Development of biocomposites using cardanol oil bio-toughener, palm kernel fiber and chitosan derived from discarded biomass wastes: a characterization study with aging conditions

IF 3.1 3区 化学 Q2 POLYMER SCIENCE Polymer Bulletin Pub Date : 2024-07-29 DOI:10.1007/s00289-024-05418-3
J. Thamilarasan, R. Ganesamoorthy
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Abstract

This study focuses on the creation of high degree biocomposite with the utilization of renewable resources, including cardanol oil, palm kernel fiber and chitosan biopolymer. The principal aim of this research was to achieve high degree ratio of biocomposite for safe and eco-friendly application. The chitosan biopolymer was extracted from marine waste sea urchin spikes via deproteination. The biocomposites were prepared via hand layup technique following testing via ASTM standards. According to results, among the composites fabricated, PC5 exhibits exceptional mechanical strength with tensile strength of 88.2 MPa, flexural strength of 133.35 MPa and impact energy of 3.92 J. Therefore, PC6 composite performs better wear resistance with reduced coefficient of friction of 0.399 and Sp. wear rate of 0.01 mm3/Nm, respectively. And also, PC6 provides good thermal resistance with initial decomposition temperature of 345 °C. Similar to mechanical properties, in fatigue behavior also PC5 exhibits high fatigue life cycle counts with 19,647 for 25% UTS, 18,799 for 50% UTS and 17,571 for 75% UTS. The obtained results show that the inclusion of palm kernel fiber and chitosan significantly enhances the mechanical properties, wear and thermal resistance of the composites, while the cardinal oil binder ensures proper adhesion. However, thermal aging conditions were implemented to assess the material’s ability to withstand harsh environmental factors. Notably, among the composite materials tested, the designations with chitin (such as PC4, PC5, and PC6) exhibited lesser susceptibility to the effects of thermal aging. This resilience is attributed to the presence of NH2 functional groups within chitin, which play a role in reducing the impact of thermal aging. These discoveries highlight the promising qualities of the developed polyester biocomposites, suggesting their suitability for a wide array of industrial applications requiring materials capable of enduring high-temperature environments such as automotive door panels, structural, space, defense and sports applications.

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利用从废弃生物质废料中提取的万丹醇油生物增韧剂、棕榈仁纤维和壳聚糖开发生物复合材料:老化条件下的表征研究
本研究的重点是利用可再生资源(包括硬脂醇油、棕榈仁纤维和壳聚糖生物聚合物)制造高比例生物复合材料。这项研究的主要目的是实现高比例生物复合材料的安全和环保应用。壳聚糖生物聚合物是从海洋废弃物海胆钉中通过脱蛋白提取的。根据 ASTM 标准进行测试后,通过手糊技术制备了生物复合材料。因此,PC6 复合材料具有更好的耐磨性,摩擦系数降低至 0.399,磨损率降低至 0.01 mm3/Nm。此外,PC6 还具有良好的耐热性,其初始分解温度为 345 ℃。与机械性能类似,在疲劳行为方面,PC5 也表现出较高的疲劳寿命循环次数,25% UTS 为 19,647 次,50% UTS 为 18,799 次,75% UTS 为 17,571 次。结果表明,加入棕榈仁纤维和壳聚糖可显著提高复合材料的机械性能、耐磨性和耐热性,而红心油粘合剂可确保适当的粘合性。不过,为了评估材料抵御恶劣环境因素的能力,还采用了热老化条件。值得注意的是,在测试的复合材料中,含有甲壳素的材料(如 PC4、PC5 和 PC6)对热老化影响的敏感性较低。这种韧性归因于甲壳素中 NH2 官能团的存在,而 NH2 官能团在降低热老化影响方面发挥了作用。这些发现凸显了所开发的聚酯生物复合材料的良好品质,表明它们适用于要求材料能够承受高温环境的各种工业应用,如汽车门板、结构、太空、国防和体育应用。
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来源期刊
Polymer Bulletin
Polymer Bulletin 化学-高分子科学
CiteScore
6.00
自引率
6.20%
发文量
0
审稿时长
5.5 months
期刊介绍: "Polymer Bulletin" is a comprehensive academic journal on polymer science founded in 1988. It was founded under the initiative of the late Mr. Wang Baoren, a famous Chinese chemist and educator. This journal is co-sponsored by the Chinese Chemical Society, the Institute of Chemistry, and the Chinese Academy of Sciences and is supervised by the China Association for Science and Technology. It is a core journal and is publicly distributed at home and abroad. "Polymer Bulletin" is a monthly magazine with multiple columns, including a project application guide, outlook, review, research papers, highlight reviews, polymer education and teaching, information sharing, interviews, polymer science popularization, etc. The journal is included in the CSCD Chinese Science Citation Database. It serves as the source journal for Chinese scientific and technological paper statistics and the source journal of Peking University's "Overview of Chinese Core Journals."
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