Effect of Fast Axial Flow CO2 Laser Processing Parameters on Graphene/AlxCoCrNiTi High Entropy Alloy

Pub Date : 2023-08-29 DOI:10.1007/s10946-023-10154-6
Xingwu Qiu
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Abstract

The energy distribution characteristics of fast axial flow CO2 lasers demonstrate that they are often used for cutting and welding metal materials, and it is generally believed that they are not suitable for material heat treatment. In order to expand the application range of these lasers, we prepare graphene (Gr) reinforced high entropy alloy (HEA) coatings, employing this type of laser under loworder mode conditions by adjusting processing parameters and cladding powder composition through orthogonal experiments. Then we study the effect of laser processing parameters on Gr/AlxCoCrNiTi composite coatings. The research results indicate that the optimum process parameters are as follows: the laser power P = 3200 W, the scanning speed V = 14 mm/s, the cladding powder thickness d = 1.2 mm, and the spot diameter D = 4.0 mm. We find that, under the optimum process parameters, the Gr/AlxCoCrNiTi laser cladding coatings exhibit typical dendrites and equiaxed grains. The microstructure refines with increase in the Al content. The Gr/AlxCoCrNiTi laser cladding coating mainly consists of the face centered cubic (FCC), body centered cubic (BCC), and M23C6. Increase in the Al content promotes the formation of the BCC structure. The microhardness of Gr/AlxCoCrNiTi composite coatings range from 550 to 725 HV. The hardness is related to the solid solution strengthening caused by Gr and Al. With increase in the Al content, the microhardness of the coating shows a trend to increase, the wear resistance first increases and then decreases. The wear resistance is related to the BCC content and cracks in the coating. Orthogonal experiments and coating performance indicate that, by adjusting laser processing parameters and alloy composition, it is possible for fast axial flow CO2 lasers to prepare Gr/AlxCoCrNiTi composite coatings under low-order mode conditions, which can expand the applicability of these lasers.

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快速轴流CO2激光加工参数对石墨烯/AlxCoCrNiTi高熵合金的影响
快速轴流CO2激光器的能量分布特性表明,它常用于金属材料的切割和焊接,一般认为它不适合材料热处理。为了扩大这类激光器的应用范围,我们通过正交实验调整工艺参数和熔覆粉末成分,制备了石墨烯(Gr)增强高熵合金(HEA)涂层,并在低模条件下使用该类型的激光器。然后研究了激光加工参数对Gr/AlxCoCrNiTi复合镀层的影响。研究结果表明,最佳工艺参数为:激光功率P = 3200 W,扫描速度V = 14 mm/s,熔覆粉末厚度d = 1.2 mm,光斑直径d = 4.0 mm。结果表明,在最佳工艺参数下,Gr/AlxCoCrNiTi激光熔覆层呈现出典型的枝晶和等轴晶粒。随着Al含量的增加,组织细化。Gr/AlxCoCrNiTi激光熔覆层主要由面心立方层(FCC)、体心立方层(BCC)和M23C6组成。Al含量的增加促进了BCC结构的形成。Gr/AlxCoCrNiTi复合镀层显微硬度为550 ~ 725 HV。硬度与Gr和Al引起的固溶强化有关,随着Al含量的增加,涂层显微硬度呈增加趋势,耐磨性先增加后降低。涂层的耐磨性与BCC含量和裂纹有关。正交实验和涂层性能表明,通过调整激光加工参数和合金成分,可以在低阶模态条件下用快速轴流CO2激光器制备Gr/AlxCoCrNiTi复合涂层,扩大了此类激光器的适用性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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