Skip to main content
U.S. flag

An official website of the United States government

Official websites use .gov
A .gov website belongs to an official government organization in the United States.

Secure .gov websites use HTTPS
A lock ( ) or https:// means you’ve safely connected to the .gov website. Share sensitive information only on official, secure websites.

Simulating Enclosure Fire Dynamics and Suppression

Published

Author(s)

Howard R. Baum, Kevin B. McGrattan

Abstract

At least three different physics based approaches to fire dynamicssimulations have evolved over the years; lumped parameter or ''zone models'',computational fluid dynamics models based on classical turbulence modelingtechniques, and large eddy simulations. Large eddy simulations provide themost realistic description of fire phenomena developed to date.All such simulations provide descriptions of the processes that controlthe mixing and combustion of fuel and air at elevated temperatures. In anenclosure fire these processes are complicated by the fact that the fuel wasinitially part of the building or its furnishings, and the air supply iscontrolled by the interaction of the fire with its surroundings. The geometryof the building and itsfurnishings all influence the fire and are in turn changed by it.Numerical models of fire suppression are dependent on the level of detailgiven to the combustion and fuel pyrolysis processes. Present models of gasphase suppression limited by the use of highly simpified models of combsutionmechanisms in large-scale simulations. Models of solid phase suppression arelimited by the lack of well-accepted, robust pyrolysis models that haveenough physical detail to accomodate the inclusion of water impingement.Several lumped parameter models of solid phase suppression by water havebeen developed over the past decade, but these models do not neccesarilywork well within a computational fluid dynamics framework. The key toimproving models of both fire dynamics and suppression phenomena is theinterface between the gas and solid phases. More physics is needed to properlydescribe solid phase suppression dynamics, and existing fundamentalcombustion models of gas phase suppression need to be simplified so that bothparts of the suppression problem can be brought into the same conceptualframework.
Citation
NRIFD Symposium-Science, Technology and Standards for Fire Suppression Systems

Keywords

computer simulation, fire modeling, fire research, sprinklers, suppression

Citation

Baum, H. and McGrattan, K. (2017), Simulating Enclosure Fire Dynamics and Suppression, NRIFD Symposium-Science, Technology and Standards for Fire Suppression Systems (Accessed March 28, 2024)
Created February 19, 2017