AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Building Simulation Article
Article Link
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Cover Article

Large eddy simulation of room fire spread using a medium scale compartment made of medium density fibreboard (MDF) panels

Jiayidaer Baolati1Kaiyuan Li1( )Yanyan Zou1( )Kevin Frank2George Hare2Jiaqing Zhang3Fanliang Ge4
School of Safety Science and Emergency Management, Wuhan University of Technology, Luoshi Road 122, Wuhan 430070, China
BRANZ, Private Bag 50 908, Porirua 5240, New Zealand
Electric Power Research Institute, State Grid Anhui Electric Power Co. LTD, Hefei 230601, China
State Key Laboratory of Fire Science, University of Science and Technology of China, Hefei 230027, China
Show Author Information

Abstract

At present, there is a shortage of experimental and simulation studies on fire spread in medium- and large-scale compartments while the existing models of the fire spread are limited for typical engineering applications. This paper proposes a new model for large-scale fire spread on medium density fibreboard (MDF) panels. Validating the model with single burning item (SBI) experiments, it is found that the numerical simulation closely predicts the experimental heat release rate (HRR) with some error near the peak. The predicted heat flux and distance of lateral flame spread are consistent with the experiments and an existing model. The effects of kinetic properties and heat of combustion are identified through a sensitivity analysis. The decrease of activation energy and increase of pre-exponential factor make the MDF easier to pyrolyze and the increase of heat of combustion enhances the flame temperature and thus provide more heat feedback to the sample surface. The low activation energy (71.9 kJ/mol) and high heat of combustion (46.5 MJ/kg) of the model ensure the occurrence of flame spread. Furthermore, the model was validated using medium-scale compartment fire experiments and the results showed that the model can accurately predict the HRR after flashover (the error is within 7%). While the burner is ignited, the predictions of in-compartment gas temperature and heat flux are more accurate. However, when the burner is extinguished, the modelled in-compartment gas temperature is lower than the experimental values, resulting in a lower heat flux prediction. The model leads to easier flame spread; therefore, the modelled flame spreads faster in the compartment compared to the experiment, and thus the HRR increases more rapidly.

Keywords

numerical simulationactivation energycompartment fireflame spreadSBIMDF

Electronic Supplementary Material

Download File(s)
bs-15-4-495-ESM.doc (7.5 MB)
bs-15-4-495-ESM.pdf (3.9 MB)

References

 

Bhattacharjee S, Tran W, Laue M, et al. (2015). Experimental validation of a correlation capturing the boundary layer effect on spread rate in the kinetic regime of opposed-flow flame spread. Proceedings of the Combustion Institute, 35: 2631–2638.
Crossref Google Scholar
 

Chaos M, Khan MM, Krishnamoorthy N, et al. (2011). Evaluation of optimization schemes and determination of solid fuel properties for CFD fire models using bench-scale pyrolysis tests. Proceedings of the Combustion Institute, 33: 2599–2606.
Crossref Google Scholar
 

Crewe RJ, Hidalgo JP, Sørensen MX, et al. (2018). Fire performance of sandwich panels in a modified ISO 13784-1 small room test: the influence of increased fire load for different insulation materials. Fire Technology, 54: 819–852.
Crossref Google Scholar
 

de Ris JN (1969). Spread of a laminar diffusion flame. Symposium (International) on Combustion, 12: 241–252.
Crossref Google Scholar
 
Drysdale D (2011). Diffusion flames and fire plumes. In: Drysdale D (ed), An Introduction to Fire Dynamics, 3rd edn. Chichester, UK: John Wiley & Sons. https://doi.org/10.1002/9781119975465
Crossref
 

Fang J, Meng Y, Wang J, et al. (2018). Experimental, numerical and theoretical analyses of the ignition of thermally thick PMMA by periodic irradiation. Combustion and Flame, 197: 41–48.
Crossref Google Scholar
 

Fukumoto K, Wang C, Wen J (2018). Large eddy simulation of upward flame spread on PMMA walls with a fully coupled fluid–solid approach. Combustion and Flame, 190: 365–387.
Crossref Google Scholar
 

Gao Z, Ji J, Wan H, et al. (2015). An investigation of the detailed flame shape and flame length under the ceiling of a channel. Proceedings of the Combustion Institute, 35: 2657–2664.
Crossref Google Scholar
 

Gollner MJ, Huang X, Cobian J, et al. (2013). Experimental study of upward flame spread of an inclined fuel surface. Proceedings of the Combustion Institute, 34: 2531–2538.
Crossref Google Scholar
 

Gollner MJ, Miller CH, Tang W, et al. (2017). The effect of flow and geometry on concurrent flame spread. Fire Safety Journal, 91: 68–78.
Crossref Google Scholar
 

Gong J, Zhou X, Li J, et al. (2015). Effect of finite dimension on downward flame spread over PMMA slabs: Experimental and theoretical study. International Journal of Heat and Mass Transfer, 91: 225–234.
Crossref Google Scholar
 

Gupta V, Hidalgo JP, Cowlard A, et al. (2021). Ventilation effects on the thermal characteristics of fire spread modes in open-plan compartment fires. Fire Safety Journal, 120: 103072.
Crossref Google Scholar
 

Hostikka S, Matala A (2017). Pyrolysis model for predicting the heat release rate of birch wood. Combustion Science and Technology, 189: 1373–1393.
Crossref Google Scholar
 

Hsu SY, T'ien JS (2011). Effect of chemical kinetics on concurrent- flow flame spread over solids: a comparison between buoyant flow and forced flow cases. Combustion Science and Technology, 183: 390–407.
Crossref Google Scholar
 

Huang H, Ooka R, Liu N, et al. (2009). Experimental study of fire growth in a reduced-scale compartment under different approaching external wind conditions. Fire Safety Journal, 44: 311–321.
Crossref Google Scholar
 

Huang X, Gollner MJ (2014). Correlations for evaluation of flame spread over an inclined fuel surface. Fire Safety Science, 11: 222–233.
Crossref Google Scholar
 

Jahn W, Rein G, Torero JL (2011). Forecasting fire growth using an inverse zone modelling approach. Fire Safety Journal, 46: 81–88.
Crossref Google Scholar
 

Jiang L, Miller CH, Gollner MJ, et al. (2017). Sample width and thickness effects on horizontal flame spread over a thin PMMA surface. Proceedings of the Combustion Institute, 36: 2987–2994.
Crossref Google Scholar
 

Jiang L, He J-J, Sun J-J (2018). Sample width and thickness effects on upward flame spread over PMMA surface. Journal of Hazardous Materials, 342: 114–120.
Crossref Google Scholar
 

Kudo Y, Ito A (2002). Propagation and extinction mechanisms of opposed-flow flame spread over PMMA. Proceedings of the Combustion Institute, 29: 237–243.
Crossref Google Scholar
 

Leventon IT, Stoliarov SI (2013). Evolution of flame to surface heat flux during upward flame spread on poly(methyl methacrylate). Proceedings of the Combustion Institute, 34: 2523–2530.
Crossref Google Scholar
 

Leventon IT, Li J, Stoliarov SI (2015). A flame spread simulation based on a comprehensive solid pyrolysis model coupled with a detailed empirical flame structure representation. Combustion and Flame, 162: 3884–3895.
Crossref Google Scholar
 

Li KY, Fleischmann CM, Spearpoint MJ (2013). Determining thermal physical properties of pyrolyzing New Zealand medium density fibreboard (MDF). Chemical Engineering Science, 95: 211–220.
Crossref Google Scholar
 

Li KY, Huang X, Fleischmann C, et al. (2014a). Pyrolysis of medium- density fiberboard: Optimized search for kinetics scheme and parameters via a genetic algorithm driven by Kissinger's method. Energy & Fuels, 28: 6130–6139.
Crossref Google Scholar
 

Li KY, Pau DSW, Hou YN, et al. (2014b). Modeling pyrolysis of charring materials: Determining kinetic properties and heat of pyrolysis of medium density fiberboard. Industrial & Engineering Chemistry Research, 53: 141–149.
Crossref Google Scholar
 

Li K, Pau DSW, Wang J, et al. (2015). Modelling pyrolysis of charring materials: Determining flame heat flux using bench-scale experiments of medium density fibreboard (MDF). Chemical Engineering Science, 123: 39–48.
Crossref Google Scholar
 

Li K, Pau DS, Zhang H (2016a). Pyrolysis of polyurethane foam: Optimized search for kinetic properties via simultaneous K-K method, genetic algorithm and elemental analysis. Fire and Materials, 40: 800–817.
Crossref Google Scholar
 

Li K, Wang J, Ji J (2016b). An experimental investigation on char pattern and depth at postflashover compartments using medium- density fibreboard (MDF). Fire and Materials, 40: 368–384.
Crossref Google Scholar
 

Li K, Hostikka S, Dai P, et al. (2017). Charring shrinkage and cracking of fir during pyrolysis in an inert atmosphere and at different ambient pressures. Proceedings of the Combustion Institute, 36: 3185–3194.
Crossref Google Scholar
 

Li K, Hostikka S (2019). Embedded flame heat flux method for simulation of quasi-steady state vertical flame spread. Fire Safety Journal, 104: 117–129.
Crossref Google Scholar
 

Li K, Zou Y, Bourbigot S, et al. (2021). Pressure effects on morphology of isotropic char layer, shrinkage, cracking and reduced heat transfer of wooden material. Proceedings of the Combustion Institute, 38: 5063–5071.
Crossref Google Scholar
 
McGrattan K, Hostikka S, McDermott R, et al. (2020a). Fire dynamics Simulator User's Guide. NIST Special Publication, 1019(6). Gaithersburg, MD, USA: National Institute of Standards and Technology.
 
McGrattan K, Hostikka S, McDermott R, et al. (2020b). Fire Dynamics Simulator Technical Reference Guide, volume 1: Mathematical Model. NIST Special Publication, 1017(6). Gaithersburg, MD, USA: National Institute of Standards and Technology.
 

Nishino T, Kagiya K (2019). A multi-layer zone model including flame spread over linings for simulation of room-corner fire behavior in timber-lined rooms. Fire Safety Journal, 110: 102906.
Crossref Google Scholar
 

Peng W, Hu L, Yang R, et al. (2011). Full scale test on fire spread and control of wooden buildings. Procedia Engineering, 11: 355–359.
Crossref Google Scholar
 

Rakesh Ranga HR, Korobeinichev OP, Harish A, et al. (2018). Investigation of the structure and spread rate of flames over PMMA slabs. Applied Thermal Engineering, 130: 477–491.
Crossref Google Scholar
 

Saito K, Quintiere J, Williams F (1986). Upward turbulent flame spread. Fire Safety Science, 1: 75–86.
Crossref Google Scholar
 

Singh AV, Gollner MJ (2015a). A methodology for estimation of local heat fluxes in steady laminar boundary layer diffusion flames. Combustion and Flame, 162: 2214–2230.
Crossref Google Scholar
 

Singh AV, Gollner MJ (2015b). Estimation of local mass burning rates for steady laminar boundary layer diffusion flames. Proceedings of the Combustion Institute, 35: 2527–2534.
Crossref Google Scholar
 

Xie W, DesJardin P (2009). An embedded upward flame spread model using 2D direct numerical simulations. Combustion and Flame, 156: 522–530.
Crossref Google Scholar
 

Yu M, Zhu G, Meng Q (2018). Experimental study and analysis of XPS vertical countercurrent fire spread. Procedia Engineering, 211: 945–953.
Crossref Google Scholar
 

Yuan S, Zhang J (2009). Large eddy simulation of compartment fire with solid combustibles. Fire Safety Journal, 44: 349–362.
Crossref Google Scholar
 

Zeinali D, Verstockt S, Beji T, et al. (2018a). Experimental study of corner fires—Part Ⅰ: Inert panel tests. Combustion and Flame, 189: 472–490.
Crossref Google Scholar
 

Zeinali D, Verstockt S, Beji T, et al. (2018b). Experimental study of corner fires—Part Ⅱ: Flame spread over MDF panels. Combustion and Flame, 189: 491–505.
Crossref Google Scholar
 

Zeinali D, Gupta A, Maragkos G, et al. (2019). Study of the importance of non-uniform mass density in numerical simulations of fire spread over MDF panels in a corner configuration. Combustion and Flame, 200: 303–315.
Crossref Google Scholar
 

Zhang J, Delichatsios M, Colobert M (2010). Assessment of fire dynamics simulator for heat flux and flame heights predictions from fires in SBI tests. Fire Technology, 46: 291–306.
Crossref Google Scholar
 

Zhang Y, Huang X, Wang Q, et al. (2011). Experimental study on the characteristics of horizontal flame spread over XPS surface on plateau. Journal of Hazardous Materials, 189: 34–39.
Crossref Google Scholar
 

Zhang Y, Ji J, Li J, et al. (2012a). Effects of altitude and sample width on the characteristics of horizontal flame spread over wood sheets. Fire Safety Journal, 51: 120–125.
Crossref Google Scholar
 

Zhang Y, Ji J, Wang Q, et al. (2012b). Prediction of the critical condition for flame acceleration over wood surface with different sample orientations. Combustion and Flame, 159: 2999–3002.
Crossref Google Scholar
 

Zhang Y, Sun JH, Huang XJ, et al. (2013). Heat transfer mechanisms in horizontal flame spread over wood and extruded polystyrene surfaces. International Journal of Heat and Mass Transfer, 61: 28–34.
Crossref Google Scholar
 
Zhao Z, Gorham D, Gollner MJ (2013). Flame spread through arrays of wooden dowels. In: Proceedings of the 8th U. S. National Combustion Meeting.
 

Zhao K, Gollner MJ, Liu Q, et al. (2020). Lateral flame spread over PMMA under forced air flow. Fire Technology, 56: 801–820.
Crossref Google Scholar
Building Simulation
Volume 15 Issue 4,
April 2022
Pages 495-510
DOI: 10.1007/s12273-021-0822-7
Cite this article:
Baolati J, Li K, Zou Y, et al. Large eddy simulation of room fire spread using a medium scale compartment made of medium density fibreboard (MDF) panels. Building Simulation, 2022, 15(4): 495-510. https://doi.org/10.1007/s12273-021-0822-7

643

Views

8

Crossref

7

Web of Science

8

Scopus

0

CSCD

Altmetrics
Received: 17 March 2021
Revised: 05 July 2021
Accepted: 14 July 2021
Published: 25 August 2021
© Tsinghua University Press and Springer-Verlag GmbH Germany, part of Springer Nature 2021
Return