Affiliation:
1. Ural Institute of State Fire Service of EMERCOM of Russia
2. Saint Petersburg university of State fire service of EMERCOM of Russia
Abstract
Modern polymer materials used in construction, transport and household products characterized, as a rule, by high flammability and combustibility, which has a significant impact on ensuring the required level of fire protection. A variant of the formalization of the choice of a flame retardant coating is proposed and an algorithm for its justification is proposed. The proposed algorithm for choosing a fire-retardant coating assumes a preliminary quantitative assessment of fire danger; analysis of possible scenarios of fire development; the choice of the type of fire protection system taking into account the operating environment, the size of potential damage from fire, technical, economic and human factors, and the rationale for choosing a fire-resistant coating that provides the specified (required) level of fire protection.
Publisher
St. Petersburg University of the State Fire Service of EMERCOM of Russia
Reference22 articles.
1. Fast fabrication of a light-scattering polycarbonate with high transmittance, high haze, and excellent flame-retardant performance / Y. Duan [et al.] // J. Appl. Polym. Sci. 2022. Vol. 139 (43). P. 53055. DOI: 10.1002/app.53055., Fast fabrication of a light-scattering polycarbonate with high transmittance, high haze, and excellent flame-retardant performance / Y. Duan [et al.] // J. Appl. Polym. Sci. 2022. Vol. 139 (43). P. 53055. DOI: 10.1002/app.53055.
2. Transparent, highly thermostable and flame retardant polycarbonate enabled by rod-like phosphorous-containing metal complex aggregates / T. Sai [et al.] // Chemical engineering journal. 2021. Т. 409. С. 128223. DOI: 10.1016/j.cej.2020.128223., Transparent, highly thermostable and flame retardant polycarbonate enabled by rod-like phosphorous-containing metal complex aggregates / T. Sai [et al.] // Chemical engineering journal. 2021. T. 409. P. 128223. DOI: 10.1016/j.cej.2020.128223.
3. Повышение безопасности объектов нефтегазового комплекса путем совершенствования огнезащитных составов / Е.В. Головина [и др.] // Пожаровзрывобезопасность. 2022. Т. 31. № 3. С. 24–33. DOI: 10.22227/0869-7493.2022.31.03.24-33., Povyshenie bezopasnosti ob"ektov neftegazovogo kompleksa putem sovershenstvovaniya ognezashchitnyh sostavov / E.V. Golovina [i dr.] // Pozharovzryvobezopasnost'. 2022. T. 31. № 3. S. 24–33. DOI: 10.22227/0869-7493.2022.31.03.24-33.
4. Making polycarbonate flame retardant: Flame retardant selection and calorimetric analyses / De-jia Chen [et al.] // Polymer testing. 2023. Vol. 117. P. 107876. DOI: 10.1016/j.polymertesting.2022.107876., Making polycarbonate flame retardant: Flame retardant selection and calorimetric analyses / De-jia Chen [et al.] // Polymer testing. 2023. Vol. 117. P. 107876. DOI: 10.1016/j.polymertesting.2022.107876.
5. Совершенствование методов и средств огнезащиты на основе термостойких минеральных заполнителей для металлических конструкций: монография / А.Ю. Акулов [и др.]. Екатеринбург: Уральский институт ГПС МЧС России, 2015. 161 с., Sovershenstvovanie metodov i sredstv ognezashchity na osnove termostojkih mineral'nyh zapolnitelej dlya metallicheskih konstrukcij: monografiya / A.Yu. Akulov [i dr.]. Ekaterinburg: Ural'skij institut GPS MCHS Rossii, 2015. 161 s.