Soil Burial, Hygrothermal and Morphology of Durian Skin Fiber Filled Polylactic Acid Biocomposites

M. Pang, Yesudian Aaron, S. Koay, J. H. Low, H. Choo, K. Tshai
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引用次数: 4

Abstract

INTRODUCTION Durian husk or skin is the waste product after the consumption of the durian fruit, which is known by local as the “King of fruits” [1]. The disposal of durian husk especially in landfill has caused various environmental issues such as soil contamination and disease spreading. The utilization of the natural fiber obtained from durian husk is seen as a potential solution to reduce the waste disposal and to diversify the usage of agricultural waste. The natural fiber is more eco-friendly and is seen as a suitable replacement for synthetic fiber. The natural fiber is lightweight, non-abrasive, renewability and biodegradability, which found applications in many fields ranging from a consumer product to the automotive industry. The examples of natural fibers are fruit fibers, wood, silk, ramie, jute, hemp, kenaf, sisal, coir, flax and bamboo [2]. The natural fiber obtained from agricultural waste such as durian skin fiber (DSF) is inexpensive and can be used as a reinforcement agent in a polymer matrix to form biocomposite. Biocomposite can be referred to a multi-phase material in which reinforcement fillers are added and integrated into a polymer matrix, resulting in synergistic properties that cannot be achieved from either component alone [3]. Polylactic acid (PLA) is one of the most common biopolymers which is derived from a renewable resource. PLA has attracted much attention due to its advantages such as high strength, high modulus, compostable and regarded as a safe material for food packaging application [4]. However, the disadvantages of the PLA are having low thermal stability and low elongation property. Previous works have been carried out to improve the performance of the PLA by adding reinforcement agent or filler to form biocomposites. Sun et al. [5] reported the good interfacial adhesion between the PLA and treated coir fiber was attributed to the pretreatment of fiber, which led to the improvement in tensile modulus and impact strength. According to Koay et al. [6], the addition of untreated DSF increased the tensile strength and modulus of the recycled polystyrene foam/DSF composites but decreased the elongation at break. The good interfacial adhesion between the natural fibers and the matrix is important for the superior properties, and this can be achieved via physical or chemical methods. Physical methods include plasma and heat treatment of natural fiber. Meanwhile, chemical methods include alkaline treatment, acetylation and the use of coupling agent [7]. In this study, DSF was obtained from durian husk and treated with an alkaline solution (sodium hydroxide) to remove lignin, hemicellulose, wax, and oil covering the external surface of the fiber cell wall [8]. The chemical composition of the DSF was Abstract
榴莲皮纤维填充聚乳酸生物复合材料的土壤埋藏、湿热及形态研究
榴莲果皮是榴莲果实食用后的废弃物,被当地人称为“水果之王”[1]。榴莲皮的处理,尤其是垃圾填埋,造成了土壤污染和病害传播等环境问题。利用从榴莲壳中获得的天然纤维被认为是减少废物处理和使农业废物利用多样化的潜在解决方案。天然纤维更环保,被认为是合成纤维的合适替代品。这种天然纤维重量轻、不磨蚀、可再生、可生物降解,在从消费品到汽车工业的许多领域都有应用。天然纤维的例子有水果纤维、木材、丝绸、苎麻、黄麻、大麻、红麻、剑麻、椰子、亚麻和竹子[2]。从农业废弃物中获得的天然纤维,如榴莲皮纤维(DSF)价格低廉,可作为增强剂在聚合物基质中形成生物复合材料。生物复合材料是指一种多相材料,在其中添加增强填料并将其整合到聚合物基体中,从而产生任何一种组分都无法单独实现的协同性能[3]。聚乳酸(PLA)是一种从可再生资源中提取的最常见的生物聚合物之一。PLA因其高强度、高模量、可堆肥等优点而备受关注,被认为是一种安全的食品包装材料[4]。然而,PLA的缺点是具有低热稳定性和低延伸性能。以往的研究都是通过添加增强剂或填充剂来形成生物复合材料来提高PLA的性能。Sun等[5]报道了PLA与处理后的椰胶纤维之间良好的界面粘附性,这是由于纤维的预处理导致拉伸模量和冲击强度的提高。Koay等[6]的研究表明,未经处理的DSF的加入提高了再生聚苯乙烯泡沫/DSF复合材料的抗拉强度和模量,但降低了断裂伸长率。天然纤维与基体之间良好的界面附着力是获得优异性能的重要因素,这可以通过物理或化学方法来实现。物理方法包括等离子体和天然纤维的热处理。化学方法包括碱处理、乙酰化和偶联剂的使用[7]。本研究从榴莲壳中提取DSF,用碱性溶液(氢氧化钠)处理,去除覆盖在纤维细胞壁外表面的木质素、半纤维素、蜡和油[8]。DSF的化学成分为Abstract
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