npj Computational Materials (May 2023)

Enabling rapid X-ray CT characterisation for additive manufacturing using CAD models and deep learning-based reconstruction

  • Amirkoushyar Ziabari,
  • S. V. Venkatakrishnan,
  • Zackary Snow,
  • Aleksander Lisovich,
  • Michael Sprayberry,
  • Paul Brackman,
  • Curtis Frederick,
  • Pradeep Bhattad,
  • Sarah Graham,
  • Philip Bingham,
  • Ryan Dehoff,
  • Alex Plotkowski,
  • Vincent Paquit

DOI
https://doi.org/10.1038/s41524-023-01032-5
Journal volume & issue
Vol. 9, no. 1
pp. 1 – 10

Abstract

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Abstract Metal additive manufacturing (AM) offers flexibility and cost-effectiveness for printing complex parts but is limited to few alloys. Qualifying new alloys requires process parameter optimisation to produce consistent, high-quality components. High-resolution X-ray computed tomography (XCT) has not been effective for this task due to artifacts, slow scan speed, and costs. We propose a deep learning-based approach for rapid XCT acquisition and reconstruction of metal AM parts, leveraging computer-aided design models and physics-based simulations of nonlinear interactions between X-ray radiation and metals. This significantly reduces beam hardening and common XCT artifacts. We demonstrate high-throughput characterisation of over a hundred AlCe alloy components, quantifying improvements in characterisation time and quality compared to high-resolution microscopy and pycnometry. Our approach facilitates investigating the impact of process parameters and their geometry dependence in metal AM.