On the subject of large-scale pool fires and turbulent boundary layer interactions

• Published in: Physics of fluids (1994) Vol. 36; no. 2
• Main Author: Domino, Stefan P.
• Format: Journal Article
• Language: English
• Published: Melville American Institute of Physics 01.02.2024; American Institute of Physics (AIP)
• Subjects: Boundary layer interaction; Combustion; Configurations; Coupling; Crosswinds; Fluid flow; Heat flux; Heat transfer; Inflow; Large eddy simulation; MATHEMATICS AND COMPUTING; Pool fires; Radiation transport; Turbulent boundary layer
• ISSN: 1070-6631; 1089-7666
• DOI: 10.1063/5.0196265

The role to which a realistic inflow turbulent boundary layer (TBL) influences transient and mean large-scale pool fire quantities of interest (QoIs) is numerically investigated. High-fidelity, low-Mach large-eddy simulations that activate low-dissipation, unstructured numerics are conducted using an unsteady flamelet combustion modeling approach with mutiphysics coupling to soot and participating media radiation transport. Three inlet profile configurations are exercised for a large-scale, high-aspect rectangular pool that is oriented perpendicular to the flow direction: a time-varying, TBL inflow profile obtained from a periodic precursor simulation, the time-mean of the transient TBL, and a steady power-law inflow profile that replicates the mean TBL crosswind velocity of 10.0 m/s at a vertical height of 10 m. Results include both qualitative transient flame evolution and quantitative flame shape with ground-level temperature and convective/radiative heat flux profiles. While transient fire events, which are driven by burst-sweep TBL coupling, such as blow-off and reattachment are vastly different in the TBL case (contributing to increased root mean square QoI fluctuation prediction and disparate flame lengths), mean surface QoI magnitudes are similar. Quadrant analysis demonstrates that the TBL configuration modifies burst-sweep phenomena at windward pool locations, while leeward recovery is found. Positive fluctuations of convective heat flux correlate with fast moving fluid away from the pool surface due to intermittent combustion events.