Abstract
Firebrand piles are known to ignite combustible infrastructure resulting in significant damage; however, the parameters that impact the heat transfer from firebrand piles to a combustible surface are not well understood. Heat transfer from a firebrand pile is directly related to the local firebrand temperatures which can vary significantly due to changes in the burning behavior. A two-phase flow analytical model was developed that includes time varying firebrand diameter, reradiation effects between firebrands, gas temperature and species evolution, and pile porosity effects. The analytical model was used to quantify the temperature of cylindrical firebrands and explore the effects of changing firebrand diameter, firebrand aspect ratio (pile porosity), gas velocity, and local oxygen mass fraction. All of these parameters were found to impact firebrand temperatures. Firebrand pile porosity has a significant impact on the velocity within the pile, with a decrease in pile porosity resulting in lower velocities and lower firebrand temperatures. The modeling results were used to explain the trends in heat transfer measured for firebrand piles on a horizontal plate.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Manzello SL, Suzuki S, Gollner MJ, Fernandez-Pello AC (2020) Role of firebrand combustion in large outdoor fire spread. Prog Energy Combust Sci 76:100801
Caton SE, Hakes RSP, Gorham DJ, Zhou A, Gollner MJ (2017) Review of pathways for building fire spread in the wildland urban interface part I: exposure conditions. Fire Technol 53(2):429–473
Dowling VP (1994) Ignition of timber bridges in bushfires. Fire Saf J 22(2):145–168
Manzello SL, Cleary TG, Shields JR, Maranghides A, Mell W, Yang JC (2008) Experimental investigation of firebrands: generation and ignition of fuel beds. Fire Saf J 43(3):226–233
Manzello SL, Park SH, Cleary TG (2009) Investigation on the ability of glowing firebrands deposited within crevices to ignite common building materials. Fire Saf J 44(6):894–900
Hakes RSP, Salehizadeh H, Weston-dawkes MJ, Gollner MJ (2019) Thermal characterization of firebrand piles. Fire Saf J 104:34–42
Manzello SL, Suzuki S (2014) Exposing decking assemblies to continuous wind-driven firebrand showers. Fire Saf Sci 11:1339–1352
Wessies SS, Chang MK, Marr KC, Ezekoye OA (2019) Experimental and analytical characterization of firebrand ignition of home insulation materials. Fire Technol 55(3):1027–1056
Manzello SL (2014) Enabling the investigation of structure vulnerabilities to wind-driven firebrand showers in wildland-urban interface (WUI) fires. Fire Saf Sci 11:83–96
Manzello SL et al (2008) On the development and characterization of a firebrand generator. Fire Saf J 43:258–268
Manzello SL, Suzuki S (2012) The new and improved NIST Dragon ’ s LAIR (Lofting and Ignition Research) facility. Fire Mater 1:623–635
Suzuki S, Manzello SL (2019) Investigating effect of wind speeds on structural firebrand generation in laboratory scale experiments. Int J Heat Mass Transf 130:135–140
Manzello SL, Suzuki S, Hayashi Y (2012) Exposing siding treatments, walls fitted with eaves, and glazing assemblies to firebrand showers. Fire Saf J 50:25–34
Suzuki S, Johnsson E, Maranghides A, Manzello SL (2016) Ignition of wood fencing assemblies exposed to continuous wind-driven firebrand showers. Fire Technol 52(4):1051–1067
Tao Z, Bathras B, Kwon B, Biallas B, Gollner MJ, Yang R (2020) Effect of firebrand size and geometry on heating from a smoldering pile under wind. Fire Saf J 1:103031
Bearinger E, Lattimer B, Hodges J, Rippe C, Kapahi A (2021) Statistical assessment of parameters affecting firebrand pile heat transfer to surfaces. Front Mech Eng 7:62
Koo E, Pagni PJ, Weise DR, Woycheese JP (2010) Firebrands and spotting ignition in large-scale fires. Int J Wildl Fire 19(7):818–843
Turns S (2000) An introduction to combustion: concepts and applications, 2nd edn. McGraw Hill, London
Baum HR, Atreya A (2014) A model for combustion of firebrands of various shapes. Fire Saf Sci 11:1353–1367
Chaos M, Khan MM, Dorofeev SB (2013) Pyrolysis of corrugated cardboard in inert and oxidative environments. Proc Combust Inst 34(2):2583–2590
Anca-Couce A, Zobel N, Berger A, Behrendt F (2012) Smouldering of pine wood: kinetics and reaction heats. Combust Flame 159(4):1708–1719
Hurt RH, Mitchell RE (1992) On the combustion kinetics of heterogeneous char particle populations. In: Twenty-fourth symposium on combustion, pp 1233–1241
Weng WG, Hasemi Y, Fan WC (2006) Predicting the pyrolysis of wood considering char oxidation under different ambient oxygen concentrations. Combust Flame 145(4):723–729
Lattimer BY, Bearinger E, Wong S, Hodges JL (2022) Evaluation of models and important parameters for firebrand burning. Combust Flame 235:111619
Monson CR, Germane GJ, Blackham AU, DouglasSmoot L (1995) Char oxidation at elevated pressures. Combust Flame 100(4):669–683
Zhou L (2018) Fundamentals of combustion theory. Elsevier, Amsterdam, pp 15–70
Rogers FE, Ohlemiller TJ (1980) Cellulosic insulation material I. Overall degradation kinetics and reaction heats. Combust Sci Technol 24(3–4):129–137
Kashiwagi T, Nambu H (1992) Global kinetic constants for thermal oxidative degradation of a cellulosic paper. Combust Flame 88(3–4):345–368
Incopera F, DeWitt D (1990) Fundamentals of heat and mass transfer, 3rd edn. Wiley, London
Barr BW, Ezekoye OA (2013) Thermo-mechanical modeling of firebrand breakage on a fractal tree. Proc Combust Inst 34(2):2649–2656
Zou RP, Yu AB (1996) Evaluation of the packing characteristics of mono-sized non-spherical particles. Powder Technol 88:71–79
Zhang C, Gao J, Zeng L, Xia Y, Xie W, Ye W (2020) Experimental analysis of the resistance of packed beds based on the morphology of cylinder. Powder Technol 369:238–247
Cholewa N, Summers PT, Feih S, Mouritz AP, Lattimer BY, Case SW (2016) A technique for coupled thermomechanical response measurement using infrared thermography and digital image correlation (TDIC). Exp Mech 56:145–164
Rippe CM, Lattimer BY (2015) Full-field surface heat flux measurement using non-intrusive infrared thermography. Fire Saf J 78:238–250
Bearinger ED, Hodges JL, Yang F, Rippe CM, Lattimer BY (2021) Localized heat transfer from firebrands to surfaces. Fire Saf J 120:1–10
Bearinger E, Lattimer B, Hodges J, Rippe C (2020) Measuring heat transfer from firebrands to surfaces. In: Proceeding of ASME 2020 heat transfer summer conference HT2020-9165, July 13–15, pp 1–9
Howell JR, Menguc MP (2011) A catalog of radiation heat transfer configuration factors. J Quant Spectros Radiat Transf 112(5):910–912
Urban JL, Fernandez-pello AC, Vicariotto M, Dunn-Rankin D (2019) Temperature measurement of glowing embers with color pyrometry. Fire Technol 55(3):1013–1026
Manzello SL, Maranghides A (2007) Measurement of firebrand production and heat release rate (HRR) from burning Korean pine trees. Fire Saf Sci 7:108–116
Acknowledgements
This research was funded by the National Institute of Standards and Technology (NIST) under contract NIST Grant No. 70NANB19H052. Brian Lattimer has an ownership/equity interest in Jensen Hughes.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Springer Nature or its licensor holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Lattimer, B.Y., Wong, S. & Hodges, J. A Theoretical Model to Understand Some Aspects of Firebrand Pile Burning. Fire Technol 58, 3353–3384 (2022). https://doi.org/10.1007/s10694-022-01303-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10694-022-01303-5