Fire induced pressure in airthigh houses: Experiments and FDS validation

Brohez, Sylvain; Caravita, Irene

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Fire induced pressure in airthigh houses: Experiments and FDS validation

Brohez, Sylvain; Caravita, Irene

2020 • In Fire Safety Journal, 114, p. 1-15

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https://hdl.handle.net/20.500.12907/3787

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Disciplines :

Mechanical engineering

Author, co-author :

Brohez, Sylvain ; Université de Mons > Faculté Polytechnique > Service de Génie des Procédés chimiques et biochimiques

Caravita, Irene

Language :

English

Title :

Fire induced pressure in airthigh houses: Experiments and FDS validation

Publication date :

01 June 2020

Journal title :

Fire Safety Journal

ISSN :

0379-7112

Publisher :

Elsevier, United Kingdom

Volume :

114

Pages :

1-15

Peer reviewed :

Peer Reviewed verified by ORBi

Research unit :

F505 - Génie des Procédés chimiques et biochimiques

Research institute :

R500 - Institut des Sciences et du Management des Risques

Available on ORBi UMONS :

since 17 January 2021

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Bibliography

Directive of the European Parliament and of the Council of 19 May 2010 on the Energy Performance of Buildings. (Directive 2010/31/EU).
Hume, B., Firefighting in Under-ventilated Compartments: Literature Review., 2004, Fire Statistics and Research Division, Office of the Deputy Prime Minister, London, UK Fire Research Technical Report 5/2005.
Bukowski, R., Modelling a backdraft: the fire at 62 watts street. NFPA J. 89 (1995), 85–89.
Francetvinfo. Retrieved from www.francetvinfo.fr/faits-divers/mort-de-cinq-pompiers-a-neuilly-le-proces-s-ouvre-aujourd-hui_1669349.html accessed November 2017.
Fourneau, C., Cornil, N., Delvosalle, C., Breulet, H., Desmet, S., Brohez, S., Comparison of fire hazards in passive and conventional houses. Chem Eng Trans 26 (2012), 375–380.
Chow, W.K., Zou, G.W., Numerical simulation of pressure changes in closed chamber fires. Build. Environ. 44 (2009), 1261–1275.
Pretrel, H., Le saux, W., Audouin, L., Pressure variations induced by a pool fire in a well-confined and force-ventilated compartment. Fire Saf. J. 52 (2012), 11–24.
Wahlqvist, J., van Hees, P., Validation of FDS for large-scale well-confined mechanically ventilated fires scenarios with emphasis on predicting ventilation system behavior. Fire Saf. J. 62 (2013), 102–114.
Bonte, F., Noterman, N., Merci, B., Computer simulations to study interaction between burning rates and pressure variations in confined enclosure fires. Fire Saf. J. 62 (2013), 125–143.
Floyd, J., Coupling a neywork HVAC model to a computational fluid dynamics odel using large eddy simulation. Fire Saf. Sci. 10 (2011), 459–470.
Van den Brink, V., Fire Safety and Suppression in Modern Residential Buildings. Master thesis, 2015, University of Eindhoven.
Kallada Janardhan, R., Hostikka, S., Experiments and numerical simulations of pressure effects in apartment fires. Fire Technol. 53 (2017), 1353–1377.
Hostikka, S., Kallada Janardhan, R., Riaz, U., Sikanen, T., Fire-induced pressure and smoke spreading in mechanilly ventilated buildings with air-tight envelopes. Fire Saf. J. 91 (2017), 380–388.
Brohez, S., Duhamel, P., Inwards doors blocked by fire induced overpressure in airtight apartment: a real case in Germany. Chem Eng Trans 67 (2018), 25–30.
Vanhaverbeke, D., Fire Development in Passive Houses: Qualitative Description and Design of Full-Scale Fire Tests. Master thesis, 2015, University of Edinburgh.
Brohez, S., Caravita, I., Fire-induced pressure in passive houses: experiments and FDS validation. Proceedings of the Ninth International Seminar on Fire and Explosion Hazards, 2019, ISFEH9), St. Petersburg, 524–533.
Peacock, R.D., Jones, W.W., Reneke, P.A., Forney, G.P., CFAST – Consolidated Model of Fire and Smoke Transport (Version 6), User's Guide, vol. 1041, 2008, NIST special publication.
NBN D 50-001 "Dispositifs de ventilation dans les bâtiments d'habitation, 1ère Ed, 1991.
Sinai, Y.L., Comments on the role of leakages in field modelling of under-ventilated compartment fires. Fire Saf. J. 33 (1999), 11–20.
ASTM E779-19, Standard Test Method for Determining Air Leakage Rate by Fan Pressurization. 2019, ASTM International, West Conshohocken, PA.
McGrattan, K., Hostikka, S., Floyd, J., McDermott, R., Vanella, M., sixth ed. Fire Dynamics Simulator, User's Guide, vol. 1019, 2017, NIST special publication.
Tewarson, A., Genereation of heat and chemical compounds in fires, chapter 3-4. DiNenno, P.J., et al. (eds.) SFPE Handbook of Fire Protection Engineering, third ed., 2002, National Fire Protection Association.
Janssens, M., Measuring rate of heat release by oxygen consumption. Fire Technol. 27 (1991), 234–249.
Brohez, S., Marlair, G., Delvosalle, C., Fire calorimetry relying on the use of the fire propagation apparatus. Part I: early learning from use in europe. Fire Mater. 30 issue 2 (2006), 131–149.
McGrattan, K., McDermott, K.R., Floyd, J., Hostikka, S., Forney, G., Baum, H., Computational fluid dynamics modelling of fire. Int. J. Comput. Fluid Dynam. 26 (2012), 349–361.
McGrattan, K., Hostikka, S., Floyd, J., McDermott, R., Vanella, M., sixth ed. Fire Dynamics Simulator, Technical Reference Guide, vols. 1018–1, 2017, NIST special publication.
J Titus, J., Hydraulics, Chapter 4-2. DiNenno, P.J., et al. (eds.) SFPE Handbook of Fire Protection Engineering, third ed., 2002, National Fire Protection Association.
Urner, G., Pressure loss of orifice plates according to ISO 5167-1. Flow Meas. Instrum. 8:1 (1997), 39–41.
Reader-Harris, M.J., Sattary, J.A., Spearman, E.P., The orifice plate discharge coefficient equation - further work. Flow Meas. Instrum. 6:Issue 2 (1995), 101–114.
Mulholland, G., Janssens M, M., Yusa, S., Twilley, W., Babrauskas, V., The effect of oxygen concentration on CO and smoke produced by flames. Proceedings of the 3rd International Symposium of Fire Safety Science, Edinburgh,U.K, 8–12 July 1991, 585–594.
Peatross, M.J., Beyler, C.L., Ventilation effects on compartment fire characterization, fire safety science. Proceedings of the Fifth International Symposium, Melbourne, Australia, 3–7 March 1997, 403–414.
Brohez, S., Marlair, G., Delvosalle, C., The effect of oxygen concentration on CO and soot yields in fires. Fire Mater. 32 (2008), 141–158.
Peacock, R.D., Forney, G.P., Reneke, P.A., CFAST – Consolidated Model of Fire and Smoke Transport (Version 6), Technical Reference Guide, vol. 1026, 2011, NIST special publication.
Brohez, S., Caravita, I., Overpressure induced by fires in airtight buildings. J. Phys. Conf., 1107, 2018 042031.
Terzis, A., von Wolfersdorf, J., Wagner, G., Weigand, B., Ott, P., Influence of thermocouple thermal inertia in impingement heat transfer experiments using transient techniques. XXI Biannual Symposium on Measuring Techniques in Turbomachinery, 22-23 March, 2012 (Valencia, Spain).
Drysdale D, D., An Introduction to Fire Dynamics. third ed., 2011, John Wiley & Sons, City of New York.