Investigating the Effects of Temperature, Azodicarbonamide, Boron Nitride, and Multilayer Film/Foam Coextrusion on the Properties of a Poly(Hydroxyalkanoate)/Poly(Lactic acid) Blend

IF 4.7 3区 工程技术 Q2 ENGINEERING, ENVIRONMENTAL Journal of Polymers and the Environment Pub Date : 2024-08-22 DOI:10.1007/s10924-024-03310-9
Amy M. Yousefi, Gary E. Wnek, Hector Gomez Jimenez, Hossein Ghassemi, Jing Zhang
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Abstract

Poly(hydroxyalkanoates) (PHAs) are emerging as sustainable materials in packaging and medical device industries. Nevertheless, the high cost and the need to improve the mechanical properties have limited their widespread use. Blending with other bio-based polymers, such as poly(lactic acid) (PLA), has been proposed in previous studies. This study investigates the effects of temperature, azodicarbonamide (AZ, foaming agent), boron nitride (BN, filler), and multilayer film/foam coextrusion on the properties of a blend containing an amorphous PHA and PLA. The effect of twin-screw micro-compounder temperature (185 °C & 205 °C) and BN concentrations of 1, 2, 3, 5, and 10 wt% (185 °C) on the properties of the PHA/PLA blend were investigated using differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), and tensile testing. Design of experiments (DoE) was used to find the optimal concentrations of AZ and BN (205 °C) using JMP® software. The response surface analysis predicted an optimal design based on the target response levels (modulus, tensile strength, strain at break, and toughness). This formulation was prepared and characterized using DSC, TGA, tensile, and melt flow index (MFI) measurements. Finally, this formulation was processed via film/foam coextrusion and examined using scanning electron microscopy (SEM) and density measurements. This study demonstrated that AZ and BN can be used to manipulate the mechanical properties and crystallinity of PHA/PLA blends, while reducing the overall material cost via density reduction (20–21% for the optimal formulation). Furthermore, reducing the concentration of AZ using the I-optimal design in this study could alleviate the toxicity concerns for food packaging.

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研究温度、偶氮二甲酰胺、氮化硼和多层薄膜/泡沫共挤对聚(羟基烷酸)/聚(乳酸)混合物性能的影响
聚(羟基烷酸)(PHAs)是包装和医疗器械行业中新兴的可持续材料。然而,高昂的成本和改善机械性能的需要限制了它们的广泛应用。以前的研究曾提出过与其他生物基聚合物(如聚乳酸)共混的建议。本研究探讨了温度、偶氮二甲酰胺(AZ,发泡剂)、氮化硼(BN,填料)和多层薄膜/泡沫共挤对含有无定形 PHA 和聚乳酸的共混物性能的影响。使用差示扫描量热法(DSC)、热重分析法(TGA)和拉伸试验研究了双螺杆微型混炼机温度(185 ℃ & 205 ℃)和 1、2、3、5 和 10 wt% 的 BN 浓度(185 ℃)对 PHA/PLA 混合物性能的影响。使用 JMP® 软件进行了实验设计 (DoE),以找出 AZ 和 BN 的最佳浓度(205 °C)。响应面分析预测了基于目标响应水平(模量、拉伸强度、断裂应变和韧性)的最佳设计。制备了这种配方,并使用 DSC、TGA、拉伸和熔体流动指数 (MFI) 测量对其进行了表征。最后,通过薄膜/泡沫共挤工艺对该配方进行了加工,并使用扫描电子显微镜(SEM)和密度测定对其进行了检验。这项研究表明,AZ 和 BN 可用于调节 PHA/PLA 混合物的机械性能和结晶度,同时通过降低密度(最佳配方为 20-21%)来降低总体材料成本。此外,利用本研究中的 I-optimal 设计降低 AZ 的浓度可以减轻食品包装的毒性问题。
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来源期刊
Journal of Polymers and the Environment
Journal of Polymers and the Environment 工程技术-高分子科学
CiteScore
9.50
自引率
7.50%
发文量
297
审稿时长
9 months
期刊介绍: The Journal of Polymers and the Environment fills the need for an international forum in this diverse and rapidly expanding field. The journal serves a crucial role for the publication of information from a wide range of disciplines and is a central outlet for the publication of high-quality peer-reviewed original papers, review articles and short communications. The journal is intentionally interdisciplinary in regard to contributions and covers the following subjects - polymers, environmentally degradable polymers, and degradation pathways: biological, photochemical, oxidative and hydrolytic; new environmental materials: derived by chemical and biosynthetic routes; environmental blends and composites; developments in processing and reactive processing of environmental polymers; characterization of environmental materials: mechanical, physical, thermal, rheological, morphological, and others; recyclable polymers and plastics recycling environmental testing: in-laboratory simulations, outdoor exposures, and standardization of methodologies; environmental fate: end products and intermediates of biodegradation; microbiology and enzymology of polymer biodegradation; solid-waste management and public legislation specific to environmental polymers; and other related topics.
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