Project Abstract

This project aims to provide a comprehensive understanding of the relationship between the microstructure and mechanical properties of titanium alloy components produced through additive manufacturing (AM) techniques. Titanium alloys are widely used in various industries, such as aerospace, biomedical, and automotive, due to their exceptional strength-to-weight ratio, corrosion resistance, and biocompatibility. However, traditional manufacturing methods can be limited in their ability to produce complex geometries and customized components. Additive manufacturing, also known as 3D printing, has emerged as a promising technology that can overcome these limitations by allowing the fabrication of intricate and personalized parts. The unique thermal history and layer-by-layer build process of AM can significantly impact the microstructural evolution and, consequently, the mechanical performance of the final product. Understanding these relationships is crucial for optimizing the design and manufacture of titanium alloy components for various applications. This project will focus on investigating the microstructural characteristics, such as grain size, phase distribution, and defect formation, of titanium alloy components produced through different AM techniques, including selective laser melting (SLM), electron beam melting (EBM), and directed energy deposition (DED). The mechanical properties, including tensile strength, hardness, and fatigue life, will be thoroughly evaluated and correlated with the observed microstructural features. The research methodology will involve a combination of experimental techniques and numerical simulations. Advanced characterization tools, such as scanning electron microscopy (SEM), X-ray diffraction (XRD), and transmission electron microscopy (TEM), will be employed to analyze the microstructural details. Mechanical testing, including tensile, hardness, and fatigue tests, will be conducted to assess the performance of the additively manufactured titanium alloy components. Numerical simulations, such as finite element analysis (FEA) and computational fluid dynamics (CFD), will be used to model the complex thermal and solidification processes during AM, enabling a deeper understanding of the microstructural evolution and its influence on the mechanical properties. These simulations will also aid in the optimization of process parameters and component design to achieve the desired mechanical performance. The expected outcomes of this project include the development of a comprehensive understanding of the relationship between the microstructure and mechanical properties of additively manufactured titanium alloy components. The findings will contribute to the advancement of AM technologies and assist in the design and manufacturing of high-performance titanium alloy components for various industrial applications. The knowledge gained from this project will be disseminated through peer-reviewed journal publications, conference presentations, and collaborations with industry partners. The insights generated will serve as a valuable resource for researchers, engineers, and manufacturers working in the field of additive manufacturing and titanium alloy-based products.

Project Overview