Journal of Engineering and Applied Sciences

Year: 2019
Volume: 14
Issue: 16
Page No. 5925 - 5941

Review of the Environmental Characteristics of Fire Extinguishing Substances of Different Composition used for Fires Extinguishing of Various Classes

Authors : Valentyna Loboichenko, Victor Strelets, Maya Gurbanova, Andriy Morozov, Pavlo Kovalov, Roman Shevchenko, Tetiana Kovalova and Roman Ponomarenko


Abbasov V.M., T.A. Ismayilov and S.E. Abdullayev, 2008. [Improving the quality of the foaming agent obtained on the basis of the amino complexes of petroleum acids (In Russian)]. Processes Petrochemistry Oil Refining, 4: 203-207.

Abbasov, V.M., S.E. Abdullayev and T.A. Ismayilov, 2010. [Foaming agent with anticorrosion property (In Russian)]. Azerbaijan Oil Ind., 4: 54-57.

Abduragimov, I.M., A.V. Vinogradov, V.V. Vinogradov, G.N. Kuprin and D.S. Kuprin, 2016. Foam silicagel, method for applying and producing same. WO2016153385A1, The World Intellectual Property Organization, Geneva, Switzerland.

Abduragimov, I.M., V.Y. Govorov and V.E. Makarov, 1980. [Physical and chemical bases of development and extinguishing fires, tutorial]. Higher Engineering Fire-Technical School of the Ministry of Internal Affairs of the USSR, Moscow, Russia. (In Russian)

Abramov, Y.A. and A.A. Kireev, 2015. Gelling Fire Extinguishing and Fire Retardant Means of Increased Efficiency in Relation to Fires Class A. National University Civil Protection of Ukraine, Kharkiv, Ukraine, Pages: 254.

Abramov, Y.A., О.E. Basmanov, J. Salamov and A.A. Mikhayl, 2018. Model of thermal effect of fire within a dike on the oil tank. Sci. Bull. National Min. Univ., 2: 95-100.
CrossRef  |  

Adams, R. and D. Simmons, 1999. Ecological effects of fire fighting foams and retardants. Proceedings of the Conference on Australian Bushfire, July 7-9, 1999, Albury Entertainment Centre, Albury, Australia, pp: 1-8.

Adams, R. and D. Simmons, 1999. Ecological effects of fire fighting foams and retardants: A summary. Aust. For., 62: 307-314.
CrossRef  |  Direct Link  |  

Al-Awad, T.K., M.N. Saidan and B.J. Gareau, 2018. Halon management and ozone-depleting substances control in Jordan. Intl. Environ. Agreements Politics Law Econ., 18: 391-408.
CrossRef  |  Direct Link  |  

Andronov, V., B. Pospelov and E. Rybka, 2017. Development of a method to improve the performance speed of maximal fire detectors. East Eur. Adv. Technol. J., 2: 32-37.
CrossRef  |  Direct Link  |  

Andronov, V., B. Pospelov, E. Rybka and S. Skliarov, 2017. Examining the learning fire detectors under real conditions of application. East Eur. J. Enterp. Technol., 3: 53-59.
CrossRef  |  Direct Link  |  

Anonymous, 1984. [GOST 4.106-83: System of product quality indices, gas extinguisher mixtures: Nomenclature of indices]. Russian Ministry of Internal Affairs, Moscow, Russia. (In Russian)

Anonymous, 1987. Conventions and agreements the Montreal protocol on substances that deplete the ozone layer. United Nations, New York, USA.

Anonymous, 1996. [The procedure for the use of foam for extinguishing fires]. The All-Russian Research Institute for Fire Protection (FGU VNIIPO) Ministry of the Interior, Russia. (In Russian)

Anonymous, 1999. [Guidelines for extinguishing oil and petroleum products in tanks and tank farms]. GUGPS-VNIIPO-MIPB, Moscow, Russia. (In Russian)

Anonymous, 2000. Directive 2000/60/EC of the European parliament and of the council establishing a framework for community action in the field of water policy. The European Environment Agency, Kobenhavn, Denmark.

Anonymous, 2002. [Foaming agents for fire extinguishing: General technical requirements and test methods]. Nippon Professional Baseball Moscow, Russia. (In Russian)

Anonymous, 2003. [About joining the stockholm convention on persistent organic pollutants]. The Law of the Republic of Azerbaijan, Baku, Azerbaijan. (In Azerbaijani)

Anonymous, 2005. Assessment of the toxic hazard of fire extinguishing gases and aerosols used for volumetric extinguishing. VNIIPO/MVD of Russia, Moscow, Russia. (In Russian)

Anonymous, 2006. 2010/15 PFOA stewardship program-guidance on reporting emissions and product content. The Environmental Protection Agency, Washington, DC., USA.

Anonymous, 2006. GB 15308-2006: Foam extinguishing agent, ICS 13.220.10. C84. Chinese National Standards, China.

Anonymous, 2007. ISO 3941:2007: Classification of fires. ISO, International Organization for Standardization, Geneva, Switzerland.

Anonymous, 2008. [On application of payments for natural resources, pollution of natural discharges and use of funds generated by these payments]. Cabinet of Azerbaijan Government office, Baku, Azerbaijan. (In Azerbaijani)

Anonymous, 2008. [Technical regulations on fire safety requirements]. Federal Law of the Russian Federation, Russia. (In Russian).

Anonymous, 2009. The stockholm convention on persistent organic pollutants. United Nations Environment Programme, Nairobi, Kenya.

Anonymous, 2009. [BS EN 615:2009: Fire protection, fire extinguishing media, Specifications for powders (other than class D powders)]. British Standards Institution, UK.,

Anonymous, 2009. [GOST R 53280.3-2009: Automatic fire extinguishing systems: Fire extinguishing media, part 3. Gaseous extinguishing media test methods]. Standard Inform, Moscow, Russia. (In Russian)

Anonymous, 2010. [GOST R 53280.2-2010: Automatic fire extinguishing systems; fire extinguishing media, part 2, foam concentrates for subsurface extinguishing of fires of oil and petroleum productsin tanks, general technical requirements and test methods]. Standard Inform, Moscow, Russia. (In Russian)

Anonymous, 2011. ISO 7203-2:2011 Fire extinguishing media-foam concentrates-Part 2: Specification for medium-and high-expansion foam concentrates for top application to water-immiscible liquids. International Organization for Standardization, Geneva, Switzerland.

Anonymous, 2011. The environmental protection industry is welcoming the golden period of development & NBSP; will become a new economic growth point. Science & Technology Development CO., Beijing, China.

Anonymous, 2012. [GOST P 50588-2012, 2012: Foaming agents for fire extinguishing, general technical requirements and test methods]. Standard Inform, Moscow, Russia, (In Russian)

Anonymous, 2013. Globally harmonized system of classification and labelling of chemicals (GHS). United Nations, New York, USA.

Anonymous, 2013. [GOST 32509-2013: Surface-active agents, method for determination of biodegradability rate in aquatic environment]. Standard Inform, Moscow, Russia. (In Russia)

Anonymous, 2015. Safety data sheet-Arctic™3x3% ATC™ foam concentrate. The Solberg Company, Wisconsin, USA.

Anonymous, 2015. Safety data sheet. Angus Fire Limited Company, USA.

Anonymous, 2016. Fact sheet on halons in fire-extinguishing systems: Phase-out and disposal. Government of Canada, Canada.

Anonymous, 2016. New York State rule regulating PFOS and PFOA: implications for Tyco fire protection. Chemguard Inc, USA.

Anonymous, 2016. Safety data sheet: Commercial ABC dry chemical (fire extinguishing agent, pressurized and non-pressurized). Badger Fire Protection Inc, Charlottesville, USA.

Anonymous, 2016. [DSTU 3789:2015: Fire safety, general designation foam concentrates for fire extinguishing, general specifications and test methods]. Dp Ukrndnts, Kyiv, Ukraine. (In Ukrainian)

Anonymous, 2016. [GOST 33777-2016: Surface-active agents: Method for determination of phytotoxicity for higher plants seeds]. GOST, Russia, (In Russian)

Anonymous, 2017. GB 4066-2017: Powder extinguishing agent ICS 13.220.10C83. National Standards of People’s Republic of China. Chinese National Standards, Chaina.

Anonymous, 2017. POPRC-13/2: Pentadecafluorooctanoic acid (CAS No: 335-67-1, PFOA, perfluorooctanoic acid), its salts and PFOA-related compounds; the persistent organic pollutants review committee. Decision Inc. Company, UK.

Anonymous, 2017. Technical bulletin: Chemical compatibility between historical and new C6 foam concentrates. Tyco Fire Products LP Company, Lansdale Town in Pennsylvania, USA.

Anonymous, 2018. Gaseous fire suppression systems in Аustralia stage 1. prepared by: Fire protection association of Australia. FPA Аustralia-Financial Planning Association, Australia.

Anonymous, 2018. ISO 7202:2018: Fire protection-fire extinguishing media-powder. International Organization for Standardization, Geneva, Switzerland.

Anonymous, 2018. [DSTU EN 1568-2:2018 (EN 1568-2:2018, IDT): Fire extinguishing media-foam concentrates-part2; Specification for high expansion foam concentrates for surface application to water-immiscible liquids]. DSTU-Ukrainian Scientific-Research and Training Center, Kyiv, Ukraine. (In Ukrainian)

Anonymous, 2018. [DSTU EN 1568-3:2018 (EN 1568-3:2018, IDT), Fire extinguishing media-Foam concentrates-part 3: Specification for low expansion foam concentrates for surface application to water-immiscible liquids]. Clarivate Analytics Analytics Company, Philadelphia, Pennsylvania, United States. (In Ukrainian)

Anonymous, 2018. [DSTU EN 1568-4:2018 (EN 1568-4:2018, IDT), Fire extinguishing media-foam concentrates-Part 4: Specification for low expansion foam concentrates for surface application to water-imiscible liquids]. National Standards Authority of Ireland, European. (In Ukrainian)

Anonymous, 2019. Biodegradability and international standards. Oil Technics Ltd, Inverbervie, Montrose, UK.

Anonymous, 2019. EN 1568 parts 1-4-European standard. Oil Technics Ltd, Inverbervie, Montrose, UK.

Anonymous, 2019. Halons program. United States Environmental Protection Agency, Washington, DC., USA.

Baduel, C., J.F. Mueller, A. Rotander, J. Corfield and M.J. Gomez-Ramos, 2017. Discovery of novel per-and polyfluoroalkyl substances (PFASs) at a fire fighting training ground and preliminary investigation of their fate and mobility. Chemosphere, 185: 1030-1038.
CrossRef  |  PubMed  |  Direct Link  |  

Balanyuk, V.M., N.M. Kozyar and O.I. Garassimyuk, 2016. [Application of gas-aerosol powder extinguishing mixtures for protection against combustible mixtures (In Ukrainian)]. Sci. J. Sci. Rise, 2: 10-14.

Banks, R.E., E.K. Clarke, E.P. Johnson and P.N. Sharratt, 1998. Environmental aspects of fluorinated materials: Part 31: Comparative life-cycle assessment of the impacts associated with fire extinguishants HFC-227ea and IG-541. Process Saf. Environ. Prot., 76: 229-238.
Direct Link  |  

Baratov, A.N. and E.N. Ivanov, 1979. [Fire Extinguishing at the Enterprises of the Chemical and Petrochemical Industry]. Chemistry Publisher, Moscow, Russia, (In Russian).

Baratov, A.N. and L.P. Wogman, 1982. [Fire Extinguishing Powder Formulations]. Stroiizdat Publisher, Moscow, Russia, (In Russian).

Baratov, A.N., 2012. [Fire extinguishing powder for extinguishing fires]. Patent of the Russian Federation, Russia. (In Russian)

Belkova, T., V. Perminov and N. Alekseev, 2016. [Review of eсological and economic impacts of peat fires (In Russian)]. XXI Century Technosphere Saf., 1: 35-44.

Bezrodnyy, I.F., 2013. [Fire ecology-these are just words (In Russian)]. Fire Explosion Saf., 22: 85-89.

Bocharov, V.V. and M.V. Raevskaya, 2013. [The increased use of perfluorinated surfactants-second coming of organohalogen compounds with the worst scenario of development for inhabitants of Earth (In Russian)]. Fire Explosion Saf., 22: 75-82.

Bocharov, V.V. and М.V. Raevskaya, 2016. [Research of ecological and hygienic characteristics of aqueous film forming foam agents and detection of the products with the minimum environmental risks (In Russian)]. Sci. Rep. BelSU. Ser. Nat. Sci., 25: 88-93.

Bondarets, Y.V., O.L. Matveev and D.A. Bezverkha, 2014. Problem of water pollution petroleum products and ways to it solve. Prob. Environ. Biotechnol., Vol. 2,

Borisov, P.F., V.E. Rosokha, Y.A. Abramov, A.A. Kireev and A.V. Babenko, 2005. [Method of extinguishing a fire and composition for its implementation]. Patent of the Russian Federation, Russia. (In Russian)

Butler, J.H., J.W. Elkins, B.D. Hall, S.O. Cummings and S.A. Montzka, 1992. A decrease in the growth rates of atmospheric halon concentrations. Nat., 359: 403-405.
CrossRef  |  Direct Link  |  

Chen, H., C. Zhang, J. Han, Y. Yu and P. Zhang, 2012. PFOS and PFOA in influents, effluents and biosolids of Chinese wastewater treatment plants and effluent-receiving marine environments. Environ. Pollut., 170: 26-31.
CrossRef  |  PubMed  |  Direct Link  |  

Chen, J., C. Li, Z. Ristovski, A. Milic and Y. Gu et al., 2017. A review of biomass burning: Emissions and impacts on air quality, health and climate in China. Sci. Total Environ., 579: 1000-1034.
CrossRef  |  PubMed  |  Direct Link  |  

Chen, S., X.C. Jiao, N. Gai, X.J. Li and X.C. Wang et al., 2016. Perfluorinated compounds in soil, surface water and groundwater from rural areas in eastern China. Environ. Pollut., 211: 124-131.
CrossRef  |  PubMed  |  Direct Link  |  

Chirkina, M., D. Saveliev and O. Pitak, 2017. [Possibility of using eco-friendly foams for fire suppression (In Russian)]. Prob. Fire Saf., 42: 176-180.

Cortina, T. and S. Korzeniowski, 2008. AFFF industry in position to exceed environmental goals. Asia Pacific Fire Mag., 26: 18-22.

Dadashov, I., 2018. [Experimental research the influence of thickness of the layer of a granulated film glow on the burning of organic liquids (In Russian)]. Prob. Fire Saf., 43: 38-44.

Dadashov, I., V. Loboichenko and A. Kireev, 2018. [Comparative assassment of environmental damage when using gel forming systems of different composition in combustible liquids extinguishing (In Russian)]. Trans. Kremenchuk Mykhailo Ostrohradskyi National Univ., 1: 123-129.

Dadashov, Y.F., L.A. Mykheenko and A.A. Kyreev, 2016. [Selection of an easy silicate carrier for gel extinguishing layer in fire-fighting (In Russian)]. Intl. J. Res. Prod. Ceram. Sci. Life, 2: 44-51.
CrossRef  |  Direct Link  |  

Dubinin, D., K. Korytchenko, A. Lisnyak, I. Hrytsyna and V. Trigub, 2018. Improving the installation for fire extinguishing with finely­dispersed water. East. Eur. J. Enterp. Technol., 2: 38-43.
CrossRef  |  Direct Link  |  

Dubinin, D.P., K.V. Koritchenko, A.A. Lisnyak, I.M. Grytsina and V.V. Trigub, 2017. Numerical simulation of the creation of a fire fighting barrier using an explosion of a combustible charge. East. Eur. J. Enterp. Technol., 6: 11-16.
Direct Link  |  

Dushdurova, N.I. and S.A.M. Khanova, 2017. [Synthetic oil, acids, salts foam-forming on the acquisition (In Russian)]. Ekoenergy, 3: 5-9.

EEA., 2015. SOER 2015-the European environment-state and outlook 2015. The European Environmental Agen, Kobenhavn, Denmark.

GB 17835, 2008. GB 17835-2008: Water fire extinguishing agent; ICS 13.220.10 C84. National standards of people’s republic of China, people’s republic of China. The Standardization Administration of the People’s Republic of China, China.

Goto, K., H. Takaichi and T. Kawano, 2015. Learning from the eco-toxicology of fire-fighting foams in aquatic organisms: Altered eco-toxicity of sodium alkyl sulfonates on green paramecia and Medaka fish maintained in different waters. J. Disaster Res., 10: 604-612.

Guo, C., Y. Zhang, X. Zhao, P. Du and S. Liu et al., 2015. Distribution, source characterization and inventory of perfluoroalkyl substances in Taihu Lake, China. Chemosphere, 127: 201-207.
CrossRef  |  PubMed  |  Direct Link  |  

Hajiyev, S.G., A.V. Ivanov, G.K. Ivakhnyuk and E.N. Kdochnikova, 2014. [Research extinguishing and thermal insulation properties of hydrogels prepared from modified nanofluids (In Russian)]. MCHS., 2: 31-37.

Holemann, H., 1994. Environmental problems caused by fires and fire-fighting agents. Fire Saf. Sci., 4: 61-77.
CrossRef  |  Direct Link  |  

Huang, Y., Z. Wencheng, X. Dai and Y. Zhao, 2012. Study on water-based fire extinguishing agent formulations and properties. Procedia Eng., 45: 649-654.
CrossRef  |  Direct Link  |  

Hurley, M.J., D.T. Gottuk, J.R. Hall Jr, K. Harada and E.D. Kuligowski et al., 2015. SFPE Handbook of Fire Protection Engineering. 5th Edn., Springer, Berlin, Germany, ISBN:978-1-4939-2564-3, Pages: 3493.

INFOSAN., 2007. Newsletter No 02/2007-POPs biomonitoring. International Network of Food Safety Authorities (INFOSAN), Russia.

ISO., 2011. ISO 7203-1: Fire extinguishing media-foam concentrates-part 1: Specification for low-expansion foam concentrates for top application to water-immiscible liquids. International Organization for Standardization, Geneva, Switzerland.

Isaeva, L.K., 2001. [Fires and the Environment]. Kalan Publisher, Moscow, Russia, (In Russian).

Ivanov A.V., D.P. Toropov, G.K. Ivakhnyuk, A.V. Fedorov and A.A. Kuzmin, 2017. [Research of the extinguishing properties of water and hydrogel with Carbon nanoparticles for liquidation burning of the petroleum products (In Russian)]. Fire Explosion Saf., 26: 31-44.

Johnson, E.P., E.K. Clarke, R.E. Banks and P.N. Sharratt, 1997. Fire extinguishers: A case study of CFC replacements. Intl. J. Life Cycle Assess., 2: 135-140.
CrossRef  |  Direct Link  |  

Kawahara, T., S. Hatae, T. Kanyama, Y. Ishizaki and K. Uezu, 2016. Development of eco-friendly soap-based firefighting foam for forest fire. Environ. Control Biol., 54: 75-78.
CrossRef  |  Direct Link  |  

Kazakov, M.V., I.I. Petrov and V.C. Reutt, 1977. [Means and Methods of Extinguishing Flames of Flammable Liquids]. Stroyizdat Publishing, Moscow, Russia, (In Russian).

Kim, S.K., Y.L. Kho, M. Shoeib, K.S. Kim and K.R. Kim et al., 2011. Occurrence of perfluorooctanoate and perfluorooctanesulfonate in the Korean water system: Implication to water intake exposure. Environ. Pollut., 159: 1167-1173.
CrossRef  |  PubMed  |  Direct Link  |  

Klein, R.A., 2008. Firefighting foam and the environment. Fire Aust., 1: 54-57.

Klymenko, M.O. and I.I. Zalessky, 2017. [Technoecology: A Textbook]. NUVGP, Ukraine, ІSВN:978-966-289-150-8, Pages: 348.

Kondratenko, O.M., S.O. Vambol, O.P. Strokov and A.M. Avramenko, 2015. Mathematical model of the efficiency of diesel particulate matter filter. Geotech. Min. Mech. Eng. Build., 6: 55-61.
Direct Link  |  

Korolchenko, A.Y. and D.A. Korolchenko, 2004. [Fire and Explosion Danger and Extinguishing Means: Handbook]. 2nd Edn., Pozhnauka Publisher, Moscow, Russia, (In Russian).

Korolchenko, A.Y. and E.N. Shilina, 2016. [Gas extinguishing (In Russian)]. Fire Explosion Saf., 25: 57-65.

Korolchenko, D.A. and A.A. Volkov, 2017. [Extinguishing of flammable liquids by film foaming agents (In Russian)]. Fire Explosion Saf., 26: 45-55.

Korolchenko, D.A., A.F. Sharovarnikov, E.N. Degaev, N.A. Vlasov and A.I. Melnikov, 2015. [Suppression of a flame of combustible liquids by reaction inhibitor (In Russian)]. Fire Explosion Saf., 24: 70-76.

Kostenko, V., T. Kostenko, O. Zemlianskiy, A. Maiboroda and S. Kutsenko, 2017. Automatization of individual anti-thermal protection of rescuers in the initial period of fire suppression. East. Eur. J. Enterp. Technol., 5: 4-11.

Kovalov, A., Y. Otrosh, O. Ostroverkh, O. Hrushovinchuk and O. Savchenko, 2018. Fire resistance evaluation of reinforced concrete floors with fire-retardant coating by calculation and experimental method. E3S. Web. Conf., 60: 1-9.
CrossRef  |  

Lim, T.C., B. Wang, J. Huang, S. Deng and G. Yu, 2011. Emission inventory for PFOS in China: Review of past methodologies and suggestions. Scient. World J., 11: 1963-1980.
CrossRef  |  Direct Link  |  

Lin, A.Y.C., S.C. Panchangam and P.S. Ciou, 2010. High levels of perfluorochemicals in Taiwan’s wastewater treatment plants and downstream rivers pose great risk to local aquatic ecosystems. Chemosphere, 80: 1167-1174.
CrossRef  |  PubMed  |  Direct Link  |  

Liu, Z., Y. Lu, P. Wang, T. Wang and S. Liu et al., 2017. Pollution pathways and release estimation of perfluorooctane sulfonate (PFOS) and perfluorooctanoic acid (PFOA) in central and eastern China. Sci. Total Environ., 580: 1247-1256.
CrossRef  |  PubMed  |  Direct Link  |  

Liu, Z., Y. Lu, T. Wang, P. Wang and Q. Li et al., 2016. Risk assessment and source identification of perfluoroalkyl acids in surface and ground water: Spatial distribution around a mega-fluorochemical industrial park, China. Environ. Intl., 91: 69-77.
CrossRef  |  PubMed  |  Direct Link  |  

Loboichenko, V. and V. Strelec, 2018. The natural waters and aqueous solutions express-identification as element of determination of possible emergency situation. Water Energy Intl., 61: 43-50.
Direct Link  |  

Loboichenko, V., Dadashov, I. and A. Kireev, 2018. Analysis of the ecological characteristics of environment friendly fire fighting chemicals used in extinguishing oil products. Pollut. Res., 37: 63-77.
Direct Link  |  

Loboichenko, V., Tishakova, T. and A. Vasyukov, 2016. Application of direct coulometry for rapid assessment of water quality in Krasno-Oskol Reservoir (Kharkiv Region, Ukraine). Der Pharma Chem., 8: 27-34.
Direct Link  |  

Loboichenko, V., V. Andronov and V. Strelec, 2018. Evaluation of the metrological characteristics of natural and treated waters with stable salt composition identification method. Ind. J. Environ. Protection, 38: 724-732.

Malhjlongi, A., D. Safiu, H. Amqam, A. Syam and M. Hatta et al., 2019. Modelling of SO2 and CO pollution due to industry PLTD emission Tello in 2 Makassar Indonesia. J. Eng. Appl. Sci., 14: 634-640.
CrossRef  |  Direct Link  |  

Martin, D., M. Tomida and B. Meacham, 2016. Environmental impact of fire. Fire Sc. Rev., 5: 1-21.
CrossRef  |  Direct Link  |  

Migalenko, K., V. Nuyanzin, A. Zemlianskyi, A. Dominik and S. Pozdieiev, 2018. Development of the technique for restricting the propagation of fire in natural peat ecosystems. East. Eur. J. Enterp. Technol., 1: 31-37.
Direct Link  |  

Mizuki, H., K. Uezu, T. Kawano, T. Kadono and M. Kobayashi et al., 2007. Novel environmental friendly soap-based fire-fighting agent. J. Environ. Eng. Manage., 17: 403-408.
Direct Link  |  

Modovsky, C., 2007. Ecological risk assessment: Wildland fire-fighting chemicals, Labat environmental. United States Forest Service, Washington, USA.

Mokeyev, Y., V. Kanibolotskyy, E. Gunieva and R. Tcitculaev, 2006. Ingredient composition for producing a fire-extinguishing powder and method for the production thereof. World Intellectual Property Organization, Geneva, Switzerland.

NFPA., 2016. NFPA 11: Standard for low-medium-and high-expansion foam. National Fire Protection Association, Massachusetts, USA.

NFPA., 2018. NFPA 10: Standard for portable fire extinguishers. National Fire Protection Association, Massachusetts, USA.

NFPA., 2019. List of NFPA codes and standards. National Fire Protection Association, Massachusetts, USA.

Nakayama, S., K. Harada, K. Inoue, K. Sasaki and B. Seery et al., 2005. Distributions of perfluorooctanoic acid (PFOA) and perfluorooctane sulfonate (PFOS) in Japan and their toxicities. Environ. Sci. Intl. J. Environ. Physiol. Toxicol., 12: 293-313.
PubMed  |  Direct Link  |  

Pan, G., Q. Zhou, X. Luan and Q.S. Fu, 2014. Distribution of perfluorinated compounds in Lake Taihu (China): Impact to human health and water standards. Sci. Total Environ., 487: 778-784.
CrossRef  |  PubMed  |  Direct Link  |  

Plaza-Alvarez, P.A., M.E. Lucas-Borja, J. Sagra, D.A. Zema and J. Gonzalez-Romero et al., 2019. Changes in soil hydraulic conductivity after prescribed fires in mediterranean pine forests. J. Environ. Manage., 232: 1021-1027.
CrossRef  |  Direct Link  |  

Pospelov, B., E. Rybka, R. Meleshchenko, S. Gornostal and S. Shcherbak, 2017. Results of experimental research into correlations between hazardous factors of ignition of materials in premises. East. Eur. J. Enterp. Technol., 6: 50-56.
Direct Link  |  

Pospelov, B., V. Andronov, E. Rybka and S. Skliarov, 2017. Research into dynamics of setting the threshold and a probability of ignition detection by self-adjusting fire detectors. East. Eur. J. Enterp. Technol., 5: 43-48.
CrossRef  |  Direct Link  |  

Pospelov, B., V. Andronov, E. Rybka, V. Popov and A. Romin, 2018. Experimental study of the fluctuations of gas medium parameters as early signs of fire. East. Eur. J. Enterp. Technol., 1: 50-55.
CrossRef  |  Direct Link  |  

Prokhorenko, E.M., V.F. Klepikov, V.V. Litvinenko, P.A. Khaymovich and N.A. Shulgin et al., 2015. Diagnostics of processes of wear of materials of ball-tube mills. East. Eur. J. Enterp. Technol., 1: 14-20.
Direct Link  |  

REACH., 2006. Corrigendum to regulation (EC) No 1907/2006 of the European parliament and of the council of 18 December 2006 concerning. Registration, Evaluation, Authorisation and Restriction of Chemicals, Europe.

Rajput, S. and P.P. Saikia, 2018. Fire extinguishing agents: Sort and comparison. Intl. J. Res. Appl. Sci. Eng. Technol., 6: 557-567.
CrossRef  |  Direct Link  |  

Reihlen, A., 2010. Background information on: The EU hazard concept and EU approaches towards chemicals management. Ministry of Education and Science, Moskva, Russia.

Reihlen, A., J. Ruut, P. Engewald, H. Fammler and E. Moukhametshina, 2010. The Russian system of chemicals management: Current understanding. MBA Thesis, Baltic Environmental Forum Group, Hamburg, Germany.

Semko, A., O. Rusanova, O. Kazak, M. Beskrovnaya and S. Vinogradov et al., 2016. The use of pulsed high-speed liquid jet for putting out gas blow-out. Intl. J. Multiphys., 9: 9-20.
CrossRef  |  Direct Link  |  

Semko, A.N., M.V. Beskrovnaya, S.A. Vinogradov, I.N. Hritsina and N.I. Yagudina, 2014. The usage of high speed impulse liquid jets for putting out gas blowouts. J. Theor. Appl. Mech., 52: 655-664.
Direct Link  |  

Seow, J., 2013. Fire Fighting Foams with Perfluorochemicals-Environmental Review. The Hemming Group Ltd, Westminster, London, UK.,.

Sharovarnikov, S.A., D.A. Korolchenko and А.V. Lyapin, 2014. [Extinguishing of the multicomponent composite fuels by aqueous film forming foam by sublayer way (In Russian)]. Fire Explosion Saf., 23: 76-80.

Skutlarek, D., M. Exner and H. Farber, 2006. Perfluorinated surfactants in surface and drinking waters. Environ. Sci. Pollut. Res., 13: 299-307.
CrossRef  |  PubMed  |  Direct Link  |  

Sontake, A.R. and S.M. Wagh, 2014. The phase-out of perfluorooctane sulfonate (PFOS) and the global future of aqueous film forming foam (AFFF), innovations in fire fighting foam. Chem. Eng. Sci., 2: 11-14.
CrossRef  |  Direct Link  |  

Tarancev, A.A. and A.S. Chashin, 2015. [Application of modified water solutions for fire on the objects of railways (In Russian)]. MCHS., 2: 30-37.

Taysumov, K.A., 2012. [Environmentally safe foaming composition of heat-resistant foam]. European Patent Office, Russian. (In Russian)

Taysumov, K.A., 2012. [Foaming composition of heat-resistant hop based foam]. European Patent Office, Russian. (In Russian)

Thiruvenkatasamy, K. and F. Rahman, 2018. Pollution prevention challenges in the production process (separation and processing) of oil and gas industry. J. Eng. Appl. Sci., 13: 8086-8096.
CrossRef  |  Direct Link  |  

Timofeeva, S.S., V.V. Garmyshev, E.A. Kuzmicheva and A.I. Chernykh, 2017. [Ecological and economic assessment of air pollution due to fires at technosphere facilities in Irkutsk oblast (In Russian)]. Technosphere Saf., 2: 57-68.

Tregubov, D.G. and D.V. Miroshnichenko, 2005. Methods of decrease in sulfur content in coke. Koks Khim, 6: 21-28.

Turekova, I. and K. Balog, 2010. The environmental impacts of fire-fighting foams. Mater. Sci. Technol., 18: 111-120.
CrossRef  |  Direct Link  |  

Turekova, I., K. Balog and M. Polka, 2012. The efekt fire fighting foams on the environment and fire extinguishing. Saf. Fire Tech., 25: 29-35.
Direct Link  |  

Tyner, H.D., 1941. Fire-extinguishing effectiveness of chemicals in water solution. Ind. Eng. Chem., 33: 60-65.
CrossRef  |  Direct Link  |  

UNEP., 2015. Technical Guidelines on the Environmentally Sound Management of Wastes Consisting of Containing or Contaminated with Perfluorooctane Sulfonic Acid, its Salts and Perfluorooctane Sulfonyl Fluoride. United Nations Environment Programme, Nairobi, Kenya,.

VNIIPO., 1997. [NPB 51-96: Gas extinguishing compositions, general technical requirements for fire safety, test methods]. VNIIPO, Moscow Oblast, Russia. (In Russian)

Vasiliev, M.I., I.O. Movchan and O.M. Koval, 2014. Diminishing of ecological risk via optimization of fire-extinguishing system projects in timber-yards. National Hirnyuchy Univ. Sci. Visnik, 1: 106-113.
Direct Link  |  

Vasyukov, A., Loboichenko, V. and S. Bushtec, 2016. Identification of bottled natural waters by using direct conductometry. Ecol. Environ. Conserv., 22: 1171-1176.
Direct Link  |  

Vlasov, N.A. and T.Y. Eremina, 2017. [Fire extinguishing efficiency ofthe foam generated from iconcentrated aqueous salt solutions (In Russian)]. Fire Explosion Saf., 26: 52-58.

Vyalyshev, A., I. Lisovsky and A. Bolshagin, 2012. [Рossible consequences of emergency situation сaused by spills of oil and petroleum products on the sea (In Russian)]. Civ. Secur. Technol., 9: 62-69.

WHO., 2015. Improving the environment and health in Europe: How far have we progressed in achieving these goals?. WHO Regional Office for Europe, Copenhagen, Kobenhavn, Denmark.

Wang, S., 2018. Research on environmental impact of water-based fire extinguishing agents. IOP. Conf. Ser. Earth Environ. Sci., 113: 1-6.
CrossRef  |  Direct Link  |  

Wang, T., P. Wang, J. Meng, S. Liu and Y. Lu et al., 2015. A review of sources, multimedia distribution and health risks of perfluoroalkyl acids (PFAAs) in China. Chemosphere, 129: 87-99.
CrossRef  |  PubMed  |  Direct Link  |  

Xiao, F., 2017. Emerging poly-and perfluoroalkyl substances in the aquatic environment: A review of current literature. Water Res., 124: 482-495.
CrossRef  |  PubMed  |  Direct Link  |  

Xiao, F., M.F. Simcik, T.R. Halbach and J.S. Gulliver, 2015. Perfluorooctane sulfonate (PFOS) and perfluorooctanoate (PFOA) in soils and groundwater of a U.S. metropolitan area: Migration and implications for human exposure. Water Res., 72: 64-74.
CrossRef  |  PubMed  |  Direct Link  |  

Xie, S., T. Wang, S. Liu, K.C. Jones and A.J. Sweetman et al., 2013. Industrial source identification and emission estimation of perfluorooctane sulfonate in China. Environ. Intl., 52: 1-8.
CrossRef  |  PubMed  |  Direct Link  |  

Yelansky, E.A., V.A. Dyakov and E.G. Krasheninnikov, 2005. [Fire extinguishing methods: Gas extinguishing agents (In Russian)]. Fire Explosion Saf., 2: 87-90.

Zhartovsky, V.M., A.V. Antonov and S.G. Vlasenko, 1997. [Fire extinguishing compositions: The use of chemicals to extinguish fires]. Patent of the Russian Federation no 2086279, Russia. (In Russian)

Zhu, Q., Y. Liu, R. Jia, S. Hua and T. Shao et al., 2018. A numerical simulation study on the impact of smoke aerosols from Russian forest fires on the air pollution over Asia. Atmos. Environ., 182: 263-274.
CrossRef  |  Direct Link  |  

Ziemba, J., 2007. Environment a priority in rig fleet’s fire safety selection. World Oil, 228: 57-58.

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