Your search keyword '"Inductive transmission systems"' showing total 3 results

1. Reduction of eddy current losses in inductive transmission systems with ferrite sheets.

Author

Maaβ, Matthias, Steixner, Viktor, Zierhofer, Clemens, Maaß, Matthias, and Griessner, Andreas

Subjects

*EDDY currents (Electric), *FERRITES, *COCHLEAR implants, *BIOMEDICAL materials, *FINITE element method, *COPPER, *ELECTROPHYSIOLOGY, *IRON compounds, *MAGNETIC fields

Abstract

Background: Improvements in eddy current suppression are necessary to meet the demand for increasing miniaturization of inductively driven transmission systems in industrial and biomedical applications. The high magnetic permeability and the simultaneously low electrical conductivity of ferrite materials make them ideal candidates for shielding metallic surfaces. For systems like cochlear implants the transmission of data as well as energy over an inductive link is conducted within a well-defined parameter set. For these systems, the shielding can be of particular importance if the properties of the link can be preserved.Results: In this work, we investigate the effect of single and double-layered substrates consisting of ferrite and/or copper on the inductance and coupling of planar spiral coils. The examined link systems represent realistic configurations for active implantable systems such as cochlear implants. Experimental measurements are complemented with analytical calculations and finite element simulations, which are in good agreement for all measured parameters. The results are then used to study the transfer efficiency of an inductive link in a series-parallel resonant topology as a function of substrate size, the number of coil turns and coil separation.Conclusions: We find that ferrite sheets can be used to shield the system from unwanted metallic surfaces and to retain the inductive link parameters of the unperturbed system, particularly its transfer efficiency. The required size of the ferrite plates is comparable to the size of the coils, which makes the setup suitable for practical implementations. Since the sizes and geometries chosen for the studied inductive links are comparable to those of cochlear implants, our conclusions apply in particular to these systems. [ABSTRACT FROM AUTHOR]

Published

2017

2. Reduction of eddy current losses in inductive transmission systems with ferrite sheets

Author

Clemens Zierhofer, Matthias Maaß, Andreas Griessner, and Viktor Steixner

Subjects

Engineering, Acoustics, Finite Element Analysis, Biomedical Engineering, 02 engineering and technology, 01 natural sciences, Ferric Compounds, law.invention, Biomaterials, Eddy current losses, law, Ferrite shield, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Miniaturization, Eddy current, Series–parallel resonant converter, Radiology, Nuclear Medicine and imaging, 010302 applied physics, Radiological and Ultrasound Technology, business.industry, Research, 020208 electrical & electronic engineering, Electric Conductivity, Inductive transmission systems, General Medicine, Transmission system, Finite element method, Inductance, Magnetic Fields, Electromagnetic coil, Electromagnetic shielding, Cochlear implants, Ferrite (magnet), business, Copper

Abstract

Background Improvements in eddy current suppression are necessary to meet the demand for increasing miniaturization of inductively driven transmission systems in industrial and biomedical applications. The high magnetic permeability and the simultaneously low electrical conductivity of ferrite materials make them ideal candidates for shielding metallic surfaces. For systems like cochlear implants the transmission of data as well as energy over an inductive link is conducted within a well-defined parameter set. For these systems, the shielding can be of particular importance if the properties of the link can be preserved. Results In this work, we investigate the effect of single and double-layered substrates consisting of ferrite and/or copper on the inductance and coupling of planar spiral coils. The examined link systems represent realistic configurations for active implantable systems such as cochlear implants. Experimental measurements are complemented with analytical calculations and finite element simulations, which are in good agreement for all measured parameters. The results are then used to study the transfer efficiency of an inductive link in a series–parallel resonant topology as a function of substrate size, the number of coil turns and coil separation. Conclusions We find that ferrite sheets can be used to shield the system from unwanted metallic surfaces and to retain the inductive link parameters of the unperturbed system, particularly its transfer efficiency. The required size of the ferrite plates is comparable to the size of the coils, which makes the setup suitable for practical implementations. Since the sizes and geometries chosen for the studied inductive links are comparable to those of cochlear implants, our conclusions apply in particular to these systems.

Published

2016

3. Reduction of eddy current losses in inductive transmission systems with ferrite sheets.

Author

Maaß M, Griessner A, Steixner V, and Zierhofer C

Subjects

Copper, Finite Element Analysis, Electric Conductivity, Ferric Compounds, Magnetic Fields

Abstract

Background: Improvements in eddy current suppression are necessary to meet the demand for increasing miniaturization of inductively driven transmission systems in industrial and biomedical applications. The high magnetic permeability and the simultaneously low electrical conductivity of ferrite materials make them ideal candidates for shielding metallic surfaces. For systems like cochlear implants the transmission of data as well as energy over an inductive link is conducted within a well-defined parameter set. For these systems, the shielding can be of particular importance if the properties of the link can be preserved., Results: In this work, we investigate the effect of single and double-layered substrates consisting of ferrite and/or copper on the inductance and coupling of planar spiral coils. The examined link systems represent realistic configurations for active implantable systems such as cochlear implants. Experimental measurements are complemented with analytical calculations and finite element simulations, which are in good agreement for all measured parameters. The results are then used to study the transfer efficiency of an inductive link in a series-parallel resonant topology as a function of substrate size, the number of coil turns and coil separation., Conclusions: We find that ferrite sheets can be used to shield the system from unwanted metallic surfaces and to retain the inductive link parameters of the unperturbed system, particularly its transfer efficiency. The required size of the ferrite plates is comparable to the size of the coils, which makes the setup suitable for practical implementations. Since the sizes and geometries chosen for the studied inductive links are comparable to those of cochlear implants, our conclusions apply in particular to these systems.

Published

2017