Compressive behavior of Co-Cr-Mo radially graded porous structures under as-built and heat-treated conditions

IF 1.2 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Frattura ed Integrita Strutturale Pub Date : 2022-09-22 DOI:10.3221/igf-esis.62.33

F. Cantaboni, P. Ginestra, M. Tocci, A. Avanzini, E. Ceretti, A. Pola

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引用次数: 1

Abstract

Additive manufacturing research is continuously growing, and this field requires a full improvement of the capability and reliability of the processes involved. Of particular interest is the study of complex geometries production, such as lattice structures, which may have a potentially huge field of application, especially for biomedical products. In this work, the powder bed fusion technique was utilized to manufacture lattice structures with defined building angles concerning the build platform. A biocompatible Co-Cr-Mo alloy was used. Three different types of elementary cell geometry were selected: Face Centered Cubic, Diagonal, and Diamond. These cells were applied to the radially oriented lattice structures to evaluate the influence of their orientation in relation to the sample and the build platform. Moreover, heat treatment was carried out to study its influence on microstructural properties and mechanical behavior. Microhardness was measured, and compressive tests were performed to detect load response and to analyse the fracture mechanisms of these structures. The results show that the mechanical properties are highly influenced by the cell orientation in relation to the building direction and that the properties can be further tuned via HT. The favorable combination of mechanical properties and biocompatibility suggests that Co-Cr-Mo lattices may represent an optimal solution to produce customized metal implants.

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Co-Cr-Mo径向梯度多孔结构在施工和热处理条件下的压缩行为

增材制造研究正在不断发展，这一领域需要全面提高相关工艺的能力和可靠性。特别令人感兴趣的是对复杂几何形状生产的研究，如晶格结构，这可能具有潜在的巨大应用领域，尤其是对生物医学产品。在这项工作中，利用粉末床融合技术制造了与构建平台相关的具有定义构建角度的晶格结构。使用了具有生物相容性的Co-Cr-Mo合金。选择了三种不同类型的基本单元几何体：面心立方体、对角线和菱形。将这些单元应用于径向取向的晶格结构，以评估它们相对于样品和构建平台的取向的影响。此外，还进行了热处理，以研究其对微观结构性能和力学行为的影响。测量了显微硬度，并进行了压缩试验，以检测载荷响应并分析这些结构的断裂机制。结果表明，与构建方向相关的细胞取向对力学性能有很大影响，并且可以通过HT进一步调节力学性能。力学性能和生物相容性的良好结合表明，Co-Cr-Mo晶格可能是生产定制金属植入物的最佳解决方案。

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