Combustion Behaviour of Epoxide Based Nanocomposites with Ammonium and Phosphonium Bentonites

Hartwig, Andreas; Pütz, Dirk; Schartel, Bernhard; Bartholmai, Matthias; Wendschuh-Josties, M.

doi:10.1002/macp.200300047

Cited by 61 publications

(34 citation statements)

References 15 publications

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“…Hence, the comprehensive cone calorimeter results presented in this article indicate that no significant improvement may be expected for nanocomposites in terms of flammability tests, as shown in a previous study. 32 What is more, the absolute high values indicated that both PP-g-MA and the nanocomposites will not show self-extinguishing behavior.…”

Section: à2mentioning

confidence: 98%

Layered silicate polymer nanocomposites: new approach or illusion for fire retardancy? Investigations of the potentials and the tasks using a model system

Bartholmai

Schartel

2004

Polymers for Advanced Techs

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229

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Polymeric nanocomposites are discussed as one of the most promising advanced materials whose nanoscale effects can be exploited for industry. Layered silicate polypropylene-graft-maleic anhydride nanocomposites are investigated as a model to clarify the potential of such materials in terms of fire retardancy. The nanostructure is characterized using transmission electron microscopy (TEM) and shear viscosity. The fire behavior is characterized using different external heat fluxes in cone calorimeter, limiting oxygen index and UL 94 classification. A comprehensive fire behavior characterization is presented which enables an assessment of the materials' potential with respect to different fire scenarios and fire tests. The influence of morphology and the active mechanisms are discussed, such as barrier formation and changed melt viscosity. To our knowledge, it is the first attempt to illuminate the concept's strengths, such as the reduction of flame spread, and weaknesses, such as the lack of influence on ignitability, in a clear, comprehensive and detailed manner.

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Section: à2mentioning

confidence: 98%

Layered silicate polymer nanocomposites: new approach or illusion for fire retardancy? Investigations of the potentials and the tasks using a model system

Bartholmai

Schartel

2004

Polymers for Advanced Techs

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229

133

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“…This positive characteristic of tetraphenyl phosphonium-modified LS has been reported before as an advantage over ammonium-modified LS. [27][28][29] Only when an irradiation of 50 kW m À2 was applied, adding G showed a tendency to shorten the t ig . Such a worsening tendency was not explained by a difference in decomposition and thus may have physical reasons.…”

Section: Flammability and Ignitabilitymentioning

confidence: 99%

Synergistic fire retardancy in layered-silicate nanocomposite combined with low-melting phenysiloxane glass

Schartel

et al. 2011

Journal of Fire Sciences

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Tetraphenyl phosphonium-modified layered silicate (LS) and low-melting phenylsiloxane glass (G) are combined for more efficient halogen-free flame retardancy in epoxy resin (EP_LSG). Particularly, the peak heat release rate (PHRR) is decreased (by up to 60%), but levels off at additive concentrations !10 wt%. The performance of EP_LSG is compared to EP_LS and EP_G assuming an absolute and a relative flame retardancy effect, respectively, and based on the same amount of each filler and, alternatively, with EP_G containing the same overall amount of filler. EP_LSG behaves close to superposition but shows a strong tendency toward synergism due to a superior structural integrity of the fire residues. Apart from LS, adding G in particular is a promising approach when its content is 5 wt%, as is LSG for !10 wt%.

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“…Introduction of up to 10 mass% of nano-layered mineral silicates may cause the increase of the initial decomposition temperature even as much as over 15°C [19,[26][27][28]. This additives decrease also the rate of composites combustion [29]. However, despite advantages mentioned above, nanoclays do not guarantee incombustibility.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and thermal studies of flexible polyurethane nanocomposite foams obtained using nanoclay modified with flame retardant compound

Piszczyk

Danowska

Mietlarek-Kropidłowska

et al. 2014

J Therm Anal Calorim

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This work presents thermal studies of nanocomposites based on the flexible polyurethane (PU) matrix and filled using montmorillonite organically modified with organophosphorus flame retardant compound. Flexible PU nanocomposite foams were prepared in the reaction carried out between reactive alcoholic hydroxyl and isocyanate groups with the ratio of NCO to OH groups equal to 1.05. The amount of an organoclay ranging from 3 to 9 vol% was added to the polyol component of the resin before mixing with isocyanate. The apparent density of PU foams was ranging from 0.066 to 0.077 g cm -1 . Thermal properties of the flexible PU nanocomposite foams were investigated by thermogravimetry and dynamical mechanical analysis. Glass transition temperatures (T g ) were defined as maximum peak on tand curve. Thermal decomposition was observed at 310-320°C (calculated from the onset of TG curve). Tensile strength of the PU foams was determined using mechanical test. The microstructure of the nanoparticles and the composites was investigated by X-ray diffraction. Finally, it was confirmed that the thermal and mechanical properties of flexible PU nanocomposite depend on the amount of nanoclay.

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Combustion Behaviour of Epoxide Based Nanocomposites with Ammonium and Phosphonium Bentonites

Cited by 61 publications

References 15 publications

Layered silicate polymer nanocomposites: new approach or illusion for fire retardancy? Investigations of the potentials and the tasks using a model system

Layered silicate polymer nanocomposites: new approach or illusion for fire retardancy? Investigations of the potentials and the tasks using a model system

Synergistic fire retardancy in layered-silicate nanocomposite combined with low-melting phenysiloxane glass

Synthesis and thermal studies of flexible polyurethane nanocomposite foams obtained using nanoclay modified with flame retardant compound

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