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On the role of radiation and dimensionality in predicting flow opposed flame spread over thin fuels
- Source :
- IndraStra Global.
- Publication Year :
- 2012
-
Abstract
- In this work a flame-spread model is formulated in three dimensions to simulate opposed flow flame spread over thin solid fuels. The flame-spread model is coupled to a three-dimensional gas radiation model. The experiments [1] on downward spread and zero gravity quiescent spread over finite width thin fuel are simulated by flame-spread models in both two and three dimensions to assess the role of radiation and effect of dimensionality on the prediction of the flame-spread phenomena. It is observed that while radiation plays only a minor role in normal gravity downward spread, in zero gravity quiescent spread surface radiation loss holds the key to correct prediction of low oxygen flame spread rate and quenching limit. The present three-dimensional simulations show that even in zero gravity gas radiation affects flame spread rate only moderately (as much as 20% at 100% oxygen) as the heat feedback effect exceeds the radiation loss effect only moderately. However, the two-dimensional model with the gas radiation model badly over-predicts the zero gravity flame spread rate due to under estimation of gas radiation loss to the ambient surrounding. The two-dimensional model was also found to be inadequate for predicting the zero gravity flame attributes, like the flame length and the flame width, correctly. The need for a three-dimensional model was found to be indispensable for consistently describing the zero gravity flame-spread experiments [1] (including flame spread rate and flame size) especially at high oxygen levels (>30%). On the other hand it was observed that for the normal gravity downward flame spread for oxygen levels up to 60%, the two-dimensional model was sufficient to predict flame spread rate and flame size reasonably well. Gas radiation is seen to increase the three-dimensional effect especially at elevated oxygen levels (>30% for zero gravity and >60% for normal gravity flames). � 2012 Copyright Taylor and Francis Group, LLC.
- Subjects :
- Zero gravity
Work (thermodynamics)
General Chemical Engineering
Analytical chemistry
General Physics and Astronomy
Three dimensional effect
Heat radiation
Two dimensional model
Physics::Fluid Dynamics
Three dimensions
Two dimensional
Three dimensional simulations
Physics::Chemical Physics
Flame research
Flame spread rate
Quenching
Radiation
Chemistry
Mechanics
Heat feedback
Radiation loss
Fuel Technology
Finite width
Modeling and Simulation
Flame spread
Flame attributes
Three-dimensional model
Gases
Sailing vessels
Gravity (chemistry)
Flow (psychology)
Energy Engineering and Power Technology
Normal gravities
Fuels
dimensionality
Opposed flow
Oxygen levels
Flame length
Three dimensional
General Chemistry
Solid fuel
Opposed flow flames
Oxygen
Low oxygen
Solid fuels
Surface radiation
Gas radiation
Experiments
Forecasting
Subjects
Details
- Language :
- English
- ISSN :
- 23813652
- Database :
- OpenAIRE
- Journal :
- IndraStra Global
- Accession number :
- edsair.doi.dedup.....5ebfc07c77fbff239a06aac2972bdb8a