Abstract
In this report, layer by layer (LBL) fire retardant coatings were produced on wood ply and Polypropylene Homopolymer/Flax fiber composites. FE-SEM and EDAX analysis was carried out to analyze the surface morphology, thickness, growth rate and elemental composition of the samples. Coatings with a high degree of uniformity were formed on Polypropylene composite (PP/flax), while coatings with highest thickness were obtained on wood ply (wood). FTIR and Raman spectroscopy were further used for the molecular identifications of the coatings, which confirmed the maximum deposition of the solution components on the wood substrate. A physiochemical analysis and model was proposed to explain the forces of adhesion between the substrate and solution molecules. Fire protection and thermal properties were studied using TGA and UL-94 tests. It was explored, that the degradation of the coated substrates was highly protected by the coatings as follows: wood > PP/flax > PP. From the UL-94 test, it was further discovered that more than 83% of the coated wood substrate was protected from burning, compared to the 0% of the uncoated substrate. The flammability resistance of the samples was ranked as wood > PP/flax > PP.
Highlights
Every year, around the globe, fire causes massive loss to human life and property
layer by layer (LBL) coatings were successfully deposited on wood ply, Polypropylene Homopolymer (PP) and Polypropylene Homopolymer/Flax fiber composite (PP/flax) substrates using CNF/VMT based polyelectrolyte solutions
Relatively uniform layers were formed on PP/flax; rough and thick coatings were observed on the wood substrates
Summary
Around the globe, fire causes massive loss to human life and property The reason behind such tragic losses is the increasing use of polymers-based products, wood and other highly flammable goods. Lai et al introduced another IFR, poly(-ethanediamine1,3,5- triazine-o-bicyclic pentaerythritol phosphate) (PETBP) and achieved high durability and thermal stability [8]. Precursors of these IFRs, such as cyanuric chloride [8,9] or phosphorus oxychloride [10,11] are highly reactive and toxic to the environment
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