Study the effect of Nano Zro2 and Tio2 and rotation speed on friction behavior of rotary friction welding of HIPS and P.P

IF 3.1 Q2 MATERIALS SCIENCE, COMPOSITES Functional Composites and Structures Pub Date : 2021-12-06 DOI:10.1088/2631-6331/ac407d
M. Afzali, V. Asghari
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引用次数: 1

Abstract

the purpose of this project was to introduce a way to improve the mechanical properties of welded dissimilar material, which gives benefits such as affordable, high speed, and suitable bond property. In this experimental project, the friction welding method has been applied, including combining parameters, such as numerical control (NC) machine including two different speeds, and three different cross-sections; including flat, cone, and step surfaces. When the welding process was done, samples were implemented and prepared via bending test of materials. the results have shown that, besides increasing the machining velocity, the surface friction increased, and so did the temperature. By considering the stated experimental facts, the melting temperature of composite materials has increased. This provides the possibility of having a better blend of nanomaterial compared to the base melted plastics. Thus, the result showed that, besides increasing the weight percentage (wt %) of Nanomaterials contents and machining velocity, the mechanical properties have increased on the welded area for all three types of samples. This enhancement is due to the better melting process on the welded area with attendance of various Nanoparticles contents. Also, the results showed that the shape of the welding area could play a significant role, and the results also change drastically where the shape changes. Optimum shape in the welding process has been dedicated to the step surface. The temperature causes the melting process, which is a significant factor in the friction welding process.
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研究纳米Zro2、Tio2和转速对HIPS和pp旋转摩擦焊摩擦行为的影响
该项目旨在介绍一种改善焊接异种材料力学性能的方法,该方法具有价格合理、速度快、粘结性能好等优点。在这个实验项目中,应用了摩擦焊接方法,包括组合参数,如数控机床,包括两种不同的速度和三种不同的横截面;包括平面、锥形和台阶表面。焊接过程完成后,通过材料的弯曲试验来实施和制备样品。结果表明,除了提高加工速度外,表面摩擦增加,温度也增加。通过考虑上述实验事实,复合材料的熔化温度有所提高。这提供了与基底熔融塑料相比具有更好的纳米材料共混物的可能性。因此,结果表明,除了提高纳米材料含量的重量百分比(wt%)和加工速度外,所有三种类型的样品的焊接区域的机械性能都有所提高。这种增强是由于焊接区域有更好的熔化过程,并且有各种纳米颗粒含量。此外,结果表明,焊接区域的形状可以发挥重要作用,并且在形状变化的地方,结果也会发生剧烈变化。焊接过程中的最佳形状已专门用于台阶表面。温度导致熔化过程,这是摩擦焊接过程中的一个重要因素。
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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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