Flame retardant nanocomposites with polymer blends

doi:10.1017/CBO9780511842412.009

8 - Flame retardant nanocomposites with polymer blends

from Part II - Flame retardancy

Published online by Cambridge University Press: 05 August 2011

J. Zhang ,

M. A. Delichatsios ,

A. Fina ,

G. Camino ,

F. Samyn ,

S. Bourbigot and

S. Nazaré

Edited by

Vikas Mittal

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Vikas Mittal: Affiliation:
The Petroleum Institute, Abu Dhabi

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Summary

Introduction

Over the past decades, nanoclays have been widely used as additives to improve the strength as well as the fire performance of polymers, as evidenced by applications and a large number of studies reported in the literature. The mechanism of action of nanoclays is now relatively well understood, despite some aspects remaining unclear, such as the phenomena controlling ignition time. During the burning of polymer nanocomposites, a surface layer is formed on top of the virgin polymer, which acts as a mass and heat shield slowing down mass transfer of pyrolyzed gas to the surface, because less heat is transferred to unpyrolyzed material. Furthermore, in the presence of nanoparticles, the temperature at the surface of the surface layer increases far beyond the so-called ignition temperature of the polymer, which results in increased surface reradiation losses and, hence, decreased heat transfer to the solid. The formation of this surface layer has been observed in a number of studies using the cone calorimeter, where a significant reduction of the peak heat release rate (PHRR) compared with the corresponding pure polymer was observed for relatively thin samples. Zhang, Delichatsios, and Bourbigot also studied the effect of the surface layer numerically, finding that the reduction in heat transfer at the interface of the surface layer and the virgin polymer is inversely proportional to the number of nanoparticles that remain on the surface after degradation of the polymer (if the concentration of nanoparticles is less than about 10%).

Type: Chapter
Information: Thermally Stable and Flame Retardant Polymer Nanocomposites , pp. 186 - 209

DOI: https://doi.org/10.1017/CBO9780511842412.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

Gilman, J. W.Kashiwagi, T.Morgan, A. B.Harris, R. H.Brassell, L.VanLandingham, M.Jackson, C. L.Flammability of Polymer Clay Nanocomposites Consortium: Year One Annual ReportNational Institute of Standards and Technology 2000CrossRef Google Scholar

Kashiwagi, T.Grulke, E.Hilding, J.Groth, K.Harris, R.Butler, K.Shields, J.Kharchenko, S.Douglas, J.Thermal and flammability properties of polypropylene/carbon nanotube nanocompositesPolymer 45 2004 4227CrossRef Google Scholar

Kashiwagi, T.Harris, Jr. R. H.Zhang, X.Briber, R. M.Cipriano, B. H.Raghavan, S. R.Awad, W. H.Shields, J. R.Flame retardant mechanism of polyamide 6–clay nanocompositesPolymer 45 2004 881CrossRef Google Scholar

Liu, X.Quintiere, J. G.The thick and thin of burning nano-clay–nylonProceedings of the 8th International Symposium on Fire Safety ScienceBostonIntl. Assoc. for Fire Safety Science 2005 647Google Scholar

Wilkie, C. A.Recent advances in fire retardancy of polymer–clay nanocompositesProceedings of the 13th Annual BCC Conference on Flame RetardancyLewin, M.NorwalkBCC Research 2002Google Scholar

Bok, N. J.Charles, A. W.The effect of clay on the thermal degradation of polyamide 6 in polyamide 6/clay nanocompositesPolymer 46 2005 3264Google Scholar

Qin, H.Su, Q.Zhang, S.Zhao, B.Yang, M.Thermal stability and flammability of polyamide 66/montmorillonite nanocompositesPolymer 44 2003 7533CrossRef Google Scholar

Dabrowski, F.Bourbigot, S.Delobel, R.Le Bras, M.Kinetic modelling of the thermal degradation of polyamide-6 nanocompositeEuropean Polymer Journal 36 2000 273CrossRef Google Scholar

Zanetti, M.Camino, G.Canavese, D.Morgan, A. B.Lamelas, F. J.Wilkie, C. A.Fire retardant halogen–antimony–clay synergism in polypropylene layered silicate nanocompositesChemistry of Materials 14 2002 189CrossRef Google Scholar

Fina, A.Bocchini, S.Camino, G.Thermal behavior of nanocomposites and fire testing performanceFire and Polymers V, Materials and Concepts for Fire RetardancyACS Symposium Series No10013Wilkie, C. A.Morgan, A. B.Nelson, G. L.Washington, DCAm. Chem. Soc 2009Google Scholar

Zhang, J.Delichatsios, M.Bourbigot, S.Experimental and numerical study of the effects of nanoparticles on pyrolysis of a polyamide 6 (PA6) nanocomposite in the cone calorimeterCombustion and Flame 156 2009 2056CrossRef Google Scholar

Robeson, L. M.Polymer Blends: A Comprehensive ReviewGermanyHanser 2007CrossRef Google Scholar

Utracki, L. A.Polymer Blends Handbook1Dordrecht, the NetherlandsKluwer Academic 2003CrossRef Google Scholar

Paul, D. R.Bucknall, C. B.Polymer Blends Set: Formulation and PerformanceNew York: Wiley 2000Google Scholar

Chuang, T. H.Guo, W.Cheng, K. C.Chen, S. W.Wang, H. T.Yen, Y. Y.Thermal properties and flammability of ethylene–vinyl acetate copolymer/montmorillonite/polyethylene nanocomposites with flame retardantsJournal of Materials Research 11 2004 169Google Scholar

Sinha Ray, S.Bousmina, M.Compatibilization efficiency of organoclay in an immiscible polycarbonate/poly(methyl methacrylate) blendMacromolecular Rapid Communications 26 2005 450CrossRef Google Scholar

Sinha Ray, S.Bousmina, M.Effect of organic modification on the compatibilization efficiency of clay in an immiscible polymer blendMacromolecular Rapid Communications 26 2005 1639CrossRef Google Scholar

Lee, M. H.Dan, C. H.Kim, J. H.Cha, J.Kim, S.Hwang, Y.Lee, C. H.Effect of clay on the morphology and properties of PMMA/poly(styrene-co-acrylonitrile)/clay nanocomposites prepared by melt mixingPolymer 47 2006 4359CrossRef Google Scholar

Xu, Y.Brittain, W. J.Vaia, R. A.Price, G.Improving the physical properties of PEA/PMMA blends by the uniform dispersion of clay plateletsPolymer 47 2006 4564CrossRef Google Scholar

Chang, Z.Guo, F.Chen, J.Yu, J.Wang, G.Synergistic flame retardant effects of nanokaolin and nano-HAO on LDPE/EPDM compositesPolymer Degradation and Stability 92 2007 1204CrossRef Google Scholar

Haurie, L.Fernández, A.Velasco, J.Chimenos, J.Lopez Cuesta, J.Espiell, F.Thermal stability and flame retardancy of LDPE/EVA blends filled with synthetic hydromagnesite/aluminium hydroxide/montmorillonite and magnesium hydroxide/aluminium hydroxide/montmorillonite mixturesPolymer Degradation and Stability 92 2007 1082CrossRef Google Scholar

Lai, S. M.Li, H. C.Liao, Y. C.Properties and preparation of compatibilized nylon 6 nanocomposites/ABS blends. Part II – Physical and thermal propertiesEuropean Polymer Journal 43 2007 1660CrossRef Google Scholar

Yu, Z.Yin, J.Yan, S.Xie, Y.Ma, J.Chen, X.Biodegradable poly(L-lactide)/poly(ɛ-caprolactone)-modified montmorillonite nanocomposites: Preparation and characterizationPolymer 48 2007 6439CrossRef Google Scholar

Elias, L.Fenouillot, F.Majesté, J. C.Cassagnau, P.Morphology and rheology of immiscible polymer blends filled with silica nanoparticlesPolymer 48 2007 6029CrossRef Google Scholar

Scaffaro, R.Mistretta, M. C.La Mantia, F. P.Compatibilized polyamide 6/polyethylene blend–clay nanocomposites: Effect of the degradation and stabilization of the clay modifierPolymer Degradation and Stability 93 2008 1267CrossRef Google Scholar

Acharya, H.Kuila, T.Srivastava, S. K.Bhowmick, A. K.Effect of layered silicate on EPDM/EVA blend nanocomposite: Dynamic mechanical, thermal, and swelling propertiesPolymer Composites 29 2008 443CrossRef Google Scholar

Zhang, J.Hereid, J.Hagen, M.Bakirtzis, D.Delichatsios, M. A.Effects of nanoclay and fire retardants on fire retardancy of a polymer blend of EVA and LDPEFire Safety Journal 44 2009 504CrossRef Google Scholar

Gcwabaza, T.Sinha Ray, S.Focke, W. W.Maity, A.Morphology and properties of nanostructured materials based on polypropylene/poly(butylene succinate) blend and organoclayEuropean Polymer Journal 45 2009 353CrossRef Google Scholar

Park, S.Kashiwagi, T.Stemp, D.Koo, J.Si, M.Sokolov, J. C.Rafailovich, M. H.Segregation of carbon nanotubes/organoclays rendering polymer blends self-extinguishingMacromolecules 42 2009 6698Google Scholar

Park, S.Si, M.Koo, J.Sokolov, J. C.Koga, T.Kashiwagi, T.Rafailovich, M. H.Mode-of-action of self-extinguishing polymer blends containing organoclaysPolymer Degradation and Stability 94 2009 306Google Scholar

Nayak, S. K.Mohanty, S.Poly (trimethylene) terephthalate/m-LLDPE blend nanocomposites: Evaluation of mechanical, thermal and morphological behaviourMaterials Science and Engineering A 527 2010 574CrossRef Google Scholar

Fenouillot, F.Cassagnau, P.Majesté, J. C.Uneven distribution of nanoparticles in immiscible fluids: Morphology development in polymer blendsPolymer 50 2009 1333CrossRef Google Scholar

Osman, M. A.Ploetze, M.Suter, U. W.Surface treatment of clay minerals – Thermal stability, basal-plane spacing and surface coverageJournal of Materials Chemistry 13 2003 2359CrossRef Google Scholar

Camino, G.Sgobbi, R.Zaopo, S.Colombier, S.Scelza, C.Investigation of flame retardancy in EVAFire and Materials 24 2000 853.0.CO;2-T>CrossRef Google Scholar

Allen, N. S.Edge, M.Rodriguez, M.Liauw, C. M.Fontan, E.Aspects of the thermal oxidation of ethylene vinyl acetate copolymerPolymer Degradation and Stability 6 2000 363CrossRef Google Scholar

Beyer, G.Flame retardant properties of EVA-nanocomposites and improvements by combination of nanofillers with aluminium trihydrateFire and Materials 25 2001 193CrossRef Google Scholar

Manos, T.Yusof, I. Y.Papayannakos, N.Gangas, N. H.Catalytic cracking of polyethylene over clay catalysts: Comparison with an ultrastable Y zeoliteIndustrial and Engineering Chemistry Research 40 2001 2220CrossRef Google Scholar

Tartaglione, G.Tabuani, D.Camino, G.Moisio, M.PP and PBT composites filled with sepiolite: Morphology and thermal behaviourComposites Science and Technology 68 2008 451CrossRef Google Scholar

Bourbigot, S.Le Bras, M.Leeuwendal, R.Shen, K. K.Schubert, D.Recent advances of zinc borates in flame retardancy of EVAPolymer Degradation and Stability 64 1999 419CrossRef Google Scholar

Hornsby, P. R.Rothon, R. N.Fire retardant fillers for polymersFire Retardancy of PolymersLe Bras, M.Wilkie, C.Bourbigot, S.CambridgeRoyal Society of Chemistry 2005Google Scholar