초록 ▼

An EMI/energy dissipating filter for an active implantable medical device (AIMD) is described. The filter comprises a first gold braze hermetically sealing the insulator to a ferrule that is configured to be mounted in an opening in a housing for the AIMD. A lead wire is hermetically sealed in a pas

An EMI/energy dissipating filter for an active implantable medical device (AIMD) is described. The filter comprises a first gold braze hermetically sealing the insulator to a ferrule that is configured to be mounted in an opening in a housing for the AIMD. A lead wire is hermetically sealed in a passageway through the insulator by a second gold braze. A circuit board substrate is disposed adjacent the insulator. A two-terminal chip capacitor disposed adjacent to the circuit board has an active end metallization that is electrically connected to the active electrode plates and a ground end metallization that is electrically connected to the at least one ground electrode plates of the capacitor. A ground path electrically extends between the ground end metallization of the chip capacitor and the ferrule. The ground path comprises a conductive pin electrically and mechanically connected to the ferrule by a third gold braze. The ground path comprises an internal ground plate disposed within the circuit board substrate, and the internal ground plate is electrically connected to both the conductive pin and the ground end metallization of the chip capacitor. An active path electrically extends between the active end metallization of the chip capacitor and the lead wire.

대표청구항 ▼

1. An EMI/energy dissipating filter assembly for an active implantable medical device, the EMI/energy dissipating filter assembly comprising: a) an electrically conductive ferrule comprising a ferrule opening, wherein a conductive ground pin is conductively and mechanically connected to the ferrule

1. An EMI/energy dissipating filter assembly for an active implantable medical device, the EMI/energy dissipating filter assembly comprising: a) an electrically conductive ferrule comprising a ferrule opening, wherein a conductive ground pin is conductively and mechanically connected to the ferrule by a first gold braze, and wherein the ferrule is configured to be attachable to an opening in a housing of an active implantable medical device (AIMD);b) an insulator residing in the ferrule opening where a second gold braze hermetically seals the insulator to the ferrule, wherein at least one insulator passageway extends through the insulator to an insulator body fluid end surface and an insulator device end surface, wherein, when the ferrule is attached to the opening in the housing of the AIMD, the insulator device end surface and the insulator body fluid end surface reside inside the AIMD and outside the AIMD, respectively;c) a conductive lead wire hermetically sealed in the insulator passageway by a third gold braze, the lead wire extending from a lead wire first portion to a lead wire second portion, wherein at least the lead wire second portion extends outwardly beyond the insulator device end surface;d) a circuit board comprising spaced apart circuit board first and second sides, wherein the circuit board first side is adjacent to the insulator device end surface, and wherein the circuit board comprises at least one circuit board ground plate;e) a two-terminal MLCC chip capacitor disposed on or adjacent to the circuit board, the two-terminal MLCC chip capacitor comprising a chip capacitor dielectric supporting at least one active electrode plate interleaved in a capacitive relationship with at least one ground electrode plate, wherein an active metallization is conductively connected to the at least one active electrode plate, and a ground metallization is conductively connected to the at least one ground electrode plate, and wherein the ground metallization of the two-terminal MLCC chip capacitor is conductively connected to the circuit board ground plate;f) a circuit board first ground via hole extending through the circuit board, wherein at least a portion of the ground pin connected to the ferrule resides in the circuit board first ground via hole where the ground pin is conductively connected to the at least one circuit board ground plate spaced from where the circuit board ground plate is conductively connected to the ground metallization of the two-terminal MLCC chip capacitor; andg) a circuit board active via hole extending through the circuit board, but being conductively isolated from the circuit board ground plate, wherein the lead wire second portion extending outwardly beyond the insulator device end surface resides in the circuit board active via hole,h) wherein a ground conductive path extends from the ground metallization of the two-terminal MLCC chip capacitor conductively connected to the at least one circuit board ground plate, the circuit board ground plate being conductively connected to the ground pin residing in the circuit board first ground via hole with the ground pin being connected to the ferrule, andi) wherein an active conductive path extends from the lead wire residing in the circuit board active via hole to the active metallization of the two-terminal MLCC chip capacitor. 2. The EMI/energy dissipating filter assembly of claim 1, wherein at least a portion of the conductive ground pin resides in a ferrule countersink. 3. The EMI/energy dissipating filter assembly of claim 1, wherein the at least one circuit board ground plate is selected from the group consisting of a circuit board ground shield plate, a circuit board ground electrode plate, and a circuit board ground circuit trace. 4. The EMI/energy dissipating filter assembly of claim 3, wherein the at least one circuit board ground plate is an internal ground plate residing between the circuit board first and second sides, and wherein the circuit board comprises a circuit board second ground via hole spaced from a circuit board first ground via hole, wherein the ground conductive path comprises the circuit board internal ground plate being conductively connected to both: i) the ground metallization of the two-terminal MLCC chip capacitor through the circuit board second ground via hole; andii) the conductive ground pin residing in the circuit board first ground via hole, the conductive ground pin being connected to the ferrule. 5. The EMI/energy dissipating filter assembly of claim 1, wherein the at least one circuit board ground plate is a circuit board external ground plate at least partially residing on the circuit board first side. 6. The EMI/energy dissipating filter assembly of claim 5, wherein the circuit board external ground plate is selected from the group consisting of a circuit board ground shield plate, a circuit board ground electrode plate, a circuit board ground circuit trace, and combinations thereof. 7. The EMI/energy dissipating filter assembly of claim 1, wherein the active conductive path extending to the active metallization of the two-terminal MLCC chip capacitor and the lead wire includes an electrical connection to both the lead wire and the third gold braze hermetically sealing the lead wire in the insulator passageway. 8. An EMI/energy dissipating filter assembly for an implantable medical device, the EMI/energy dissipating filter assembly comprising: a) an electrically conductive ferrule comprising a ferrule opening, wherein a conductive ground pin is conductively and mechanically connected to the ferrule by a first gold braze, and wherein the ferrule is configured to be attachable to an opening in a housing of an active implantable medical device;b) an insulator at least partially disposed within the ferrule opening where a second gold braze hermetically seals the insulator to the ferrule, wherein at least one insulator passageway extends through the insulator to an insulator first end surface and an insulator second end surface;c) a conductive lead wire in nonconductive relationship with the ferrule and being hermetically sealed in the insulator passageway by a third gold braze, the lead wire extending from a lead wire first portion to a lead wire second portion, wherein at least the lead wire second portion extends outwardly beyond the insulator second end surface;d) a circuit board comprising spaced apart circuit board first and second sides, wherein the circuit board first side is adjacent to the insulator second end surface, and wherein the circuit board comprises at least one circuit board ground plate;e) a two-terminal chip capacitor disposed on or adjacent to the circuit board, the two-terminal chip capacitor comprising a chip capacitor dielectric supporting at least one active electrode plate interleaved in a capacitive relationship with at least one ground electrode plate, wherein an active metallization is conductively connected to the at least one active electrode plate, and a ground metallization is conductively connected to the at least one ground electrode plate, and wherein the ground metallization of the two-terminal chip capacitor is conductively connected to the circuit board ground plate;f) a circuit board first ground via hole extending through the circuit board, wherein at least a portion of the ground pin connected to the ferrule resides in the circuit board first ground via hole where the ground pin is conductively connected to the at least one circuit board ground plate spaced from where the circuit board ground plate is conductively connected to the ground metallization of the two-terminal chip capacitor; andg) a circuit board active via hole extending through the circuit board, but being conductively isolated from the circuit board ground plate, wherein the lead wire second portion extending outwardly beyond the insulator second end surface resides in the circuit board active via hole,h) wherein a ground conductive path comprises the at least one circuit board ground plate being conductively connected to both the ground metallization of the two-terminal chip capacitor and the conductive ground pin residing in the circuit board first ground via hole with the ground pin being connected to the ferrule, andi) wherein an active conductive path extends to the active metallization of the two-terminal chip capacitor and the conductive lead wire second portion residing in the circuit board active via hole. 9. The EMI/energy dissipating filter assembly of claim 8, wherein the at least one circuit board ground plate comprises at least one circuit board internal ground plate residing between the circuit board first and second sides, and wherein the circuit board comprises a circuit board second ground via hole spaced from the circuit board first ground via hole, wherein the ground conductive path comprises the at least one circuit board internal ground plate being conductively connected to both the ground metallization of the two-terminal chip capacitor through the circuit board second ground via hole and to the conductive ground pin residing in the circuit board first ground via hole, the conductive ground pin being connected to the ferrule. 10. The EMI/energy dissipating filter assembly of claim 8, wherein the at least one circuit board ground plate comprises a plurality of circuit board internal ground plates residing between the circuit board first and second sides, and wherein the circuit board comprises a circuit board second ground via hole spaced from the circuit board first ground via hole, wherein the ground conductive path comprises the plurality of circuit board internal ground plates being conductively connected to both the ground metallization of the two-terminal chip capacitor through the circuit board second ground via hole and to the conductive ground pin residing in the circuit board first ground via hole, the conductive ground pin being connected to the ferrule. 11. The EMI/energy dissipating filter assembly of claim 8, wherein the at least one circuit board ground plate comprises a circuit board external ground plate at least partially residing on the circuit board first side, and wherein the ground conductive path comprises the circuit board external ground plate being conductively connected to both the ground metallization of the two-terminal chip capacitor and the conductive ground pin residing in the circuit board first ground via hole, the conductive ground pin being connected to the ferrule. 12. The EMI/energy dissipating filter assembly of claim 8, wherein the at least one circuit board ground plate comprises both a circuit board internal ground plate residing between the circuit board first and second sides and a circuit board external ground plate at least partially residing on the circuit board first side, the circuit board comprising a circuit board second ground via hole spaced from the circuit board first ground via hole, and wherein the ground conductive path comprises the circuit board internal and external ground plates being conductively connected to both the ground metallization of the two-terminal chip capacitor adjacent to the circuit board second ground via hole and to the conductive ground pin residing in the circuit board first ground via hole, the conductive ground pin being connected to the ferrule. 13. The EMI/energy dissipating filter assembly of claim 8, wherein there are: a) a plurality of spaced apart conductive ground pins that are conductively and mechanically connected to the ferrule by respective first gold brazes; andb) a plurality of two-terminal chip capacitors disposed on or adjacent to the circuit board, andc) wherein the ground conductive path comprises the at least one circuit board ground plate being conductively connected to both the ground metallization of each of the plurality of two-terminal chip capacitors and to the plurality of conductive ground pins residing in respective circuit board first ground via holes, the plurality of conductive ground pins being connected to the ferrule. 14. The EMI/energy dissipating filter assembly of claim 8, wherein at least a portion of the conductive ground pin resides in a ferrule countersink. 15. The EMI/energy dissipating filter assembly of claim 8, wherein the two-terminal chip capacitor is a two-terminal MLCC chip capacitor. 16. The EMI/energy dissipating filter assembly of claim 8, wherein the two-terminal chip capacitor is selected from the group consisting of a monolithic ceramic capacitor, a wet tantalum capacitor, an aluminum electrolytic capacitor, a stacked film capacitor, and combinations thereof. 17. The EMI/energy dissipating filter assembly of claim 8, wherein the two-terminal chip capacitor has a cross-sectional shape selected from the group consisting of rectangular, cylindrical, and round. 18. The EMI/energy dissipating filter assembly of claim 8, wherein the at least one circuit board ground plate is selected from the group consisting of a circuit board ground shield plate, a circuit board ground electrode plate, and a circuit board ground circuit trace. 19. The EMI/energy dissipating filter assembly of claim 8, wherein the active conductive path extending to the active metallization of the two-terminal chip capacitor comprises a conductive connection to the third gold braze hermetically sealing the lead wire in the insulator passageway. 20. The EMI/energy dissipating filter assembly of claim 8, wherein the active conductive path comprises a conductive connection to: a) the active metallization of the two-terminal chip capacitor;b) the conductive lead wire second portion residing in the circuit board active via hole; andc) the third gold braze hermetically sealing the conductive lead wire in the insulator passageway. 21. The EMI/energy dissipating filter assembly of claim 20, wherein the conductive connection comprises at least one of the group consisting of a circuit board active trace, a circuit board active plate, and a circuit board active electrode. 22. A filtered feedthrough assembly for an active implantable medical device, the filtered feedthrough assembly comprising: a) an electrically conductive ferrule comprising a ferrule opening, wherein at least one conductive ground pin is conductively and mechanically connected to the ferrule by a first gold braze, and wherein the ferrule is configured to be attachable to an opening in a housing of an active implantable medical device (AIMD);b) an insulator at least partially residing in the ferrule opening where a second gold braze hermetically seals the insulator to the ferrule, wherein at least one insulator passageway extends through the insulator to an insulator body fluid end surface adjacent to a ferrule body fluid side outside the AIMD and an insulator device end surface adjacent to a ferrule device side inside the AIMD;c) an electrically conductive lead wire residing in the at least one insulator passageway in nonconductive relation with the ferrule where a third gold braze hermetically seals the lead wire to the insulator, the lead wire extending from a lead wire first portion to a lead wire second portion, wherein at least the lead wire second portion extends outwardly beyond the insulator device end surface;d) a circuit board comprising spaced apart circuit board first and second sides, wherein the circuit board first side is adjacent to the ferrule device side and the insulator device end surface, and wherein a circuit board internal ground conductive path resides between the circuit board first and second sides;e) a circuit board first ground via hole and a circuit board second ground via hole, both circuit board ground via holes extending to the circuit board internal ground conductive path; andf) at least one two-terminal chip capacitor disposed on the circuit board, the two-terminal chip capacitor comprising a chip capacitor dielectric supporting at least one active electrode plate interleaved in a capacitive relationship with at least one ground electrode plate, wherein an active metallization is conductively connected to the at least one active electrode plate, and a ground metallization is conductively connected to the at least one ground electrode plate of the two-terminal chip capacitor,g) wherein: i) the ground metallization of the two-terminal chip capacitor is conductively connected to a circuit board external ground conductive path at least partially residing in the circuit board first ground via hole, the circuit board external ground conductive path comprising at least one of the group consisting of a circuit board land, a circuit board trace, and a via hole metallization, andii) the circuit board external ground conductive path residing in the circuit board first ground via hole is conductively connected to the circuit board second ground via hole by the circuit board internal ground conductive path, andiii) at least a portion of the ground pin, which is connected to the ferrule by the first gold braze, resides in the circuit board second ground via hole where the ground pin is conductively connected to the circuit board internal ground conductive path, andh) wherein an active conductive path extends to: A) the conductive lead wire second portion extending outwardly beyond the insulator device end surface, andB) the active metallization of the at least one two-terminal chip capacitor. 23. The filtered feedthrough assembly of claim 22, wherein the circuit board internal ground conductive path comprises at least one circuit board internal ground plate residing between the circuit board first and second sides and being conductively connected to both the ground metallization of the two-terminal chip capacitor through the circuit board external ground conductive path residing in the circuit board first ground via hole and to the conductive ground pin residing in the circuit board second ground via hole, the conductive ground pin being connected to the ferrule. 24. The filtered feedthrough assembly of claim 22, wherein at least a portion of the conductive ground pin resides in a ferrule countersink. 25. The filtered feedthrough assembly of claim 22, wherein the two-terminal chip capacitor is a two-terminal MLCC chip capacitor. 26. The filtered feedthrough assembly of claim 22, wherein the two-terminal chip capacitor is selected from the group consisting of a monolithic ceramic capacitor, a wet tantalum capacitor, an aluminum electrolytic capacitor, a stacked film capacitor, and combinations thereof. 27. The filtered feedthrough assembly of claim 22, wherein the two-terminal chip capacitor has a cross-sectional shape selected from the group consisting of rectangular, cylindrical or round. 28. The filtered feedthrough assembly of claim 22, wherein the circuit board internal ground conductive path is selected from the group consisting of at least one of a circuit board ground shield plate, a circuit board ground electrode plate, and a circuit board ground circuit trace. 29. The filtered feedthrough assembly of claim 22, wherein there are: a) a plurality of spaced apart conductive ground pins that are conductively and mechanically connected to the ferrule by respective first gold brazes; andb) a plurality of two-terminal chip capacitors disposed on or adjacent to the circuit board, andc) wherein the circuit board internal ground conductive path comprises at least two circuit board internal ground plates residing between the circuit board first and second side, the at least two circuit board internal ground plates being conductively connected to both the ground metallization of each of the plurality of two-terminal chip capacitors through a circuit board external ground conductive path residing in a respective circuit board first ground via hole and to the plurality of conductive ground pins residing in a respective circuit board second ground via hole, the plurality of conductive ground pins being connected to the ferrule.