References
- Bland, J. M., & Altman, D. G. (1999). Measuring agreement in method comparison studies. Statistical Methods in Medical Research, 8(2), 135–160.
- Chen, H. X., Liu, N. A., & Chow, W. K. (2011). Wind tunnel tests on compartment fires with crossflow ventilation. Journal of Wind Engineering and Industrial Aerodynamics, 99(10), 1025–1035.
- Hunt, G. R., & Linden, P. F. (2001). Steady-state flows in an enclosure ventilated by buoyancy forces assisted by wind. Journal of Fluid Mechanics, 426, 355–386.
- Hunt, G. R., & Linden, P. F. (2005). Displacement and mixing ventilation driven by opposing wind and buoyancy. Journal of Fluid Mechanics, 527, 27–55.
- IPMVP. (2012). International Performance Measurement and Verification Protocol: Concepts and Options for Determining Energy and Water Savings, Volume 1, Technical Report, Efficiency Valuation Organization: Washington, DC, USA.
- International Organization for Standardization (ISO). (2004). Nuclear facilities. Criteria for the design and operation of ventilation systems for nuclear installation other than nuclear reactors. (ISO 17873: 2004).
- Le Dez, T. (2016). Approche par similitude du couplage des effets thermiques et du vent sur les transferts de masse dans les réseaux aérauliques des bâtiments complexes (Doctoral Dissertation). Retrieved from https://hal.archives-ouvertes.fr/tel-01661300.
- Le Roux, N. (2011). Etude par similitude de l’influence du vent sur les transferts de masse dans les bâtiments complexes (Doctoral Dissertation). Retrieved from https://hal.archives-ouvertes.fr/tel-00717838.
- Le Roux, N., Faure, X., Inard, C., Soares, S., & Ricciardi, L. (2012). Reduced-scale study of wind influence on mean airflows inside buildings equipped with ventilation systems. Building and Environment, 58, 231–244.
- Le Roux, N., Faure, X., Inard, C., Soares, S., & Ricciardi, L. (2013). Reduced-scale study of transient flows inside mechanically ventilated buildings subjected to wind and internal overpressure effects. Building and Environment, 62, 18–32.
- Li, Y., Delsante, A., Chen, Z. D., Sandberg, M., Andersen, A., Bjerre, M., & Heiselberg, P. (2001). Some examples of solution multiplicity in natural ventilation. Building and Environment, 36(7), 851–858.
- Lucchesi, C., Vauquelin, O., Pretrel, H., & Bournot, P. (2011). Doorway flow from a reduced scale isothermal air/helium approach. International Journal of Thermal Sciences, 50(10), 1920–1929.
- Prétrel, H., Le Saux, X., & Audouin, L. (2012). Pressure variations induced by a pool fire in a well-confined and force-ventilated compartment. Fire Safety Journal, 52, 11–24.
- Ricciardi, L., Gélain, T., & Soares, S. (2015). Experimental and numerical characterization of wind-induced pressure coefficients on nuclear buildings and chimney exhausts. Nuclear Engineering and Design, 292, 248–260.
- Vauquelin, O., & Megret, O. (2002). Smoke extraction experiments in case of fire in a tunnel. Fire Safety Journal, 37(5), 525–533.
- Vauquelin, O. (2008). Experimental simulations of fire-induced smoke control in tunnels using an “air-helium reduced scale model”: Principle, limitations, results and future. Tunnelling and Underground Space Technology, 23(2), 171–178.
- Vaux, S., & Prétrel, H. (2013). Relative effects of inertia and buoyancy on smoke propagation in confined and forced ventilated enclosure fire scenarios. Fire Safety Journal, 62, Part B, 206–220.