source was relatively large and the opening was set at the 3rd, 6th, and 9th floors, which was considered to be a result of insufficient oxygen supply. The mass loss rate in the current work decreased after the occurrence of ghosting flames. Two parameters theta, which is related to fuel mass loss rate, and eta, which is related to the air flow rate at the opening of the stairwell, can be roughly used to identify whether the fire is ventilation control. It is shown that theta increases with the opening height and pool size. The ghosting flames appear at a large degree of under-ventilated condition. There was a stable neutral plane at the opening at the 1st floor, whereas no stable neutral plane was identified at the openings at higher floors. Smoke moving upward depends on turbulent mixing in the stairwell in the current work. Temperature attenuation coefficient with the movement mechanism of turbulent mixing is much higher than that with the movement mechanism of stack effect. (C) 2016 Elsevier Ltd. All rights reserved.

 
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