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Design and Optimization of Coil for Transcutaneous Energy Transmission System

This article presents a coil couple-based transcutaneous energy transmission system (TETS) for wirelessly powering implanted artificial hearts. In the TETS, the performance of the system is commonly affected by the change in the position of the coupling coils, which are placed inside and outside the...

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Published in:	Electronics (Basel) 2024-06, Vol.13 (11), p.2157
Main Authors:	Wu, Ruiming, Li, Haonan, Chen, Jiangyu, Le, Qi, Wang, Lijun, Huang, Feng, Fu, Yang
Format:	Article
Language:	English
Subjects:	Analysis Artificial organs Coils Coupling Design optimization Efficiency Electric power transmission Energy Energy transmission Heart Implants, Artificial Magnetic fields Medical equipment Medical research Misalignment Numerical models Optimization Prosthesis Skin Transplants & implants
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creator	Wu, Ruiming Li, Haonan Chen, Jiangyu Le, Qi Wang, Lijun Huang, Feng Fu, Yang
description	This article presents a coil couple-based transcutaneous energy transmission system (TETS) for wirelessly powering implanted artificial hearts. In the TETS, the performance of the system is commonly affected by the change in the position of the coupling coils, which are placed inside and outside the skin. However, to some extent, the influence of coupling efficiency caused by misalignment can be reduced by optimizing the coil. Thus, different types of coils are designed in this paper for comparison. It has been found that the curved coil better fits the surface of the skin and provides better performance for the TETS. Various types of curved coils have been designed in response to observed bending deformations, dislocations, and other coupling variations in the curved coil couple. The numerical model of the TETS is established to analyze the effects of the different types of coils. Subsequently, a series of experiments are designed to evaluate the resilience to misalignment and to verify the heating of the coil under conditions of severe coupling misalignment. The results indicated that, in the case of misalignment of the coils used in artificial hearts, the curved transmission coil demonstrated superior efficiency and lower temperature rise compared to the planar coil.
doi_str_mv	10.3390/electronics13112157
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In the TETS, the performance of the system is commonly affected by the change in the position of the coupling coils, which are placed inside and outside the skin. However, to some extent, the influence of coupling efficiency caused by misalignment can be reduced by optimizing the coil. Thus, different types of coils are designed in this paper for comparison. It has been found that the curved coil better fits the surface of the skin and provides better performance for the TETS. Various types of curved coils have been designed in response to observed bending deformations, dislocations, and other coupling variations in the curved coil couple. The numerical model of the TETS is established to analyze the effects of the different types of coils. Subsequently, a series of experiments are designed to evaluate the resilience to misalignment and to verify the heating of the coil under conditions of severe coupling misalignment. 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subjects	Analysis Artificial organs Coils Coupling Design optimization Efficiency Electric power transmission Energy Energy transmission Heart Implants, Artificial Magnetic fields Medical equipment Medical research Misalignment Numerical models Optimization Prosthesis Skin Transplants & implants
title	Design and Optimization of Coil for Transcutaneous Energy Transmission System
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