Development of an electrostatic generator that harnesses the motion of a living body - Fundamental study

R. Tashiro; N. Kabei; K. Tsuchiya; K. Katayama; Y. Ishizuka; F. Tsuboi

Development of an electrostatic generator that harnesses the motion of a living body - Fundamental study

R. Tashiro, N. Kabei, K. Tsuchiya, K. Katayama, Y. Ishizuka, F. Tsuboi

Department of Bioscience and Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

We studied a variable-capacitance-type electrostatic generator that could potentially be used to permanently supply electrical energy to an apperatus for in vivo use such as a cardiac pacemaker. The generating system consists of a battery for supplying electric charge, a variable capacitor for energy conversion, a capacitor for electrical energy storage and two rectifiers. A honeycomb-type variable capacitor whose capacitance varies from 54 to 290 nF was created. It was possible to generate a maximum electrical energy of approximately 14.3 μJ/cycle. We found that the electrical energy for driving a cadiac pacemaker can be generated by using the honeycomb-type variable capacitor with higher capacitance.

Original language	English
Pages (from-to)	491-496
Number of pages	6
Journal	Japanese Journal of Artificial Organs
Volume	28
Issue number	2
Publication status	Published - 1999 Jan 1

Keywords

Cardiac pacemaker
Electrostatic
Generator
Micromachine

ASJC Scopus subject areas

Biophysics

Cite this

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AU - Katayama, K.

AU - Ishizuka, Y.

AU - Tsuboi, F.

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N2 - We studied a variable-capacitance-type electrostatic generator that could potentially be used to permanently supply electrical energy to an apperatus for in vivo use such as a cardiac pacemaker. The generating system consists of a battery for supplying electric charge, a variable capacitor for energy conversion, a capacitor for electrical energy storage and two rectifiers. A honeycomb-type variable capacitor whose capacitance varies from 54 to 290 nF was created. It was possible to generate a maximum electrical energy of approximately 14.3 μJ/cycle. We found that the electrical energy for driving a cadiac pacemaker can be generated by using the honeycomb-type variable capacitor with higher capacitance.

AB - We studied a variable-capacitance-type electrostatic generator that could potentially be used to permanently supply electrical energy to an apperatus for in vivo use such as a cardiac pacemaker. The generating system consists of a battery for supplying electric charge, a variable capacitor for energy conversion, a capacitor for electrical energy storage and two rectifiers. A honeycomb-type variable capacitor whose capacitance varies from 54 to 290 nF was created. It was possible to generate a maximum electrical energy of approximately 14.3 μJ/cycle. We found that the electrical energy for driving a cadiac pacemaker can be generated by using the honeycomb-type variable capacitor with higher capacitance.

KW - Cardiac pacemaker

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Development of an electrostatic generator that harnesses the motion of a living body - Fundamental study

Abstract

Keywords

ASJC Scopus subject areas

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