Tribological performance analysis of sustainable basalt micro-filler loaded bio-based polypropylene and high density polyethylene composites

IF 3.6 4区 材料科学 Q2 MATERIALS SCIENCE, COMPOSITES Journal of Thermoplastic Composite Materials Pub Date : 2024-01-29 DOI:10.1177/08927057231223478
Praveenkumara Jagadeesh, Sanjay Mavinkere Rangappa, Suchart Siengchin
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Abstract

The current research work involves the fabrication and tribological properties analysis of constant basalt filler reinforced (30 wt %) bio-based polypropylene (PP) and high density polyethylene (HDPE) thermoplastic composites. Compression molding technique is used after an internal mixing process in order to produce composite samples. The physical and hardness properties have been evaluated for both neat polymers and composite samples. In order to study the coefficient of friction (COF) and specific wear rate (SWR) of PP and HDPE composite samples, the Taguchi and Analysis of Variance (ANOVA) methodologies were applied. For PP samples, the optimum parameters in response to COF are found to be 0 wt% basalt (rank 3), 9 N load (rank 1), 200 r/min speed (rank 4), and 100 m distance (rank 2); for the SWR output, the optimum parameters are 30 wt% basalt (rank 1), 6 N load (rank 4), 100 r/min speed (rank 2), and 200 m distance (rank 3). For HDPE samples, the optimum parameters in response to COF are 0 wt% basalt (rank 1), 6 N load (rank 3), 100 r/min speed (rank 4), and 100 m distance (rank 2); for the SWR output, the optimum parameters are 30 wt% basalt (rank 1), 6 N load (rank 3), 100 r/min speed (rank 4), and 150 m distance (rank 2). Consistently, it has been shown that incorporating basalt fillers to PP and HDPE composites has more dramatically decreased SWR than COF. The depth of wear constantly rises according to increasing load, irrespective of the processing variables, as shown in 2D depth profiles. It is discovered that the confirmation tests carried out for the optimum parameters are within statistically acceptable bounds. The depth profile plots revealed that the worn track edges are found with polymer bumps because of deep grooves and softened polymer debris, which commonly observed more with HDPE samples due to low softening temperature. Moreover, the worn surfaces of the composites have plowed lines and cracks that are brought about by the micro-cutting and micro-plowing activity of the erosive asperities counterface. In addition to surface characteristics, the transfer films created during sliding also significantly influenced the mode of sample wear.
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负载生物基聚丙烯和高密度聚乙烯复合材料的可持续玄武岩微填料的摩擦学性能分析
目前的研究工作涉及恒定玄武岩填料增强(30 wt %)生物基聚丙烯(PP)和高密度聚乙烯(HDPE)热塑性复合材料的制造和摩擦学特性分析。在经过内部混合过程后,采用压缩成型技术生产复合材料样品。对纯净聚合物和复合材料样品的物理和硬度特性进行了评估。为了研究聚丙烯和高密度聚乙烯复合材料样品的摩擦系数(COF)和特定磨损率(SWR),采用了田口方法和方差分析(ANOVA)方法。对于聚丙烯样品,COF 的最佳参数为 0 wt%的玄武岩(排序 3)、9 N 的负载(排序 1)、200 r/min 的速度(排序 4)和 100 m 的距离(排序 2);对于 SWR 输出,最佳参数为 30 wt%的玄武岩(排序 1)、6 N 的负载(排序 4)、100 r/min 的速度(排序 2)和 200 m 的距离(排序 3)。对于高密度聚乙烯样品,响应 COF 的最佳参数为 0 wt%的玄武岩(排名 1)、6 N 的负载(排名 3)、100 r/min 的速度(排名 4)和 100 m 的距离(排名 2);对于 SWR 输出,最佳参数为 30 wt%的玄武岩(排名 1)、6 N 的负载(排名 3)、100 r/min 的速度(排名 4)和 150 m 的距离(排名 2)。一致表明,在 PP 和 HDPE 复合材料中加入玄武岩填料比 COF 更能显著降低 SWR。如二维磨损深度剖面图所示,无论加工变量如何,磨损深度随着载荷的增加而不断增加。我们发现,对最佳参数进行的确认测试在统计学上可接受的范围内。深度剖面图显示,由于凹槽较深和聚合物碎片软化,磨损的轨道边缘会出现聚合物凸起,而高密度聚乙烯样品由于软化温度较低,通常会出现这种情况。此外,复合材料的磨损表面还出现了犁纹和裂纹,这是由侵蚀性反面的微切割和微犁活动造成的。除表面特征外,滑动过程中产生的转移膜也对样品的磨损模式产生了重大影响。
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来源期刊
Journal of Thermoplastic Composite Materials
Journal of Thermoplastic Composite Materials 工程技术-材料科学:复合
CiteScore
8.00
自引率
18.20%
发文量
104
审稿时长
5.9 months
期刊介绍: The Journal of Thermoplastic Composite Materials is a fully peer-reviewed international journal that publishes original research and review articles on polymers, nanocomposites, and particulate-, discontinuous-, and continuous-fiber-reinforced materials in the areas of processing, materials science, mechanics, durability, design, non destructive evaluation and manufacturing science. This journal is a member of the Committee on Publication Ethics (COPE).
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