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Fire Technology

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18-01-2017

Variation of Intumescent Coatings Revealing Different Modes of Action for Good Protection Performance

Authors: Michael Morys, Bernhard Illerhaus, Heinz Sturm, Bernhard Schartel

Published in: Fire Technology | Issue 4/2017

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Abstract

Thermal insulation and mechanical resistance play a crucial role for the performance of an intumescent coating. Both properties depend strongly on the morphology and morphological development of the foamed residue. Small amounts (4 wt%) of fiberglass, clay and a copper salt, respectively, are incorporated into an intumescent coating to study their influence on the morphology and performance of the residues. The bench scale fire tests were performed on 75 × 75 × 2 mm³ coated steel plates according to the standard time–temperature curve in the Standard Time Temperature Muffle Furnace⁺ (STT Mufu⁺). It provided information about foaming dynamics (expansion rates) and thermal insulation. Adding the copper salt halved the expansion height, whereas the clay and fiberglass change the height of the residue only moderately. The time to reach 500°C was improved by 31% for clay and 15% for the other two fillers. Nondestructive micro computed tomography is used to assess the inner structure of the residues. A transition of the residue from a black, carbonaceous foam with closed cells into an inorganic, residual open cell sponge occurs at high temperatures. This transition is due to a loss of carbon; the change in microstructure is analyzed by scanning electron microscopy. Additional mechanical tests are performed and interpreted with respect to the results of the morphology analysis. Adding clay or copper salt improved the mechanical resistance tested by a factor 4. The additives significantly influence the thickness and foaming dynamics as well as the inner structure of the residues, whereas their influence on insulation performance is moderate. In conclusion, different modes of action are observed to achieve similar insulation performance during the fire test.

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Vandersall H (1971) Intumescent coating systems, their development and chemistry. J Fire Flammabil 2(2):97–140

Bourbigot S, Le Bras M, Duquesne S, Rochery M (2004) Recent advances for intumescent polymers. Macromol Mater Eng 289(6):499–511. doi:10.1002/mame.200400007 CrossRef

Alongi J, Han ZD, Bourbigot S (2015) Intumescence: tradition versus novelty. A comprehensive review. Prog Polym Sci 51:28–73. doi:10.1016/j.progpolymsci.2015.04.010 CrossRef

Duquesne S, Magnet S, Jama C, Delobel R (2004) Intumescent paints: fire protective coatings for metallic substrates. Surf Coat Technol 180–181:302–307. doi:10.1016/j.surfcoat.2003.10.075 CrossRef

Weil ED (2011) Fire-protective and flame-retardant coatings—a state-of-the-art review. J Fire Sci 29(3):259–296. doi:10.1177/0734904110395469 CrossRef

Saxena NK, Gupta DR (1990) Development and evaluation of fire retardant coatings. Fire Technol 26(4):329–341. doi:10.1007/bf01293077 CrossRef

Hörold A, Schartel B, Trappe V, Gettwert V, Korzen M (2015) Protecting the structural integrity of composites in fire: intumescent coatings in the intermediate scale. J Reinf Plast Compos 34(24):2029–2044. doi:10.1177/0731684415609791 CrossRef

Hassan MA, Kozlowski R, Obidzinski B (2008) New fire-protective intumescent coatings for wood. J Appl Polym Sci 110(1):83–90. doi:10.1002/app.28518 CrossRef

Rhys JA (1980) Intumescent coatings and their uses. Fire Mater 4(3):154–156. doi:10.1002/fam.810040308 CrossRef

10.

Landucci G, Molag M, Reinders J, Cozzani V (2009) Experimental and analytical investigation of thermal coating effectiveness for 3 m3 LPG tanks engulfed by fire. J Hazard Mater 161(2–3):1182–1192. doi:10.1016/j.jhazmat.2008.04.097 CrossRef

11.

Droste B (1992) Fire protection of LPG tanks with thin sublimation and intumescent coatings. Fire Technol 28(3):257–269. doi:10.1007/bf01857695 CrossRef

12.

Schuff W, Clar C, Kühnel P, Tramm H (1934) Feuersichere Überzüge ergebendes Anstrichmittel. Germany Patent

13.

Anderson CE, Dziuk J, Mallow WA, Buckmaster J (1985) Intumescent reaction-mechanisms. J Fire Sci 3(3):161–194. doi:10.1177/073490418500300303 CrossRef

14.

Anderson CE, Ketchum DE, Mountain WP (1988) Thermal-conductivity of intumescent chars. J Fire Sci 6(6):390–410. doi:10.1177/073490418800600602 CrossRef

15.

Camino G, Costa L, Martinasso G (1989) Intumescent fire-retardant systems. Polym Degrad Stab 23(4):359–376. doi:10.1016/0141-3910(89)90058-x CrossRef

16.

Camino G, Costa L, Trossarelli L (1984) Study of the mechanism of intumescence in fire retardant polymers: part I—thermal degradation of ammonium polyphosphate-pentaerythritol mixtures. Polym Degrad Stab 6(4):243–252. doi:10.1016/0141-3910(84)90004-1 CrossRef

17.

Mesquita L, Piloto P, Vaz M, Pinto T (2009) Decomposition of intumescent coatings: comparison between a numerical method and experimental results. Acta Polytech 49(1):60–65

18.

Wang G, Yang J (2011) Influences of glass flakes on fire protection and water resistance of waterborne intumescent fire resistive coating for steel structure. Prog Org Coat 70(2–3):150–156. doi:10.1016/j.porgcoat.2010.10.007 CrossRef

19.

Wang Z, Han E, Ke W (2006) Effect of nanoparticles on the improvement in fire-resistant and anti-ageing properties of flame-retardant coating. Surf Coat Technol 200(20–21):5706–5716. doi:10.1016/j.surfcoat.2005.08.102 CrossRef

20.

Staggs J (2010) Thermal conductivity estimates of intumescent chars by direct numerical simulation. Fire Saf J 45(4):228–237CrossRef

21.

Cirpici BK, Wang YC, Rogers B (2016) Assessment of the thermal conductivity of intumescent coatings in fire. Fire Saf J 81:74–84. doi:10.1016/j.firesaf.2016.01.011 CrossRef

22.

Li G-Q, Zhang C, Lou G-B, Wang Y-C, Wang L-L (2012) Assess the fire resistance of intumescent coatings by equivalent constant thermal resistance. Fire Technol 48(2):529–546. doi:10.1007/s10694-011-0243-8 CrossRef

23.

Wang L, Dong Y, Zhang C, Zhang D (2015) Experimental study of heat transfer in intumescent coatings exposed to non-standard furnace curves. Fire Technol 51(3):627–643. doi:10.1007/s10694-015-0460-7 CrossRef

24.

Reshetnikov IS, Yablokova MY, Potapova EV, Khalturinskij NA, Chernyh VY, Mashlyakovskii LN (1998) Mechanical stability of intumescent chars. J Appl Polym Sci 67(10):1827–1830. doi:10.1002/(sici)1097-4628(19980307)67:10<1827::aid-app16>3.0.co;2-t CrossRef

25.

Norgaard KP, Dam-Johansen K, Catala P, Kiil S (2013) Investigation of char strength and expansion properties of an intumescent coating exposed to rapid heating rates. Prog Org Coat 76(12):1851–1857. doi:10.1016/j.porgcoat.2013.05.028 CrossRef

26.

Naik AD, Duquesne S, Bourbigot S (2016) Hydrocarbon time-temperature curve under airjet perturbation: an in situ method to probe char stability and integrity in reactive fire protection coatings. J Fire Sci. doi:10.1177/0734904116658049

27.

Bugajny M, Bras ML, Bourbigot S (1999) New approach to the dynamic properties of an intumescent material. Fire Mater 23(1):49–51. doi:10.1002/(sici)1099-1018(199901/02)23:1<49::aid-fam668>3.0.co;2-d CrossRef

28.

Morys M, Illerhaus B, Sturm H, Schartel B (2016) Revealing the inner secrets of intumescence: Advanced standard time temperature oven (STT Mufu +)—μ-computed tomography approach. Fire Mater (submitted)

29.

Bailey C (2004) Indicative fire tests to investigate the behaviour of cellular beams protected with intumescent coatings. Fire Saf J 39(8):689–709. doi:10.1016/j.firesaf.2004.06.007 CrossRef

30.

Dai XH, Wang YC, Bailey CG (2009) Effects of partial fire protection on temperature developments in steel joints protected by intumescent coating. Fire Saf J 44(3):376–386. doi:10.1016/j.firesaf.2008.08.005 CrossRef

31.

Jimenez M, Duquesne S, Bourbigot S (2006) High-throughput fire testing for intumescent coatings. Ind Eng Chem Res 45(22):7475–7481. doi:10.1021/ie0608410 CrossRef

32.

Jimenez M, Duquesne S, Bourbigot S (2006) Intumescent fire protective coating: toward a better understanding of their mechanism of action. Thermochim Acta 449(1–2):16–26. doi:10.1016/j.tca.2006.07.008 CrossRef

33.

Jimenez M, Duquesne S, Bourbigot S (2006) Multiscale experimental approach for developing high-performance intumescent coatings. Ind Eng Chem Res 45(13):4500–4508. doi:10.1021/ie060040x CrossRef

34.

Bartholmai M, Schartel B (2007) Assessing the performance of intumescent coatings using bench-scaled cone calorimeter and finite difference simulations. Fire Mater 31(3):187–205. doi:10.1002/Fam.933 CrossRef

35.

Bartholmai M, Schriever R, Schartel B (2003) Influence of external heat flux and coating thickness on the thermal insulation properties of two different intumescent coatings using cone calorimeter and numerical analysis. Fire Mater 27(4):151–162. doi:10.1002/Fam.823 CrossRef

36.

Schartel B, Hull TR (2007) Development of fire-retarded materials—interpretation of cone calorimeter data. Fire Mater 31(5):327–354. doi:10.1002/Fam.949 CrossRef

37.

Amir N, Abd Majid AA, Ahmad F (2016) Effects of hybrid fibre reinforcement on fire resistance performance and char morphology of intumescent coating. In: Karim ZAA, Baharudin ZH, Basrawi MF, Rahman MM, Noor MM (eds) Utp-ump symposium on energy systems 2015, vol 38. MATEC Web of Conferences. doi:10.1051/matecconf/20163803001

38.

Amir N, Ahmad F, Megat-Yusoff PSM (2012) Char strength of wool fibre reinforced epoxy-based intumescent coatings (FRIC). In: Abdullah MMA, Jamaludin L, Razak RA, Yahya Z, Hussin K (eds) Advanced materials engineering and technology, vol 626. Advanced Materials Research, pp 504–508. doi:10.4028/www.scientific.net/AMR.626.504

39.

Aziz H, Ahmad F, Yusoff P, Zia-Ul-Mustafa M (2014) Effect of kaolin clay and alumina on thermal performance and char morphology of intumescent fire retardant coating. In: Karuppanan S, Karim ZAA, Ovinis M, Baheta AT (eds) Icper 2014—4th international conference on production, energy and reliability, vol 13. MATEC Web of Conferences

40.

Fan F-Q, Xia Z-B, Li Q-Y, Li Z (2013) Effects of inorganic fillers on the shear viscosity and fire retardant performance of waterborne intumescent coatings. Prog Org Coat 76(5):844–851. doi:10.1016/j.porgcoat.2013.02.002 CrossRef

41.

Kahraman HT, Gevgilili H, Pehlivan E, Kalyon DM (2015) Development of an epoxy based intumescent system comprising of nanoclays blended with appropriate formulating agents. Prog Org Coat 78:208–219. doi:10.1016/j.porgcoat.2014.09.002 CrossRef

42.

Ullah S, Ahmad F, Shariff AM, Bustam MA (2014) Synergistic effects of kaolin clay on intumescent fire retardant coating composition for fire protection of structural steel substrate. Polym Degrad Stab 110:91–103. doi:10.1016/j.polymdegradstab.2014.08.017 CrossRef

43.

Duquesne S, Bachelet P, Bellayer S, Bourbigot S, Mertens W (2013) Influence of inorganic fillers on the fire protection of intumescent coatings. J Fire Sci 31(3):258–275. doi:10.1177/0734904112467291 CrossRef

44.

Li H, Hu Z, Zhang S, Gu X, Wang H, Jiang P, Zhao Q (2015) Effects of titanium dioxide on the flammability and char formation of water-based coatings containing intumescent flame retardants. Prog Org Coat 78:318–324. doi:10.1016/j.porgcoat.2014.08.003 CrossRef

45.

CEN (1999) EN 1363-1: 1999-10: Feuerwiderstandsprüfungen–Allgemeine Anforderungen

46.

Muller M, Bourbigot S, Duquesne S, Klein R, Giannini G, Lindsay C, Vlassenbroeck J (2013) Investigation of the synergy in intumescent polyurethane by 3D computed tomography. Polym Degrad Stab 98(9):1638–1647. doi:10.1016/j.polymdegradstab.2013.06.018 CrossRef

47.

Brehme S, Schartel B, Goebbels J, Fischer O, Pospiech D, Bykov Y, Döring M (2011) Phosphorus polyester versus aluminium phosphinate in poly(butylene terephthalate) (PBT): flame retardancy performance and mechanisms. Polym Degrad Stab 96(5):875–884. doi:10.1016/j.polymdegradstab.2011.01.035 CrossRef

48.

Müller P, Morys M, Sut A, Jäger C, Illerhaus B, Schartel B (2016) Melamine poly(zinc phosphate) as flame retardant in epoxy resin: decomposition pathways, molecular mechanisms and morphology of fire residues. Polym Degrad Stab 130:307–319. doi:10.1016/j.polymdegradstab.2016.06.023 CrossRef

49.

Goebbels J, Illerhaus B, Onel Y, Riesemeier H, Weidemann G (2004) 3D-computed tomography over four orders of magnitude of X-ray energies. In: 16th world conference on nondestructive testing, Montreal, Canada

50.

DIN (1994) DIN 4102 Teil 4 Brandverhalten von Baustoffen und Bauteilen

51.

Sturm H, Schartel B, Weiß A, Braun U (2012) SEM/EDX: advanced investigation of structured fire residues and residue formation. Polym Testing 31 (5):606–619. doi:10.1016/j.polymertesting.2012.03.005 CrossRef

Title: Variation of Intumescent Coatings Revealing Different Modes of Action for Good Protection Performance
Authors: Michael Morys
Bernhard Illerhaus
Heinz Sturm
Bernhard Schartel
Publication date: 18-01-2017
Publisher: Springer US
Published in: Fire Technology / Issue 4/2017
Print ISSN: 0015-2684
Electronic ISSN: 1572-8099
DOI: https://doi.org/10.1007/s10694-017-0649-z

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