Synthesis of starch-derived biopolymer reinforced Enset fiber green composite packaging films: Processes and properties optimization

Elizabeth Mekonnen Feyissa, Adane Dagnaw Gudayu
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Abstract

The use and disposal of traditional fiber-reinforced polymer composites is an important environmental challenge as one of the factors contributing to worsening climate change. The primary objective of this research is to synthesize thermoplastic starch (TPS) from edible banana skins which can potentially be used as a matrix to produce bio-composite films. For the synthesis of TPS, the preparation of banana peels was performed followed by plasticization to obtain the banana peels TPS. For bio-composite film fabrication, the TPS was mixed with short false banana fibers (FBF) (10–30% by weight of the film) with an electronic blender to form a uniform dispersion of the fibers in the TPS. The FBF/TPS blend was applied uniformly on the surface of the rectangular metal mold. The autoclave method has been adopted for curing and molding the bio-composite film. Then, it was hot pressed varying the temperature and pressure from 131–141 OC to 3–6 MPa, respectively, to obtain the final cured film. The specimen was then solidified or hardened at ambient temperature. Finally, optimization of process parameters, fiber content, and their interaction effects on the tear strength, tensile strength, and bending modulus of the bio composite films were conducted using response surface methodology. The results indicate that both the effects of one factor and the interaction of factors have a significant effect on the mechanical properties of composite films. The optimum processing parameters for TPS production are a temperature of 50 OC and a drying time of 24 h. The optimal result indicates that, at 30% fiber loading, the optimum processing temperature and pressure are 135.14°C and 4.33 MPa, respectively, resulting in a composite film with good mechanical properties.
淀粉基生物聚合物增强Enset纤维绿色复合包装薄膜的合成:工艺与性能优化
传统纤维增强聚合物复合材料的使用和处置是一个重要的环境挑战,是导致气候变化恶化的因素之一。本研究的主要目的是利用可食用香蕉皮合成热塑性淀粉(TPS),该淀粉有可能用作制备生物复合薄膜的基质。为了合成TPS,首先制备香蕉皮,然后进行塑化,得到香蕉皮TPS。为了制备生物复合薄膜,将TPS与短假香蕉纤维(FBF)(薄膜重量的10-30%)用电子搅拌器混合,使纤维在TPS中均匀分散。将FBF/TPS共混物均匀地涂在矩形金属模具表面。采用高压灭菌法对生物复合材料薄膜进行固化和成型。然后,将温度和压力分别在131 ~ 141℃至3 ~ 6 MPa之间进行热压,得到最终固化膜。然后将试样在室温下固化或硬化。最后,利用响应面法对工艺参数、纤维含量及其对生物复合膜撕裂强度、拉伸强度和弯曲模量的影响进行了优化。结果表明,单个因素的作用和多个因素的相互作用对复合薄膜的力学性能都有显著影响。制备TPS的最佳工艺参数为温度为50℃,干燥时间为24 h。优化结果表明,在纤维负荷为30%时,最佳工艺温度为135.14℃,最佳工艺压力为4.33 MPa,可制备出具有良好力学性能的复合膜。
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