Hygroscopic analysis and tribo-mechanical characterization of biocompatible PP/PA6/Boron sesquioxide composite

K. S. Randhawa
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Abstract

Purpose The purpose of this study is to look into the hygroscopic and tribo-mechanical properties of a polypropylene/polyamide-6 (PP/PA6) blend and a PP/PA6/Boron sesquioxide composite. Design/methodology/approach The hygroscopic behaviour of the PP/PA6 blend and PP/PA6/Boron sesquioxide composite was studied using a water contact angle goniometer in this study. To validate the hygroscopic behaviour of the blend and composite, water contact angles and surface energy of the materials were investigated. Tensile strength and hardness tests were used to determine mechanical characteristics, and tribological experiments on a pin-on-disc tribometer were used to demonstrate the friction and wear rates of dry and water-conditioned blends and composites. The melting temperature of dry and water-conditioned composites was determined using DSC analysis. Findings The hygroscopic effect of the PP/PA6 blend was found to be minimal in the experiment, while it was relatively dominating in the PP/PA6/Boron sesquioxide composite. Tensile strength was found to be somewhat lower in blend and composite compared to virgin PP, whereas hardness was found to be higher in both blend and composite. The composite’s tribological testing findings were fairly outstanding, with the coefficient of friction (COF) and wear rates significantly reduced due to boron sesquioxide reinforcement. The reaction between boron sesquioxide and water molecules produced boric acid, which increased the tribological characteristics of the composite even further. Following 30 days of water conditioning, the weight of the blend increased by 3.64% and the weight of the composite increased by 6.45% as compared to the dry materials. After water conditioning, tensile strength reduced by 0.8% for the blend and 14.16% for the composite. Hardness was determined to be the same in the dry state and after water-conditioning for blend but dropped 1% for composite. As compared to blend, the COF and wear resistance of composite were 15.52% and 25.16% higher, respectively. After absorbing some water, the results increased to 28.57% and 34.9%, respectively. Originality/value The mechanical and thermal behaviour of polymer composites (particularly polyamide composites) vary depending on the surrounding environment. Tests were carried out to explore the effect of water treatment on the tribo-mechanical and thermal characteristics of PP/PA6/Boron sesquioxide composite. Water treatment caused polyamides to bind with water molecules, resulting in voids in the material. The interaction between boron sesquioxide and water molecules produced boric acid, which increased the tribological characteristics of the composite.
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生物相容性PP/PA6/倍半氧化硼复合材料的吸湿分析及摩擦力学特性
目的研究聚丙烯/聚酰胺-6 (PP/PA6)共混物和PP/PA6/倍半氧化硼复合材料的吸湿性能和摩擦力学性能。设计/方法/方法本研究采用水接触角计研究了PP/PA6共混物和PP/PA6/倍半氧化硼复合材料的吸湿性能。为了验证共混和复合材料的吸湿性能,研究了材料的水接触角和表面能。拉伸强度和硬度测试用于确定机械特性,在销盘式摩擦计上进行摩擦学实验,以证明干燥和水条件下的共混物和复合材料的摩擦和磨损率。采用DSC分析确定了干燥和水态复合材料的熔融温度。实验发现PP/PA6共混物的吸湿效果最小,而PP/PA6/倍半氧化硼的吸湿效果相对占主导地位。与原始PP相比,共混和复合的拉伸强度略低,而硬度则较高。该复合材料的摩擦学测试结果相当出色,由于倍半氧化硼的增强,摩擦系数(COF)和磨损率显著降低。倍半氧化硼和水分子之间的反应产生硼酸,进一步提高了复合材料的摩擦学特性。经过30 d的水处理后,与干燥材料相比,共混物的重量增加了3.64%,复合材料的重量增加了6.45%。经水处理后,共混物的抗拉强度降低0.8%,复合材料的抗拉强度降低14.16%。经测定,共混物的硬度与水处理后的硬度相同,而复合物的硬度下降1%。与共混材料相比,复合材料的COF和耐磨性分别提高了15.52%和25.16%。在吸收一定水分后,结果分别提高到28.57%和34.9%。原创性/价值聚合物复合材料(特别是聚酰胺复合材料)的机械和热性能取决于周围环境。研究了水处理对PP/PA6/倍半氧化硼复合材料摩擦力学性能和热性能的影响。水处理导致聚酰胺与水分子结合,从而在材料中产生空隙。倍半氧化硼与水分子相互作用产生硼酸,提高了复合材料的摩擦学性能。
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