Abstract
Some crop by-products are considered to be promising materials for the development of novel biobased products for industrial applications. The flammability of these alternatives to conventional materials is a constraint to expanded applications. Polylactide (PLA) composites containing a combination of oxidized corn pith fiber (OCC) and a biobased flame retardant (PA-THAM) have been prepared via an in situ modification method. SEM/EDS, FTIR and TGA were performed to establish that PA-THAM was coated onto the surface of OCC. The mechanical properties, thermal stability and fire behavior of PLA-based biocomposites were investigated. The incorporation of 5 phr PA-THAM imparted biocomposite good interfacial adhesion and increased decomposition temperature at 10% mass loss by 50 °C. The flame retardant properties were also improved, as reflected by an increased LOI value, a UL-94 V-2 rating, reduction of PHRR, and increased formation of char residue. Therefore, the introduction of 5 phr PA-THAM can maintain a good balance between flame retardancy and mechanical properties of this PLA/OCC system.
Highlights
The peak width at half height of the biocomposites, which is for hinting interaction between components in the multiphase system, increased with the considered as a criterion for hinting interaction between components in the multiphase system, increased with the content of phytic acid (PA)-THAM [37]
In order to analyze the significant improvement in thermal stability, TGA/FTIR was carried out to investigate the evolution of volatile products during thermal degradation process of PLA-based biocomposites
A biobased flame retardant (PA-THAM) was successfully coated onto the surface of oxidized corn pith fiber (OCC) via in situ modification. This modified OCC was introduced to PLA to prepare natural fiber reinforced plastic composites (NPCs)
Summary
Environmental and sustainable awareness is stimulating the development of novel eco-friendly materials, which possess acceptable properties, biodegradability, low density and low cost [1]. Among these alternatives, natural fiber reinforced plastic composites (NPCs) are finding increasing acceptance and demand for structural applications [2,3,4]. A natural fiber/PLA system containing a phosphorus flame retardant, which has a metal–organic framework (MOF) structure, shows a 43% reduction in smoke production after combustion and improvement in tensile and impact strength compared to the same properties for pure
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