Reforming wet-tantalum capacitors in implantable medical devices
First Claim
1. A capacitor-reform method comprising:
- a) charging at least one wet-tantalum capacitor in an implantable medical device;
b) allowing the one wet-tantalum capacitors to discharge through system leakage after charging the one wet-tantalum capacitor in the implantable medical device; and
c) discharging the one or more of the wet-tantalum capacitors through a non-therapeutic load, after allowing the one or more wet-tantalum capacitors to discharge through system leakage.
8 Assignments
0 Petitions
Accused Products
Abstract
Miniature defibrillators and cardioverters detect abnormal heart rhythms and automatically apply electrical therapy to restore normal heart function. Critical to this function, aluminum-electrolytic capacitors store and deliver life-saving bursts of electric charge to the heart. This type of capacitor requires regular “reform” to preserve its charging efficiency over time. Because reform expends valuable battery energy, manufacturers developed wet-tantalum capacitors, which are generally understood not to require reform. Yet, the present inventors discovered through extensive study that wet-tantalum capacitors exhibit progressively worse charging efficiency over time. Accordingly, to address this problem, the inventors devised unique reform techniques for wet-tantalum capacitors. One exemplary technique entails charging wet-tantalum capacitors to a voltage equal to about 90% of their rated voltage and allowing the charge to dissipate through system leakage for a period of time, before discharging through a non-therapeutic load.
90 Citations
18 Claims
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1. A capacitor-reform method comprising:
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a) charging at least one wet-tantalum capacitor in an implantable medical device; b) allowing the one wet-tantalum capacitors to discharge through system leakage after charging the one wet-tantalum capacitor in the implantable medical device; and c) discharging the one or more of the wet-tantalum capacitors through a non-therapeutic load, after allowing the one or more wet-tantalum capacitors to discharge through system leakage. - View Dependent Claims (2, 3, 4)
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5. A capacitor-reform method comprising:
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a) charging at least one wet-tantalum capacitor to a high voltage relative its rated voltage or maximum-energy voltage; b) partially discharging the one the wet-tantalum capacitors through system leakage after charging the one wet-tantalum capacitor to the high voltage; and c) discharging the one or more of the wet-tantalum capacitors through a non-therapeutic load, after partially discharging the one or more wet-tantalum capacitors through system leakage. - View Dependent Claims (6, 7, 8, 9, 10)
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11. A capacitor-reform method comprising:
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a) charging at least one wet-tantalum capacitor in an implantable medical device, in response to a reform signal from a processor in the medical device; b) allowing the one wet-tantalum capacitors to discharge through system leakage after charging the one wet-tantalum capacitor in the implantable medical device; and c) discharging the one or more of the wet-tantalum capacitors through a non-therapeutic load, after allowing the one or more wet-tantalum capacitors to discharge through system leakage. - View Dependent Claims (12, 13, 14)
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15. A capacitor-reform method comprising:
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a) charging at least one wet-tantalum capacitor in a device to a voltage; b) allowing the one wet-tantalum capacitors to discharge through system leakage after charging the one wet-tantalum capacitor in the device; and c) discharging the one or more of the wet-tantalum capacitors through a load, after allowing the one or more wet-tantalum capacitors to discharge through system leakage. - View Dependent Claims (16, 17, 18)
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Specification