The Role of Carbonized Layers for Fire Protection of Polymer Materials

Z. A. Mansurov; B. Ya. Kolesnikov; V. L. Efremov

doi:10.18321/ectj709

Authors

Z. A. Mansurov The Institute of Combustion Problems, 050012, Bogenbay batyr str. 172, Almaty Kazakhstan
B. Ya. Kolesnikov The Institute of Combustion Problems, 050012, Bogenbay batyr str. 172, Almaty Kazakhstan
V. L. Efremov The Institute of Combustion Problems, 050012, Bogenbay batyr str. 172, Almaty Kazakhstan

DOI:

https://doi.org/10.18321/ectj709

Abstract

The present work studies the processes occurring in pre-flame zone in the form of «candle-like flame» which is spread over the surface of epoxy polymer. As exemplified by epoxy polymer, it can be seen that the dominating mechanism of heat transfer from flame to pre-flame zone of carbonized polymers is a thermal conductivity by condensed phase (to phase). The mechanism of gasification processes in pre-flame zone is proposed. Gasification of the material in front of the flame edge is a controlling process, and when selecting flame retardants, it is necessary to register their ability to influence on kinetics and mechanism of gasification. The flame leading edge is bordered with the surface of polymer, which largely determines the nature of heat transfer in pre-flame region. Due to investigations of gas-phase composition at «candle-like» combustion of epoxy polymer it has been detected a considerable amount of oxygen (up to 10‒12%) near burning surface. Its presence facilitates the thermal oxidation of polymer, moreover the rate of thermal oxidation can significantly exceed the thermal decomposition rate of the polymer. The possibility to form the heat-insulating intumescent layer during decomposition of carbonizable polymers was used at development of flame retardant coatings ‒ complex multicomponent systems. Which in turns forms the intumescent carbonized layer with high porosity and low thermal conductivity, and protects based material or construction from premature heating up to critical temperatures.

References

(1). Xiu-yan Pang, Wei-shu Chang, Academic journal of chemistry 2 (1) (2017) 1‒7.

(2). Xiaodong Jin, Jun Sun, Jessica Shiqing Zhang, Xiaoyu Gu, Serge Bourbigot, Hongfei Li, Wufei Tang, Sheng Zhang, ACS Appl. Mater. Interfaces 9 (29) (2017) 24964‒24975. Crossref

(3). H.L. Gao, S. Hu, H.C. Han, and J. Zhang, J. Appl. Polym. Sci. 122 (2011) 3263‒3269. Crossref

(4). Chang Lu, Qing-qing Cao, Xiao-ning Hu, Cui-yun Liu, Xin-hui Huang, Yu-qing Zhang, Fire Mater. 38 (2014) 765‒776. Crossref

(5). H. Seefeldt, U. Braun, and M.H. Wagner, Macromol. Chem. Phys. 213 (2012) 2370‒2377. Crossref

(6). A.A. Berlin, Combustibility reduction of polymeric materials. Low-combustible polymeric materials. The materials of VIII International Conference. 5-10 June 2017, al-Farabi Kazakh National University, Almaty, 2017, p. 22 (in Russian).

(7). B.Ya. Kolesnikov, Peculiarities of combustion and flame inhibition of epoxide polymers // Dissertation of Doctor of Chemistry, Alma-Ata, 1987, p. 350 (in Russian).

(8). Z.А. Mansurov, R.G. Abdulkarimova, R.М. Mansurova, B.Ya. Kolesnikov, G.I. Ksandopulo, EPR-spectroscopic study of destruction processes of epoxide compounds. 1 All-Soviet Union symposium on macroscopic kinetics and chemical gasdynamics: Thesis report – Chernogolovka, 1 (2) (1984) 143–144. (in Russian).

(9). V.L. Efremov, B.Ya. Kolesnikov, G.I. Ksandopulo. Vysokomolekuljarnye soedinenija [High-molecular compounds] 20 (11) (A) (1978) 2587‒2591 (in Russian).

(10). B.Ya. Kolesnikov, V.L. Efremov, N.S. Umarbekov, A.B. Kolesnikov. Flames, Lasers and Reactive Systems, Progress in Astronautics and Aeronautics 88 (1983) 228‒236. Crossref

(11). A.B. Kolesnikov, B.Ya. Kolesnikov, Eurasian Chemico-Technological Journal 2 (2) (2000) 191‒200. Crossref

(12). A.B. Jung, A.B. Kolesnikov, Detailed mechanism of a flame spread oven an epoxy polymer surface. 4th International seminar on fire and explosion hazards, 8-12 Sept. 2003, Londonderry, UK, Book of abstracts, 2003, p. 94‒95.

(13). R.M. Aseeva, G.E. Zaikov. Combustion of polymeric materials. – М.: Science,1981, p. 280 (in Russian).

(14). S.K. Brauman, J. Fire Retard. Chem. 6 (4) (1979) 266‒275.

(15). S. Bourbigot, M. LeBras, R. Delobel, Carbon 31 (1993) 1219–1294. Crossref

(16). S.А. Yamshikova, Increasing of fire-retardant ability of intumescent coatings for oil and gas industry objects. Autoabstract, thesis for the degree of Doctor of chemistry, Ufa, 2009, p. 24. (in Russian).

(17). S.A. Nenakhov, V.P. Pimenova, L.I. Nateikina, The Effect of Fillers on the Structure of Foamed Coke Based on Ammonium Polyphosphate, Pozharovzryvobezopasnost' [Fire and Explosion Safety] 18 (7) (2009) 51–58 (in Russian).

(18). S.А. Nenakhov, V.P. Pimenova, Effect of Concentration of Gas-Generating Agent on Regularities of Development Fireproofing Foamed Cokes, Pozharovzryvobezopasnost' [Fire and Explosion Safety] 19 (3) (2010) 14–26 (in Russian).

(19). S.А. Nenakhov, V.P. Pimenova, Physico- Chemical Foaming Fire-Retardant Coatings Based on Ammonium Polyphosphate, Pozharovzryvobezopasnost' [Fire and Explosion Safety] 19 (8) (2010) 11–58 (in Russian).

(20). M. Le Bras and S. Bourbigot. In: M. Le Bras, G. Camino, S. Bourbigot and R. Delobel, Editors. Fire retarded intumescent thermoplastics formulations, synergy and synergistic agent. The Royal Society of Chemistry, Cambridge (1998). p. 64–75.

(21). G. Camino, M.P. Luda. Mechanistic Study on Intumescence. In book: Fire Retardancy of Polymers. The Use of Intumescence. Published by the Royal Society of Chemistry, Cambridge, UK, 1998, p.49-63.

(22). S.G. Shuklin, Carbonization processes during formation of multi-layered fire-proof coatings containing carbonaceous metal-containing nanostructures. Autoabstract, thesis for the degree of Doctor of chemistry. Izhevsk, 2006, p. 34 (in Russian).

The Role of Carbonized Layers for Fire Protection of Polymer Materials

Authors

DOI:

Abstract

References

Downloads

Published

How to Cite

Issue

Section

License

Most read articles by the same author(s)

test

Developed By

Make a Submission

database

Information