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Communication Dans Un Congrès Année : 2005

Chemfire : a zone model for predicting chemical effects of pool fire in a single forced ventilation enclosure

Résumé

Zone models have been developed since the early 60s for the prediction of fire parameters such as smoke temperature, smoke filling and movement in multi-compartment buildings. Unfortunately, one major difficulty in current zone models is that heat and chemical species release rates in relation with a given fire source term are usually to be provided as input data. A new zone model for prediction of thermal and chemical effects of pool fire in a forced ventilated enclosure has been developed. The novelty of the approach relies in particular on the provision of three sub-models that are used for reducing the number of input data needed for a given simulation. The burning rate history of liquid pool fire is calculated from a vaporisation sub-model. A solid flame sub-model is used for predicting radiative properties of flame. Yields of chemical species are estimated from a dedicated sub-model of combustion. This zone model has received some validation for use in forced ventilated enclosures only. Promising results have been obtained.
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Dates et versions

ineris-00972509 , version 1 (03-04-2014)

Identifiants

  • HAL Id : ineris-00972509 , version 1
  • INERIS : PU-2005-233

Citer

Sylvain Brohez, Christian Delvosalle, Guy Marlair. Chemfire : a zone model for predicting chemical effects of pool fire in a single forced ventilation enclosure. 4. Mediterranean combustion Symposium, Oct 2005, Lisbonne, Portugal. pp.NC. ⟨ineris-00972509⟩

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