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Balbi, J. H., Rossi, J. L., Marcelli, T., & Chatelon, F. J. (2010) Physical Modeling of Surface Fire under Nonparallel Wind and Slope Conditions. Combustion Science and Technology, 182, 922-939.
http://dx.doi.org/10.1080/00102200903485178

has been cited by the following article:

  • TITLE: Generalized Blaze Flash, a “Flashover” Behavior for Forest Fires—Analysis from the Firefighter’s Point of View

    AUTHORS: François-Joseph Chatelon, Sophie Sauvagnargues, Gilles Dusserre, Jacques-Henri Balbi

    KEYWORDS: Fire Behavior, Flashover, Blow up, Induced Wind, VOC

    JOURNAL NAME: Open Journal of Forestry, Vol.4 No.5, October 29, 2014

    ABSTRACT: The phenomenon called “flashover” or “eruptive fire” in forest fires is characterized by a sudden change in fire behavior: everything seems to burst into flames instantly and firefighters are overwhelmed by a sort of eruption, spreading at a speed at far several meters per second. Unfortunately it has cost several lives in the past. The reasons for such an accident always create controversy in the research field. Different theories are highlighted and especially two major axes are currently subject to discussion because they are very popular among people involved in fire-fighting. The one with regard to VOCs emissions is the best-known among firemen. Under great heat, during summer or with a fire approaching, plants emit VOCs and the more the temperature grows, the more the amount of VOCs emitted grows. Under specific conditions (essentially topographical, meteorological and atmospheric), the cloud of gas can accumulate in an appropriate zone. The concentration of VOCs may therefore reach the Lower Explosive Limit, triggering the burst of the cloud when in contact with the fire. The second theory depends on physical considerations. An example is based on a convective flow created by the fire itself. When a fire spreads on a slope, it creates an aspiration phenomenon in a way to supply the fire with oxygen. The more this phenomenon is important, the more the flames tilt and increase the rate of speed, needing even more oxygen and thus induced flow. This vicious circle can stabilize or have an erratic behavior to trigger off a fire eruption. This article presents these two theories, and especially the new advances on this research subject.