论文信息 - Analyzing smoke alarm response to flaming fires using the fire model JET

Analyzing smoke alarm response to flaming fires using the fire model JET

An algorithm that calculates the time dependent smoke concentration in a fire-induced ceiling jet within a smoke layer and algorithms for predicting the response of photoelectric smoke alarms, both of which are part of the computer model JET, are examined using three different fires in a small room. The objectives of this analysis are to test the ceiling jet smoke algorithm and understand the limitations of analyzing signals from photoelectric smoke alarms located in the ceiling jet to estimate fire size and thereby support decision making by emergency responders. The analysis is restricted to flaming fires that produce turbulent plumes and can be represented by axisymmetric point sources. Two different smoke yields from the literature are used to obtain ceiling jet smoke density from JET. Depending on the value of the smoke yield used, the predictions of JET follow or do not follow the photoelectric smoke alarm signals. This suggests that additional information about how smoke yields are measured or that a better calibration technique is required in order to accurately model smoke alarm response.

[1] Thomas G. Cleary,et al. Particulate Entry Lag In Spot-type Smoke Detectors , 2000 .

[2] W. D. Davis,et al. NASA fire detector study , 1996 .

[3] William D. Davis,et al. Predicting Smoke and Carbon Monoxide Detector Response in the Ceiling Jet in the Presence of a Smoke Layer (NISTIR 6976) | NIST , 2003 .

[4] R. L. Alpert. Turbulent Ceiling-Jet Induced by Large-Scale Fires , 1975 .

[5] Erik L. Johnsson,et al. Design and testing of a new smoke concentration meter , 2000 .

[6] A. Tewarson. Generation of Heat and Chemical Compounds in Fires , 2002 .

[7] G. Mulholland,et al. Specific extinction coefficient of flame generated smoke , 2000 .

[8] R. L. Alpert. Calculation of response time of ceiling-mounted fire detectors , 1972 .

[9] David W. Stroup,et al. Methods to calculate the response time of heat and smoke detectors installed below large unobstructed ceilings , 1985 .

[10] T. Kashiwagi,et al. Estimate of the Effect of Scale on Radiative Heat Loss Fraction and Combustion Efficiency , 1994 .

[11] Louis A. Gritzo,et al. Soot scattering measurements in the visible and near-infrared spectrum , 2000 .

[12] Richard W. Bukowski,et al. Performance of Home Smoke Alarms, Analysis of the Response of Several Available Technologies in Residential Fire Settings. | NIST , 2007 .

[13] Takashi Kashiwagi,et al. Fire safety science : proceedings of the Fourth international symposium , 1994 .