麻纤维增强聚乳酸生物复合材料的摩擦学性能:不同改性方法的影响

IF 3.1 Q2 MATERIALS SCIENCE, COMPOSITES Functional Composites and Structures Pub Date : 2023-02-27 DOI:10.1088/2631-6331/acbf9d
Nurhan Çevik Elen, Musa Yıldırım, Y. Kanbur
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引用次数: 1

摘要

在本研究中,用30% wt.%的大麻纤维增强聚乳酸(PLA)制备绿色复合材料,以提高其冲击和摩擦学性能。采用碱和硅烷、马来酸酐(MA)增容剂、热塑性聚氨酯(TPU)和聚丁二酸丁二烯共混物等不同的表面处理方法,改善纤维与基体的界面附着力。制备了大麻增强PLA生物复合材料,并对其硬度、冲击强度、磨损和摩擦性能进行了表征。根据ASTM G133标准,在两种不同的载荷(10牛顿和20牛顿)下进行了注射成型部件的摩擦学测试,作为干滑动线性往复运动。改性复合材料的摩擦学性能优于未改性复合材料。未经处理的纤维增强复合材料硬度值没有明显提高,但碱处理的复合材料硬度值提高了43%。总的来说,随着载荷的增加,所有复合材料的减重都有所增加。与纯PLA相比,未经改性的生物复合材料在10 N载荷下表现出非常低的失重和比磨损率(SWR)。与其他生物样品相比,MA生物复合材料在10 N和20 N负荷下的SWR均最低。TPU共混生物复合材料的冲击强度为22.96 kJ m−2,高于纯PLA (26.5 kJ m−2)。因此,由于对纤维进行表面处理和共混,一些复合材料的硬度和耐磨性有所提高,而冲击强度和摩擦系数有所降低。特别是硅烷表面处理和MA增容剂的应用提高了复合材料的耐磨性。扫描电镜图像显示,纤维与基体界面结合良好,纤维在基体中嵌入牢固。此外,在干滑动过程中,由表面的聚合物碎屑形成的保护薄膜层增加了生物复合材料的磨损性能。
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Tribological properties of hemp fiber reinforced polylactic acid bio-composites: effect of different types of modification methods
In this study, green composites are prepared with 30 wt.% hemp fibers reinforced polylactic acid (PLA) to enhance the impact and tribological properties. Different surface treatments of alkali and silane, compatibilizer of maleic anhydride (MA), and blends of thermoplastic polyurethane (TPU) and poly (butylene succinate) were applied to improve interfacial adhesion between fibers and matrix. Hemp-reinforced PLA bio-composites were fabricated and characterized by hardness, impact strength, wear, and friction properties. The tribological tests of the injection-molded components were performed under two different loads (10 N and 20 N) as dry-sliding linearly reciprocating motion per ASTM G133. Modified composites gave better tribological properties than unmodified composites. While no remarkable improvement was observed in the hardness value of untreated fiber-reinforced composite, alkali-treated composite reached up to 43% improvement in hardness value. In general, as the load increased, weight loss increase was observed in all composites. Unmodified bio-composite exhibited a very low weight loss and specific wear rate (SWR) compared to neat PLA under 10 N load. The SWR of the MA bio-composite had the lowest value for both loads (10 N and 20 N) compared to the other bio-samples. The TPU blended bio-composite exhibited the highest impact strength (22.96 kJ m−2) after pure PLA (26.5 kJ m−2). Therefore, due to surface treatments and blends applied to the fibers, some composites’ hardness and wear resistance were increased while the impact strength and friction coefficient was decreased. Especially silane surface treatment and MA compatibilizer application increased the wear resistance of composites. When the scanning electron microscope images were examined, it was revealed that the fiber and matrix interface bonding was good, and the fibers were firmly embedded in the matrix. Furthermore, forming a protective thin film layer formed by the polymer debris from the surface during dry-sliding increased the wear performance of the bio-composites.
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来源期刊
Functional Composites and Structures
Functional Composites and Structures Materials Science-Materials Science (miscellaneous)
CiteScore
4.80
自引率
10.70%
发文量
33
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