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用于膀胱压力长期监测的植入式无线电池充电系统。

Implantable wireless battery recharging system for bladder pressure chronic monitoring.

作者信息

Young Darrin J, Cong Peng, Suster Michael A, Damaser Margot

机构信息

Electrical and Computer Engineering Department, University of Utah, Salt Lake City, Utah, USA.

Electrical Engineering and Computer Science Department, Case Western Reserve University, Cleveland, Ohio, USA.

出版信息

Lab Chip. 2015 Nov 21;15(22):4338-47. doi: 10.1039/c5lc00821b.

DOI:10.1039/c5lc00821b
PMID:26419677
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6944981/
Abstract

This paper presents an implantable wireless battery recharging system design for bladder pressure chronic monitoring. The wireless recharging system consists of an external 15 cm-diameter 6-turn powering coil and a silicone-encapsulated implantable rectangular coil with a dimension of 7 mm × 17 mm × 2.5 mm and 18 turns, which further encloses a 3 mm-diameter and 12 mm-long rechargeable battery, two ferrite rods, an ASIC, and a tuning capacitor. For a constant recharging current of 100 μA, an RF power of 700 μW needs to be coupled into the implantable module through the tuned coils. Analyses and experiments confirm that with the two coils aligned coaxially or with a 6 cm axial offset and a tilting angle of 30°, an external power of 3.5 W or 10 W is required, respectively, at an optimal frequency of 3 MHz to cover a large implant depth of 20 cm.

摘要

本文介绍了一种用于膀胱压力长期监测的植入式无线电池充电系统设计。该无线充电系统由一个直径15厘米的6匝外部供电线圈和一个尺寸为7毫米×17毫米×2.5毫米、18匝的硅橡胶封装植入式矩形线圈组成,该矩形线圈进一步封装了一个直径3毫米、长12毫米的可充电电池、两根铁氧体棒、一个专用集成电路(ASIC)和一个调谐电容器。对于100μA的恒定充电电流,需要700μW的射频功率通过调谐线圈耦合到植入式模块中。分析和实验证实,当两个线圈同轴对齐或轴向偏移6厘米且倾斜角度为30°时,在3MHz的最佳频率下,分别需要3.5W或10W的外部功率,以覆盖20厘米的大植入深度。

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