High-Efficiency Transcutaneous Energy Transfer for Implantable Mechanical Heart Support Systems

Inductive power transfer technology is a promising solution for powering implantable mechanical circulatory support systems, due to the elimination of the percutaneous driveline, which is still the major cause of severe infections. However, at the present time, no transcutaneous energy transfer (TET...

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Bibliographic Details
Published in:IEEE transactions on power electronics 2015-11, Vol.30 (11), p.6221-6236
Main Authors: Knecht, Oliver, Bosshard, Roman, Kolar, Johann W.
Format: Article
Language:English
Subjects:
Batteries
Circuits
Coils
Couplings
Electrical design
Electronics
Frequencies
Gallium-Nitride FET
Heart surgery
Impedance
Inductive Power Transfer
Inverters
Mathematical model
Mathematical models
Power Loss Modeling
Resonant Converter
Synchronous Rectifier
Topology
Transcutaneous Energy Transfer
Transplants & implants
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Summary:Inductive power transfer technology is a promising solution for powering implantable mechanical circulatory support systems, due to the elimination of the percutaneous driveline, which is still the major cause of severe infections. However, at the present time, no transcutaneous energy transfer (TET) system is commercially available and ready for long-term use. Specifically, the heating of the tissue due to power losses in the TET coils and the implanted electronic components are a major problem. The focus of this paper is, therefore, on the design and realization of a highly efficient TET system and the minimization of the power losses in the implanted circuits in particular. Parameter sweeps are performed in order to find the optimal energy transmission coil parameters. In addition, simple and meaningful design equations for optimal load matching are presented together with a detailed mathematical model of the power electronic stages. To achieve highest efficiencies, a high-frequency self-driven synchronous rectifier circuit with minimized volume is developed. Extensive measurements are carried out to validate the mathematical models and to characterize the performance of the prototype system. The optimized system is capable of transmitting 30 W of power with an efficiency greater than 95 %, even at a coil separation distance of 20 mm (0.79 in) and 70 mm (2.76 in) coil diameter.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2015.2396194