The effect of interfacial alloy formation on the mechanical properties of the additively manufactured Ti6Al4V/Ti1Al8V5Fe microstructurally graded material
IF 6.1 2区 材料科学Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Alexander E. Medvedev, Shenglu Lu, Ma Qian, Milan Brandt
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引用次数: 0
Abstract
Multi-material (MM) structures have been shown in the past to be potential candidates for future high performance high strain rate applications. With the advancement of MM additive manufacturing (AM), there is a renewed push to explore the vast array of materials combinations to deliver advanced protective capabilities. At the same time, many fundamental issues are still plaguing MM assemblies, primarily linked to the often-poor quality of the MM interface. Here, we present a novel approach to obtain microstructural and mechanical properties gradient without interface defects by leveraging the link between the chemical composition and complex grain/phase morphology in titanium alloys. We used additive manufacturing (AM) to combine α+β-titanium alloy Ti6Al4V with metastable β-titanium alloy Ti1Al8V5Fe (which belong to different alloy classes but share common alloying elements), into a microstructurally graded material (MGM). Uniquely, the classic MM interface was replaced by the two additional intermixed alloy layers with unique chemical composition, microstructure and mechanical properties, with both ultimately making a significant contribution to the overall performance. The properties of these interface alloys are affected by many factors, such as thermal properties of the substrate, process parameters, alloying element distribution and post-manufacturing heat treatment. As a result, we showed that a superior combination of the strength and ductility could be achieved in the hybrid material after heat treatment compared to the original materials or the as-built hybrid material, which was ultimately attributed to the formation of the interface alloys. The presented approach is not limited to titanium alloys and could be extended to other materials systems and is expected to contribute to the development of a deeper understanding of the intermixing phenomena and its effects on microstructure and mechanical performance of MGMs, opening the door to a range of unique solutions in alloy and MM structural design for high performance applications.
过去的研究表明,多材料(MM)结构是未来高性能、高应变率应用的潜在候选材料。随着多材料增材制造(AM)技术的发展,人们再次推动探索各种材料组合,以提供先进的保护能力。与此同时,许多基本问题仍然困扰着 MM 组件,这主要与 MM 接口质量不佳有关。在此,我们提出了一种新方法,利用钛合金中化学成分与复杂晶粒/相形态之间的联系,获得无界面缺陷的微结构和机械性能梯度。我们利用增材制造(AM)技术将α+β-钛合金 Ti6Al4V 与易变β-钛合金 Ti1Al8V5Fe(它们属于不同的合金类别,但具有共同的合金元素)结合成微结构梯度材料(MGM)。与众不同的是,传统的 MGM 界面被另外两个具有独特化学成分、微观结构和机械性能的混合合金层所取代,这两个合金层最终都对整体性能做出了重大贡献。这些界面合金的性能受到许多因素的影响,如基体的热性能、工艺参数、合金元素分布和制造后的热处理。结果表明,与原始材料或制造后的混合材料相比,热处理后的混合材料可以获得更高的强度和延展性组合,这最终归功于界面合金的形成。所介绍的方法并不局限于钛合金,还可扩展到其他材料体系,预计将有助于加深对混杂现象及其对 MGM 微观结构和机械性能影响的理解,为高性能应用领域的合金和 MM 结构设计提供一系列独特的解决方案。
期刊介绍:
Materials Science and Engineering A provides an international medium for the publication of theoretical and experimental studies related to the load-bearing capacity of materials as influenced by their basic properties, processing history, microstructure and operating environment. Appropriate submissions to Materials Science and Engineering A should include scientific and/or engineering factors which affect the microstructure - strength relationships of materials and report the changes to mechanical behavior.