Transactions on Additive Manufacturing Meets Medicine
Vol. 6 No. S1 (2024): Trans. AMMM Supplement
https://doi.org/10.18416/AMMM.2024.24091867
Enhancing additive electronic manufacturing using verification tools
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Copyright (c) 2024 Pascal Stagge, Maximilian Wattenberg, Eric Aderhold, Mandy Ahlborg, Thorsten M. Buzug, Matthias Gräser
This work is licensed under a Creative Commons Attribution 4.0 International License.
Abstract
The advent of additive manufacturing for electronic components and circuits enables the realisation of various new possibilities for developers, as the technology offers the potential to realise concepts that were previously considered impossible or only viable through considerable effort using conventional manufacturing techniques. The introduction of this new design freedom, however, also implies a corresponding increase in the parameter space, and thereby creating various risks and difficulties for developers, which may result in errors during the printing process. These errors may be a consequence of design flaws, slicing artefacts, or imperfect printing hardware, which can lead to suboptimal printing results. While the inherent inaccuracy in the 3D printing process can typically be accounted for and thus tolerated during the construction of mechanical components, inaccuracy in the printing of conductive traces can result in unexpected component behaviour, higher resistive traces or even disconnection of a circuit. This necessitates the implementation of a quality verification process following the printing stage, with the aim of enhancing the design process and ensuring the accuracy of the printed circuit. The typical verification tools employed for this task include electrical measurements, and tomographic imaging modalities.
In this work, a series of multi-dimensional coils were constructed to be used in in-house developed magnetic field generators, which form the basis of medical imaging systems. Following the printing process, the printed results were subjected to a series of tests. The thorough analysis of the printed parts revealed different kinds of deficiencies. Following the identification of these errors, redesigns were implemented, and printer parameters were adjusted to compensate for a majority of errors. These adaptions result in an overall improvement of quality in the finalised parts, a decreased completion time due to less redesigning iterations and a more comprehensive understanding of the influence of printing parameters.