Effect of build and unit cell orientation on the tensile, compressive, and torsional behavior of Ti-6Al-4V gyroid sheet-based structures

Gaetano Pollara; Amanda Heimbrook; Livan Fratini; Ken Gall

doi:10.1007/s40436-025-00566-9

Advances in Manufacturing ›› : 1 -15. DOI: 10.1007/s40436-025-00566-9

Article

Effect of build and unit cell orientation on the tensile, compressive, and torsional behavior of Ti-6Al-4V gyroid sheet-based structures

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¹Department of Engineering, University of Palermo, Viale delle Scienze, 90128, Palermo, Italy

²Department of Mechanical Engineering and Materials Science, Duke University, 27708, Durham, NC, USA

Corresponding author:

^a gaetano.pollara@unipa.it

Gaetano Pollara

Gaetano Pollara received his M.S. degree in Biomaterials Engineering and Ph.D. degree in Mechanical, Manufacturing, Management and Aerospace Innovation (M3AI) from University of Palermo in 2020 and 2024, respectively. Currently, he is working with Department of Engineering at University of Palermo as a Postdoctoral Associate. His research interests focus on additive manufacturing, especially laser powder bed fusion of metals.

Amanda Heimbrook

Amanda Heimbrook received her B.S. in Materials Science and Engineering from Virginia Tech in 2019, M.S. degree in Materials Science and Engineering from The University of Tennessee, Knoxville in 2020, and her Ph.D. degree in Mechanical Engineering and Materials Science from Duke University in 2023. She is currently a Postdoctoral Associate at Duke University, and her research interest focuses on 3D printing metals specifically through laser powder bed fusion.

Livan Fratini

Livan Fratini graduated with honors in Mechanical Engineering in 1993 and received his Ph.D. in Production Engineering in 1997 from University of Palermo. Currently, he is a professor of the Chair of Manufacturing at University of Palermo. He was awarded a young researcher travel award by the Japan Society for Technology of Plasticity (2000) and the F.W. Taylor Medal by the CIRP (2007). Professor Fratini has been involved in several research projects on metal forming topics and is a coauthor of about 260 papers in international scientific journals.

Ken Gall

Ken Gall received his B.S, M.S, and Ph.D. from University of Illinois, Champaign-Urbana in Mechanical Engineering (1995,1996, and 1998, respectively). He is currently a professor in Department of Mechanical Engineering and Materials Science at Duke University. His research aims to develop a fundamental understanding of the relationship between the processing, structure, and mechanical properties of materials.

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Abstract

Laser powder bed fusion (LPBF) enables the fabrication of intricate porous metallic structures, such as the sheet-based gyroid, recently used in orthopedic implants. Many implants are subjected to a complex stress environment, making strength verification across different loading modes imperative. This study investigates the effect of both unit cell and build orientation on gyroid structures. Build orientation and unit cell orientation were varied from 0° to 90° in 15° increments to determine the degree of anisotropy of Ti-6Al-4V samples in tension, compression, and torsion. For the relatively isotropic gyroid structure, build orientation was the most influential factor on anisotropy in tension and compression. The samples with 30° build orientation (B30) showed the highest strength across all three loading modes due to the overall print quality and orientation of layers withstanding the applied forces. These results guide the design optimization of 3D printed orthopedic implants with varying build and unit cell orientation.

Keywords

3D printing / Laser power bed fusion (LPBF) / Titanium alloys / Gyroid / Anisotropy

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Gaetano Pollara, Amanda Heimbrook, Livan Fratini, Ken Gall. Effect of build and unit cell orientation on the tensile, compressive, and torsional behavior of Ti-6Al-4V gyroid sheet-based structures. Advances in Manufacturing 1-15 DOI:10.1007/s40436-025-00566-9

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Received	Accepted	Published
2024-05-03	2025-05-12	2025-06-28
Issue Date	Revised Date
2025-07-14

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