Simulation of Ethylene Wall Fires Using the Spatially-Evolving One-Dimensional Turbulence Model

Autor:	Ryan S. Hintze, Zoltan Jozefik, Alan R. Kerstein, Elizabeth I. Monson, David O. Lignell, Chris Werner, Mark A. Finney
Rok vydání:	2014
Předmět:	Meteorology Turbulence Advection Flow (psychology) 020101 civil engineering 02 engineering and technology Mechanics medicine.disease_cause 01 natural sciences Temperature measurement Soot 010305 fluids & plasmas 0201 civil engineering law.invention Physics::Fluid Dynamics Ignition system law 0103 physical sciences Heat transfer Radiative transfer medicine Environmental science General Materials Science Physics::Chemical Physics Safety Risk Reliability and Quality
Zdroj:	Fire Technology. 52:167-196
ISSN:	1572-8099 0015-2684
DOI:	10.1007/s10694-014-0441-2
Popis:	The mechanism of flame propagation in fuel beds of wildland fires is important to understand in order to quantify fire spread rates. Fires spread by radiative and convective heating and in some cases require direct flame contact to achieve ignition. The flame in an advancing fire is unsteady and turbulent, making study of intermittent flames in complex fuels difficult. A 1.83 m tall, 0.61 m wide vertical wall fire, in which ethylene fuel is slowly fed through a porous ceramic, is modeled to investigate unsteady turbulent flames in a controlled environment. Three fuel flow rates of 235, 390, and 470 L/min are considered. Simulations of this configuration are performed using a spatial formulation of the one-dimensional turbulence (ODT) model which is able to resolve individual flames (a key property of this model) and has been shown to provide turbulent statistics that compare well with experimental data for a number of flow configurations including wall fires. In the ODT model diffusion–reaction equations are solved along a notional line of sight perpendicular to the wall that is advanced vertically. Turbulent advection is modeled through stochastic domain mapping processes. A new Darrieus–Landau combustion instability model is incorporated in the ODT eddy selection process. The ODT model is shown to capture the evolution of the flame and describe the intermittent properties at the flame/air interface. Simulations include radiation and soot effects and are compared to experimental temperature measurements. Simulated mean temperatures differ from the experiments by an average of 63 K over all measurement points for the three fuel flow rates. Predicted root mean square temperature fluctuations capture the trends in the experimental data, but overestimate the raw experimental values by a factor of two. This difference is discussed using thermocouple response and heat transfer correction models. Simulated velocity, soot, and radiation properties are also reported.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::3e1ab78881983a4c73202cefae3633aa https://doi.org/10.1007/s10694-014-0441-2 Zobrazit plný text záznamu Full text from SpringerLink