4.5 Article

Numerical Modeling of Distortion of Ti-6Al-4V Components Manufactured Using Laser Powder Bed Fusion

Journal

METALS
Volume 12, Issue 9, Pages -

Publisher

MDPI
DOI: 10.3390/met12091484

Keywords

additive manufacturing; laser powder bed fusion; tibial component; titanium alloy; numerical modeling; distortion

Funding

  1. King Mongkut's University of Technology North Bangkok [KMUTNB-64-KNOW-18]
  2. National Research Council of Thailand (NRCT) and King Mongkut's University of Technology North Bangkok (KMUTNB) [N42A650321]
  3. Thailand Graduate Institute of Science and Technology (TGIST), National Science and Technology Development Agency (NSTDA) [SCA-CO-2562-9649-TH]
  4. Program Management Unit for Human Resources and Institutional Development, Research and Innovation, NXPO [B05F630092, B05F640205]
  5. National Research Council of Thailand (NRCT) [66082]

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This study explored and predicted the distortion of Ti-6Al-4V components manufactured using the L-PBF process through numerical modeling. The results showed good agreement between the numerical model and experimental data, and identified that the difference in stiffness between the tibial tray and support structure resulted in significant distortion. Additionally, component size and support-structure design were found to play an important role in distortion reduction.
The laser powder bed fusion (L-PBF) process is a powder-based additive manufacturing process that can manufacture complex metallic components. However, when the metallic components are fabricated with the L-PBF process, they frequently encounter the residual stress and distortion that occurs due to the cyclic of rapid heating and cooling. The distortion detrimentally impacts the dimensional and geometrical accuracy of final built parts in the L-PBF process. The purpose of this research was to explore and predict the distortion of Ti-6Al-4V components manufactured using the L-PBF process by using numerical modeling in Simufact Additive 2020 FP1 software. Firstly, the numerical model validation was conducted with the twin-cantilever beam part. Later, studies were carried out to examine the effect of component sizes and support-structure designs on the distortion of tibial component produced by the L-PBF process. The results of this research revealed a good agreement between the numerical model and experiment data. In addition, the platform was extended to predict the distortion in the tibial component. Large distortion arose near the interface between the tibial tray and support structure due to the different stiffness between the solid bulk and support structure. The distortion of the tibial component increased with increasing component size according to the surface area of the tibial tray, and with increasing thickness of the tibial tray. Furthermore, the support-structure design plays an important role in distortion reduction in the L-PBF process. For example, the maximum distortion of the tibial component was minimized up to 44% when a block support-structure design with a height of 2.5 mm was used instead of the lattice-based support. The present study provides useful information to help the medical sector to manufacture effective medical components and reduce the chance of part failure from cracking in the L-PBF process.

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