Synergistic effect of melamine and tricresyl phosphate on fire retardant properties of semi flexible polyurethane foam

Abstract

Semi flexible polyurethane (PU) foam provides various applications in aerospace as well as daily life due to its vibration dampening, sound absorption, thermal insulation properties etc. One of the major disadvantages of PU foams is its poor fire-resistant characteristics. The present study aimed to improve the fire retardant behavior of PU foam by incorporation of fillers like melamine powder (M.P) and tricresyl phosphate (TCP) in PU matrix. A set of PU foams were prepared with M.P alone, with TCP alone and with a combination of both melamine powder and TCP. The effect of these fire retardants on mechanical, thermal and fire retardant properties of semi flexible PU foam were evaluated based on density, resilience ball rebound, compressive strength, tensile strength, thermal stability, thermal conductivity, limiting oxygen index (LOI) and fire test. In addition, Cell morphology of PU foam was examined using scanning electron Microscope (SEM). LOI was improved from 19% to 26% with the addition of fire retardants. Cushioning property was retained however density was increased with the addition of fire retardants. 40% melamine powder and 40% TCP with respect to premix have been chosen as the optimized composition based on the fire resistant and physical properties. Scale up studies of the developed PU foam was done up to 1 m × 1 m size foam pad. With respect to the lab level properties, LOI value of 26% was retained and resilience ball rebound value change was found to be minimal.

Graphical Abstract

Keywords

semi flexible PU foam fire resistance melamine tricresyl phosphate scale up

Get full access to this article

View all access options for this article.

References

Gharehbaghi

Bashirzadeh

Ahmadi

. Polyurethane flexible foam fire resisting by melamine and expandable graphite: industrial approach. J Cell Plast 2011; 19: 0021955X11414789.

Konig

Fehrenbacher

Hirth

. Flexible polyurethane foam with the flame-retardant melamine. J Cell Plast 2008; 12: 469-480.

Wolska

Gozdzikiewicz

Ryszkowska

. Influence of graphite and wood-based fillers on the flammability of flexible polyurethane foams. Mater Sci 2012; 47: 5693–5700.

Akar

Değirmenci

Köken

. Fire-retardant and smoke-suppressant rigid polyurethane foam composites. Pigment Resin Technol 2023; 52: 237–245.

Degirmenci

Nesrin

Ahmet

, et al. Smoke suppressant and fire retardant polyurethane polyisocyanurate (PIR) foam. J Appl Polym Sci 2023; 140: e54372.

Ülkü

Köken

Akar

, et al. Tris (1-chloro-2-propyl) phosphate (TCPP) microcapsules for the preparation of flame-retardant rigid polyurethane foam. Polymer plastics technology and materials 2021; 60(5): 562–570.

Köken

Akşitb

Yilmaz

, et al. Nanofibers from chitosan/polyacrylonitrile/sepiolite nanocomposites. Polymer plastics technology and materials 2021; 60(16): 1820–1832.

Keskin

Köken

Akar

, et al. Copolymers and terpolymers of vinyl phosphonic acid, acrylonitrile, methyl acrylate, and vinyl acetate. Thermal oxidative stabilization and their nanofiber 175: 109142.

Akar

Kızılcan

Yivlik

, et al. Alendronic acid bearing ketone-formaldehyde resin and clay nanocomposites for fire-retardant polyurethanes. J Appl Polym Sci 2021; 138: e50829.

10.

Liu

Zhang

Luo

, et al. Multifunctional polyurethane sponge coatings with excellent flame retardant, antibacterial, compressible, and recyclable properties. Journal of composites.part B 2021; 215: 108785.

11.

yang

song

, et al. Surface-coating engineering for flame retardant flexible polyurethane foams: a critical review. Journal of composites.part B 2019; 176: 107185.

12.

Carl

Dennis

Fisher

, et al. Stable polyol-melamine blend for use in the manufacture of fire retardant flexible urethane foam. United states Patent, 1987, p. 4644015.

13.

Shin Kim

Jeon

. Analysis of mechanical and flame retardant properties of flexible polyurethane foams. J Appl Polym Sci 2023; 140: e54670.

14.

chan

Zhou

, et al. A liquid phosphorous flame retardant combined with expandable or melamine in flexible polyurethane foam. J Appl Polym Sci 2022; 33: 326-339.

15.

Camino

In: Pritchard

(ed). Dordrecht: Springer, 1998, 1, pp. 297–306.

16.

Lipins

M Pearce

. Chemistry and toxicity of flame retardants for plastics. EHP (Environ Health Perspect) 1976; 17: 55–63.

17.

Suparanon

Phetwarotai

. Fire-extinguishing characteristics and flame retardant mechanism of polylactide foams: influence of tricresyl phosphate combined with natural flame retardant. Int J Biol Macromol 2020; 158: 1090–1101.

18.

Yao

Yang

, et al. Phosphorus and nitrogen-containing polyols: synergistic effect on the thermal property and flame retardancy of rigid polyurethane foam composites. Journal of industrial & engineering chemistry research 2016; 10: 1021.

19.

Sabyasachi

Gang

Katherine

, et al. Effect of nitrogen additives on flame retardant action of tributyl phosphate: phosphorus-nitrogen synergism. Journal of Polymer Degradation and Stability 2008; 93: 99–108.

20.

Hindersinn . Flame retardancy of polymeric materials. : Marcel Dekkar, 1978, vol 4, p. p68.

21.

Lewin

. Synergism and catalysis in flame retardancy of polymers. Polym Adv Technol 2001; 12: 215–222.

22.

Ugartea

Saralegi b

Fernández a

, et al. Flexible polyurethane foams based on 100% renewably sourced polyols. Journal of Industrial crops and products 2014; 62: 545–551.

23.

Horrocks

Smart

Nazare

, et al. Quantification of zinc hydroxystannate and stannate synergies in halogen-containing flame-retardant polymeric formulations. J Fire Sci 2010; 28: 217–248.