This paper studies the feasibility of reciprocating motion of non-contact control implants (small permanent magnets) by simulating a magnetic stereotaxic system using COMSOL software. The experimental results are consistent with the simulation results. When the large permanent magnet (LPM) on one side is approached, it will attract the small permanent magnet (SPM) to move towards the barrel wall, and when it leaves, the small permanent magnet stays at the barrel wall. At this time, the large permanent magnet on the other side begins to approach. When a certain distance is reached, the small permanent magnet is attracted by it, moves from one side of the barrel wall to the other side, and stays on the barrel wall after arrival.
KEYWORDS: 3D modeling, Lung, Computed tomography, Rapid manufacturing, 3D printing, Printing, Visual process modeling, Systems modeling, Data modeling, Visualization
The development of such a model of the human lung allowed to master the technology of recreating anatomical structures based on personalized data of spiral computed tomography taking into account individual variability, which can be useful in determining the volume of pathologically altered areas and planning treatment. These approaches also make it possible to significantly improve the technology of training medical and bioengineering specialists.
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