Constant charge time of defibrillation capacitor
First Claim
1. A system for controlling the charging and discharging of a defibrillation capacitor comprising:
- battery supply means for providing a supply voltage;
defibrillation capacitor means for being charged to a predetermined voltage;
transformer means comprising a primary and a secondary, the secondary being connected to said defibrillation capacitor means, the secondary being charged by said primary for delivering current to the defibrillation capacitor means;
inverter means connected to said battery supply means and to the primary of said transformer means, said inverter means capable of assuming a first state in which current is supplied from the battery supply means to the primary of the transformer means and a second state in which no current is supplied to the primary;
inverter drive means connected to the inverter means for generating an inverter drive signal at least three times the value of the supply voltage comprising repeating spaced pulses, each pulse of the drive signal triggering the inverter means to assume said first state to supply current to the primary of the transformer means for a duration corresponding to a duration of each pulse;
control means connected to said defibrillation capacitor means, to said inverter means and to said inverter drive means, said control means monitoring the voltage across said defibrillation capacitor means and monitoring the current in the primary reaching a preset value, and to terminate the inverter drive signal in response to the voltage of said defibrillation capacitor means reaching said predetermined voltage;
said control means controlling said inverter drive means to maintain the frequency of the inverter drive signal constant so that the energy delivered to the defibrillation capacitor means from the secondary of the transformer means per cycle of the inverter drive signal is constant;
defibrillation trigger means connected to said defibrillation capacitor means for triggering the discharge of said defibrillation capacitor means to defibrillation electrodes;
termination means connected to said defibrillation capacitor means for terminating the discharge of said defibrillation capacitor means a preset period of time after the discharge of the defibrillation capacitor means to the defibrillation electrodes by directing the charge of said defibrillation capacitor means to ground; and
internal discharge means for connecting the defibrillation capacitor means to ground upon desiring not to deliver a defibrillation shock.
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Accused Products
Abstract
A capacitor charging circuit for charging a defibrillation capacitor in a constant period of time regardless of battery voltage by employing a controlled duty cycle charging technique. The defibrillation capacitor is charged in a piecemeal manner through a transistor and flyback transformer circuit. The gate of the transistor is driven by a constant frequency pulse train inverter drive signal in which voltage is conveyed to the capacitors during one-half of the full cycle of the pulse train. The primary of the transformer is controlled by each pulse of the inverter drive signal so that the secondary of the transformer supplies current to the defibrillation capacitors during the off half cycle of the drive signal, the charge being built up in the defibrillation capacitors incrementally during the off half cycle of the inverter drive signal until the predetermined voltage is reached.
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Citations
2 Claims
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1. A system for controlling the charging and discharging of a defibrillation capacitor comprising:
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battery supply means for providing a supply voltage; defibrillation capacitor means for being charged to a predetermined voltage; transformer means comprising a primary and a secondary, the secondary being connected to said defibrillation capacitor means, the secondary being charged by said primary for delivering current to the defibrillation capacitor means; inverter means connected to said battery supply means and to the primary of said transformer means, said inverter means capable of assuming a first state in which current is supplied from the battery supply means to the primary of the transformer means and a second state in which no current is supplied to the primary; inverter drive means connected to the inverter means for generating an inverter drive signal at least three times the value of the supply voltage comprising repeating spaced pulses, each pulse of the drive signal triggering the inverter means to assume said first state to supply current to the primary of the transformer means for a duration corresponding to a duration of each pulse; control means connected to said defibrillation capacitor means, to said inverter means and to said inverter drive means, said control means monitoring the voltage across said defibrillation capacitor means and monitoring the current in the primary reaching a preset value, and to terminate the inverter drive signal in response to the voltage of said defibrillation capacitor means reaching said predetermined voltage;
said control means controlling said inverter drive means to maintain the frequency of the inverter drive signal constant so that the energy delivered to the defibrillation capacitor means from the secondary of the transformer means per cycle of the inverter drive signal is constant;defibrillation trigger means connected to said defibrillation capacitor means for triggering the discharge of said defibrillation capacitor means to defibrillation electrodes; termination means connected to said defibrillation capacitor means for terminating the discharge of said defibrillation capacitor means a preset period of time after the discharge of the defibrillation capacitor means to the defibrillation electrodes by directing the charge of said defibrillation capacitor means to ground; and internal discharge means for connecting the defibrillation capacitor means to ground upon desiring not to deliver a defibrillation shock. - View Dependent Claims (2)
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Specification