The accelerating forest fire phenomenon for two real accidents is studied. This phenomenon is investigated using the thermochemical hypothesis, based on the ignition of a biogenic volatile organic compounds cloud accumulated in canyons. By heating a Rosmarinus officinalis plant in a specific hermetic enclosure, a mixture of 14 biogenic volatile organic compounds is identified and their mass fractions determined as temperature functions. The theoretical flammability limits of those components are calculated by means of empirical correlations. Froude-scaling law is applied to laboratory emission results to find the concentrations of biogenic volatile organic compounds at field scale. The comparison of the flammability limits with the calculated concentrations at real scale using this changing-scale analysis shows that the emitted biogenic volatile organic compounds can lead to an accelerating forest fire.
An approach to estimate species production during a compartment fire is proposed. Semi-empirical correlations based on oxygen concentration are given. They give an estimate of the concentrations of carbon monoxide, carbon dioxide, hydrogen, and hydrocarbons with a carbon chain length lower than five. Three intervals of oxygen concentration are noted, and they correspond to sufficiently ventilated, underventilated, and very underventilated fires. In order to validate these correlations, fire experiments are performed in a reduced-scale room. Species concentrations predicted by the model are in good agreement with our experimental data and with those of the literature. Coefficients used in the correlations are obtained for heptane and dodecane fires.
Ignition and combustion characteristics of a low‐vulnerability propellant mainly composed of nitrocellulose are studied experimentally. Ignition is obtained using a 10 W laser diode. Experiments are performed in a cylindrical closed‐volume reactor for different initial pressures and initial propellant masses under nitrogen and argon surrounding atmospheres. Ignition delays, maximal overpressures and propagation rates are obtained for different initial pressures and laser powers. Ignition probabilities for different laser powers and gaseous atmospheres are also investigated using the modified Langlie method. Argon is found to be a combustion enhancer for this kind of propellant, compared to nitrogen. Laser power plays a significant role on ignition probabilities and ignition delays, but not on propagation rates. As expected, ignition delay is highly dependent on initial pressure.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.