References
- Hansen R., Ingason H. 2012 Heat release rates of multiple objects at varying distances. Fire Safety Journal, vol. 52, pp. 1–10.
- Hansen R., 2021 Modelling the throttle effect in a mine drift. Journal of Sustainable Mining, vol. 20, pp. 277-295.
- Hwang C.C., Chaiken R.F., 1978 Effect of Duct Fire on the Ventilation Air Velocity. Report of Investigations 8311. Bureau of Mines. United States Department of Interior.
- Lee C.K., Chaiken R.F., Singer J.M., 1979 Interaction Between Duct Fires and Ventilation Flow: An Experimental Study. Combustion and Technology, vol. 20, pp. 59-72.
- Litton C.D., DeRosa M., Li J-S., 1987 Calculating Fire-Throttling of Mine Ventilation Airflow. Report of Investigations 9076. Bureau of Mines. United States Department of Interior.
- Hansen R., 2020 Mass flow during fire experiments in a model-scale mine drift with longitudinal ventilation. Mining Technology, vol. 129, pp. 68-81. https://doi.org/10.1080/25726668.2020.1766302.
- Edwards J.C., Hwang C.C., 1999 CFD analysis of mine fire smoke spread and reverse flow conditions. NIOSH.
- Edwards J.C., Hwang C.C., 2006 CFD modelling of fire spread along combustibles in a mine entry. SME annual meeting and exhibit, St. Louis, MO.
- Yuan L., Zhou L., Smith A.C., 2016 Modeling carbon monoxide spread in underground mine fires. Applied Thermal Engineering, vol. 100, pp. 1319-26.
- Edwards J.C., Franks R.A., Friel G.F., Yuan L., 2006 Experimental and modelling investigation of the effect of ventilation on smoke rollback in a mine entry. NIOSH.
- Edwards J.C., Friel G.F., Yuan L., Franks R.A., 2006 Smoke reversal interaction with diagonal airway - its elusive character. NIOSH.
- Friel G.F., Yuan L., Edwards J.C., Franks R.A., 2006. Fire-generated smoke rollback through crosscut from return to intake - experimental and CFD study. NIOSH.
- Hansen R., 2020. Modelling temperature distributions and flow conditions of fires in an underground mine drift. Geosystem Engineering, vol. 23, pp. 299-314.
- Vaitkevicius A., Carvel R., Colella F. 2016. Investigating the Throttling Effect in Tunnel Fires. Fire Technology, vol. 52, pp. 1619-1628.
- Hansen R., Ingason H., 2010 Model scale fire experiments in a model tunnel with wooden pallets at varying distances. Research report SiST 2010:8. Mälardalen University. Västerås, Sweden.
- Ingason H., 2005. Model scale tunnel fire tests. SP report 2005:49. Swedish National Testing and Research Institute. Borås, Sweden.
- Newman J.S., 1984. Experimental evaluation of fire-induced stratification. Combustion and Flame, vol. 57, pp. 33–39.
- Yeoh G.H, Yuen K.K., 2009. Computational Fluid Dynamics in Fire Engineering, Theory, Modelling and Practice. Academic Press, Oxford.
- McGrattan K., Hostikka S., Floyd J., McDermott R., Vanella M., 2020. Fire Dynamics simulator, user's guide, sixth edition. NIST special publication 1019. Gaithersburg, USA.
- Hansen R., 2019 The influence of rough rock surface on the heat losses of fire gases in a mine drift. Proceedings of the 5th World Congress on Mechanical, Chemical, and Material Engineering (MCM'19), Lisbon, Portugal.
- Heskestad G., 1972. Modeling of Enclosure Fires. Proceedings of the Fourteenth Symposium (International) on Combustion, The Pennsylvania State University, PA. pp. 1021-1030.
- Heskestad G., 1975 Physical Modeling of Fire. Journal of Fire & Flammability, vol. 6, pp. 253-273.
- Quintiere J.G., 1989 Scaling Applications in Fire Research. Fire Safety Journal, vol. 15, pp. 3-29.
- Hansen R., Ingason H., 2013. Heat release rate measurements of burning mining vehicles in an underground mine. Fire Safety Journal, vol. 61, pp. 12–25.