Capacitor charging circuit for implantable defibrillator
First Claim
1. In an implantable defibrillator sized for implantation within a living human patient, having a battery, a voltage step-up transformer having a primary winding connected to said battery, and having a secondary winding, a high-voltage energy storage capacitor connected to said secondary winding, and a lead and an electrode each sized for implantation within a living human patient in proximity to cardiac tissue, said electrode being electrically connected to said high-voltage storage capacitor via said lead, the improvement comprising a capacitor charger including:
- switching means in circuit communication with said battery and said primary winding for interrupting current flow through said primary winding; and
control means in circuit communication with said battery and with said switching means, and directly responsive to the voltage of said battery, for causing said switching means to interrupt current cyclicly at a frequency that is variable as a function of the voltage of said battery throughout the useful life of said battery.
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Accused Products
Abstract
An implantable defibrillator having a charging circuit for charging a high-voltage energy storage capacitor from a low voltage battery. Current from the battery is switched on and off through the primary winding of a voltage step-up transformer to induce a fly-back current in the secondary winding. The fly-back current is rectified and applied across the energy storage capacitor. The frequency of switching of the primary current is varied in relationship to the voltage of the battery to maintain a substantially constant average charging current as battery voltage decreases. Current through the primary is monitored on a cycle-by-cycle basis and switched off if it exceeds a preset limit.
74 Citations
15 Claims
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1. In an implantable defibrillator sized for implantation within a living human patient, having a battery, a voltage step-up transformer having a primary winding connected to said battery, and having a secondary winding, a high-voltage energy storage capacitor connected to said secondary winding, and a lead and an electrode each sized for implantation within a living human patient in proximity to cardiac tissue, said electrode being electrically connected to said high-voltage storage capacitor via said lead, the improvement comprising a capacitor charger including:
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switching means in circuit communication with said battery and said primary winding for interrupting current flow through said primary winding; and control means in circuit communication with said battery and with said switching means, and directly responsive to the voltage of said battery, for causing said switching means to interrupt current cyclicly at a frequency that is variable as a function of the voltage of said battery throughout the useful life of said battery. - View Dependent Claims (2, 3, 4)
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5. In an implantable defibrillator sized for implantation within a living human patient, having a battery, a voltage step-up transformer having a primary winding connected to said battery, and having a secondary winding, a high-voltage energy storage capacitor connected to said secondary winding, and a lead and an electrode each sized for implantation within a living human patient in proximity to cardiac tissue, said electrode being electrically connected to said high-voltage storage capacitor via said lead, the improvement comprising a capacitor charger including:
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switching means in circuit communication with said battery and said primary winding for cyclicly permitting and interrupting current flow through said primary winding; and control means in circuit communication with said battery and with said switching means, and directly responsive to the voltage of said battery, for causing said switching means to cyclicly permit and interrupt current such that the on-time of each cycle is variable as a function of the voltage of said battery throughout the useful life of said battery. - View Dependent Claims (6, 7, 8)
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9. In an implantable defibrillator sized for implantation within a living human patient, having a battery, a voltage step-up transformer having a primary winding connected to said battery, and having a secondary winding, a high-voltage energy storage capacitor connected to said secondary winding, and a lead and an electrode each sized for implantation within a living human patient in proximity to cardiac tissue, said electrode being electrically connected to said high-voltage storage capacitor via said lead, the improvement comprising a capacitor charger including:
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switching means in circuit communication with said battery and said primary winding for cyclicly permitting and interrupting current flow through said primary winding; and control means in circuit communication with said battery and with said switching means, and directly responsive to the voltage of said battery, for causing said switching means to cyclicly permit and interrupt current such that the average current is substantially constant as the voltage of said battery decreases throughout the useful life of said battery. - View Dependent Claims (10, 11, 12)
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13. In an implantable defibrillator sized for implantation within a living human patient, having a battery, a voltage step-up transformer having primary and secondary windings, a high-voltage energy storage capacitor connected to said secondary winding, and a lead and an electrode each sized for implantation within a living human patient in proximity to cardiac tissue, said electrode being electrically connected to said high-voltage storage .capacitor via said lead, the improvement comprising a capacitor charger including:
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switching means in circuit communication with said battery and said primary winding for interrupting current flow from said battery through said primary winding; current sensing means in circuit communication with said primary winding for sensing current flow through said primary winding; and control means in circuit communication with said battery and with said switching means, and directly responsive to the voltage of said battery, for causing said switching means to interrupt current cyclicly at a frequency that is variable as a function of the voltage of said battery throughout the useful life of said battery, said control means further being in circuit communication with said current sensing means for causing said switching means to interrupt current in response to sensed current flow exceeding a preset current limit.
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14. A method of charging a high-voltage energy storage capacitor in an implantable defibrillator from a low voltage battery, said high-voltage energy storage capacitor having electrical terminals and said implantable defibrillator including a voltage step-up transformer having a primary winding and a secondary winding, comprising the steps of:
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switching on and off current from said battery through said primary winding of said voltage step-up transformer to induce a fly-back current in said secondary winding of said transformer; rectifying said fly-back current and applying said rectified current across the terminals of said high-voltage energy storage capacitor; and monitoring the voltage of said battery and varying the rate of switching of current through said primary winding in response to a decrease in battery voltage such that average current through said primary winding remains substantially constant as battery voltage decreases. - View Dependent Claims (15)
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Specification