News Release

Enhancement of material microstructure and properties in Arc wire-based direct energy deposition: A short review

Peer-Reviewed Publication

Tsinghua University Press

Outline of the review

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The primary issue in arc melting additive manufacturing is the high heat input, which results in stress and deformation, significantly affecting the microstructure. Factors such as temperature gradient, solidification rate, and sub-cooling of the layer play a crucial role. Techniques to manage these factors include auxiliary outfield, auxiliary plastic deformation, and heat treatment. The microstructure's key characteristics, such as grain size, orientation, and distribution, determine yield strength, hardness, strength, and flexibility. External fields can enhance sample performance through work hardening, fine grain, and dispersion strengthening.

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Credit: Journal of Advances Mechanical Science and Technology

In recent years, additive manufacturing technology has attracted considerable attention from various stakeholders. Among the different techniques, Arc wire-based direct energy deposition (DED) has experienced a notable increase in development, offering compelling advantages such as cost-effectiveness and high forming efficiency. However, a high deposition rate results in extremely high heat input and temperature inhomogeneity, leading to a deterioration in surface quality, a reduction in material properties, an increase in residual stresses and even distortion and cracking. Consequently, the current research agenda is focused on developing methods to ensure the quality of components produced at high deposition rates. Furthermore, additional research is necessary to gain a comprehensive understanding of Arc wire-based direct energy deposition technology, particularly regarding microstructure control and mechanical property optimization, to meet the demands of higher-performance applications.

A team led by the Nanjing University of Aeronautics and Astronautics in China conducted a literature review to identify the factors that influence the microstructure evolution of materials during the deposition process. The team employed the principle of dynamic recrystallisation to investigate the influence of heat input during the deposition process and to delineate methods for controlling heat input and its operating mechanisms. Furthermore, the article presents a comprehensive analysis of the impact of diverse process parameters on the melt pool behavior and microstructure during the deposition process, with a particular focus on the influence of process methods and deposition materials. To enhance the material's microstructure and properties, various supplementary techniques and treatments, including interlayer forging and ultrasonic impact, are examined to optimize the material's characteristics. The effect of these methods on the microstructure and mechanical properties during deposition, as well as their respective advantages and disadvantages, are discussed in detail. This work presents novel approaches for improving the properties of materials deposited by Arc wire-based DED, thereby contributing to the advancement of the field.

The team published their work in the Journal of Advances Mechanical Science and Technology on October 15, 2024.

“In this report, we discuss the factors that influence the evolution of the material's microstructure during the deposition process. It summarizes methods to control the heat input during deposition and highlights various heat treatment techniques to reduce defects and improve the microstructure and properties of the deposited parts. These techniques include pre-deposition, process, and post-deposition treatments. The study also investigates methods for introducing deformation strengthening and briefly reviews their advantages and disadvantages. Lastly, the manuscript presents the future development direction and research focus of Arc wire-based DED.” said Dr. Qian, an associate professor at the Nanjing University of Aeronautics and Astronautics (NUAA).

This manuscript provides valuable insights for researchers in related fields. It enables them to comprehensively understand methods to enhance the microstructure and properties of Arc wire-based DED parts in a short timeframe. Additionally, it offers insights into the functional mechanisms that can be applied in their research work, thereby expanding the potential applications of Arc wire-based DED parts.

Nevertheless, research into the solidification characteristics of different materials and the deposition characteristics of different processes continues to yield increasingly detailed insights and innovative methods for regulating the microstructure and mechanical properties of Arc wire-based directed energy deposition parts. These research directions on microstructure and mechanical property control should focus on the following four aspects, as previously highlighted by Dr. Qian: The research above directions on microstructure and mechanical property control should focus on the following four aspects: control of heat input, control of solidification behavior, control of the dynamic recrystallisation process, and control of deleterious phases and defects.

Other participants in the research include Jingjing Shi, Professor Honghua SU, Professor Wenfeng DING, Professor Yucan FU of Nanjing University of Aeronautics and Astronautics, and Shihao SUN of Jiangsu JITRI Institute of Precision Manufacturing.

This work was supported by the National Natural Science Foundation of China (Nos.52205476 and 92160301), the Youth Talent Support Project of Jiangsu Provincial Association of Science and Technology (No. TJ-2023-070), the Fund of Prospective Layout of Scientific Research for the Nanjing University of Aeronautics and Astronautics (No. 1005-ILB23025-1A), and the Fund of Jiangsu Key Laboratory of Precision and Micro-Manufacturing Technology (No. 1005-ZAA20003-14).

 


About Author

Ning Qian is currently an associate professor at the Nanjing University of Aeronautics and Astronautics (NUAA), where he is primarily engaged in Arc wire-based direct energy deposition of superalloys. He has overseen numerous research projects, including the Youth Project of the National Natural Science Foundation of China (NSFC), sub-projects of the NSFC integrated project, projects of Science Center of Gas Turbine, projects of industrial reengineering and high-quality development of the manufacturing industry, and the China Postdoctoral Science Foundation.

Qian has published over 40 academic papers and holds over ten invention patents. His research findings have been recognized with the second prize of the Jiangsu Science and Technology Award, the Excellent Doctoral Dissertation Award of Jiangsu Province, and the bronze medal of the Geneva Invention Exhibition. He has been selected for the Jiangsu Provincial Association for Science and Technology Youth Support Program and the Jiangsu Provincial Excellent Postdoctoral Program. He is currently a member of the Chinese Mechanical Engineering Society, the Chinese Aeronautical Society. Additionally, he serves as an academic part-time member of the young editorial board of the Journal of Advanced Manufacturing Science and Technology.


About Journal of Advanced Manufacturing Science and Technology

Journal of Advanced Manufacturing Science and Technology (JAMST) is an open-access and peer-reviewed journal that was launched by Dalian University of Technology and Engineering Research Center of Advanced Manufacturing Technology for Aero Engine, Ministry of Education, Northwestern Polytechnical University in 2021. The journal is published by Tsinghua University Presss.

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