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Dexterous magnetic manipulation of conductive non-magnetic objects

Lan N. Pham, Griffin F. Tabor, Ashkan Pourkand, Jacob L. B. Aman, Tucker Hermans and Jake J. Abbott ()
Additional contact information
Lan N. Pham: University of Utah
Griffin F. Tabor: University of Utah
Ashkan Pourkand: University of Utah
Jacob L. B. Aman: Lawrence Livermore National Laboratory
Tucker Hermans: University of Utah
Jake J. Abbott: University of Utah

Nature, 2021, vol. 598, issue 7881, 439-443

Abstract: Abstract Dexterous magnetic manipulation of ferromagnetic objects is well established, with three to six degrees of freedom possible depending on object geometry1. There are objects for which non-contact dexterous manipulation is desirable that do not contain an appreciable amount of ferromagnetic material but do contain electrically conductive material. Time-varying magnetic fields generate eddy currents in conductive materials2–4, with resulting forces and torques due to the interaction of the eddy currents with the magnetic field. This phenomenon has previously been used to induce drag to reduce the motion of objects as they pass through a static field5–8, or to apply force on an object in a single direction using a dynamic field9–11, but has not been used to perform the type of dexterous manipulation of conductive objects that has been demonstrated with ferromagnetic objects. Here we show that manipulation, with six degrees of freedom, of conductive objects is possible by using multiple rotating magnetic dipole fields. Using dimensional analysis12, combined with multiphysics numerical simulations and experimental verification, we characterize the forces and torques generated on a conductive sphere in a rotating magnetic dipole field. With the resulting model, we perform dexterous manipulation in simulations and physical experiments.

Date: 2021
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DOI: 10.1038/s41586-021-03966-6

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