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Building fires heavy pollute the air and jeopardize human health and life. In this paper, the Large Eddy Simulation method of Fire Dynamics Simulator code has been used to investigate the temperature regime and the pollutant concentrations in a compartment and near a building wall under fire scenario. Numerical results show that the generation of fire products in the compartment is largely dependent on the temperature and the quantity of oxygen available for combustion. The outdoor plume parameters are affected by the temperature difference between the fire flame and plume and the surrounding ambient air.

Andersson, B. (2003), Combustion Products from Fires; Influence from ventilation conditions, Report 1029, Lund.

Liu, X., Zhai, Z. (2008), Location identification for indoor instantaneous point contaminant source by probability-based inverse computational fluid dynamics modeling, Indoor air Vol.18(1), pp. 2–11.

McGrattan, K.B., Baum, H.R., Rehm, R.G., (1998), Large eddy simulations of smoke movement, Fire Safety Journal, Vol.30(1998), pp.161–178.

McGrattan, K., Hostikka, S., Floyd, J., Baum, H., Mell, R.R.W., McDermott, R., (2009), Fire Dynamics Simulator (Version 5.4) Technical reference guide. National Institute of Standards and Technology. Washington.

Pešić, D.J., Kartov, R., Zigar, D.N., Chochev, V. (2014), The impact of wind inertial and fire buoyancy forces on air pollution in street canyon, Facta Universitatis, Series: Working and Living Environmental Protection, Vol. 11(2), pp. 65 - 74.

Schudel, D. (1996) Glass Fracture Analysis for Fire Investigators. Fire and Arson Investigator 46, pp. 28-35.