Abstract
This paper shows the presence of the influence of fire protection systems on the value of individual possible risk, and such influence can be determined through a constant value. Mathematical approaches and applicable mathematical models are presented, with the help of which an individual fire risk is assessed. Theoretical approaches to establishing the coefficients of the probability of effective operation of fire protection systems are substantiated. As a criterion for evaluating the effectiveness of fire protection systems, it is proposed to use the time of achievement of critical values for life by fire hazards. Using field models on the sample of real objects, examples of estimating the time of reaching critical values of life-threatening factors for fire hazards for cases when the object is not equipped and equipped with separate fire protection systems are given. The average values of the coefficients of the probability of operation efficiency of such fire protection systems as smoke protection systems and sprinkler fire extinguishing systems are determined. The dependence which allows considering the probability of efficiency of joint work of separate types of fire protection systems is established.
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References
DBN B.2.5–56: 2014. Fire protection systems. [In force from 2015–07–01]. Official publisher Kyiv: Ministry of Regional Development of Ukraine, p. 127 (2015)
Ivanyuta, S.M.: Anti-crisis management. Кyiv, Center for Educational Literature, p. 288 (2007)
Dunbar J.H.: Risk Management and Risk Assesment. Russia: British Fire Safety and Protection Seminar (1995)
Begun, V.V., Naumenko, I.M.: Life safety, Кyiv, Fenix, p. 328 (2004)
Brushlinsky, N.N., Shebeko, Yu.N.: Fire Risks. Dynamics, Management, Forecasting. Moscow, FGU VNIIPO, p. 370 (2007)
DSTU 8828: 2019 Fire safety. Terms. National Standard of Ukraine (official edition). Kyiv “UkrNDNC” (2020)
Nizhnyk, V.V., Mikhailova, A.V.: Regarding foreign experience in determining fire risk. Кyiv: Sci. Bull. UkrNDIPB 1(27), 100–105 (2013)
Klimas, R.V., Mikhailova, A.V., Matviychuk, D.Y.: The results of calculations of the probability of fires in buildings and structures for various purposes. Кyiv: Sci. Bull. UkrNDIPB (2010)
Nizhnyk, V.V., Klimas, R.V., Sizikov, O.O., Yakimenko, O.P., Netreba, A.V., Dovgosheeva, N.M.: Improving methodological approaches to fire risk assessment. Кyiv: Sci. Bull. Civil Prot. Fire Saf. 2(2), 83–88 (2016)
Chernov, M.N.: Methodology for calculating the reliability indicators of the fire warning system and managing the evacuation of people in case of fire “RND 73–16–90, Novosibirsk (1990)
Akhmedova, A.A., Shevtsova, T.G., Kotlyarov, R.V., Crol, A.N.: The failure rate of a single element. Tech. Technol. Prod. Process. 49(4) (2008)
Cauchemarov, Y.A.: Forecasting Fire Hazards in a Premises: Textbook, Academy of the State Fire Service of the Ministry of Internal Affairs of Russia, Moscow (2000)
McGrattan, K.: Fire Dynamics Simulator (Version 5) Technical Reference Guide, Volume 1: Mathematical model. NIST Special Publication 1018–5, p. 94 (2009)
McGrattan, K.: Fire Dynamics Simulator (Version 5) User’s Guide. NIST Special Publication 1019–5 (2019)
DSTU ISO 13571: 2018 (ISO 13571: 2012, IDT) Fire hazards. Guidelines for determining the period of time before disability during a fire (2008)
Ballo, Y., Yakovchuk, R., Nizhnyk, V., Sizikov, O., Kuzyk, A.: Investigation of design parameters facade fire-preventing eaves for prevent the spread of fires on facade structures of high-rise buildings. Fire Saf. 37, 16–23 (2020)
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Nizhnyk, V., Savchenko, O., Ballo, Y., Nekora, V. (2023). Theoretical Approaches to Justify the Coefficients of Influence of Fire Protection Systems on Individual Fire Risk. In: Blikharskyy, Z. (eds) Proceedings of EcoComfort 2022. EcoComfort 2022. Lecture Notes in Civil Engineering, vol 290. Springer, Cham. https://doi.org/10.1007/978-3-031-14141-6_30
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DOI: https://doi.org/10.1007/978-3-031-14141-6_30
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