A self-centering ceramic washer is positioned between a feedthrough and a filter circuit board. The washer has openings through which first and second terminal pins extend. A first opening has an inner arcuate portion contacting the first terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. A second opening has an inner arcuate portion contacting the second terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. In an imaginary configuration with the first and second washer openings superimposed one on top of the other, the cumulative arcuate distance of the inner arcuate portions about one of the terminal pins, subtracting overlap, results in a gap between the superimposed washer openings that is less than a diameter of the first and second terminal pins so that the washer is prevented from lateral movement.

A self-centering ceramic washer is positioned between a feedthrough and a filter circuit board. The washer has openings through which first and second terminal pins extend. A first opening has an inner arcuate portion contacting the first terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. A second opening has an inner arcuate portion contacting the second terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. In an imaginary configuration with the first and second washer openings superimposed one on top of the other, the cumulative arcuate distance of the inner arcuate portions about one of the terminal pins, subtracting overlap, results in a gap between the superimposed washer openings that is less than a diameter of the first and second terminal pins so that the washer is prevented from lateral movement.

A self-centering ceramic washer is positioned between a feedthrough and a filter circuit board. The washer has openings through which first and second terminal pins extend. A first opening has an inner arcuate portion contacting the first terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. A second opening has an inner arcuate portion contacting the second terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. In an imaginary configuration with the first and second washer openings superimposed one on top of the other, the cumulative arcuate distance of the inner arcuate portions about one of the terminal pins, subtracting overlap, results in a gap between the superimposed washer openings that is less than a diameter of the first and second terminal pins so that the washer is prevented from lateral movement.

The present invention concerns a corrosion-resistant terminal (10) before being crimped to an aluminum wire (40) in which a core (41) is covered with a coating (42) and the corrosion-resistant terminal (10) includes a wire barrel (31) to be crimped to the core (41) exposed by removing the coating (42), an insulation barrel (32) to be crimped to the coating (42), and an anticorrosive (50) applied in advance to a surface of the insulation barrel (32) to be held in contact with the coating (40). According to such a configuration, since the anticorrosive (50) is applied in advance to the surface of the insulation barrel (32) to be held in contact with the coating (42) of the aluminum wire (40), the anticorrosive 50 can be filled between the insulation barrel (32) and the coating (42) of the aluminum wire (40) when crimping is performed.

The present invention concerns a corrosion-resistant terminal (10) before being crimped to an aluminum wire (40) in which a core (41) is covered with a coating (42) and the corrosion-resistant terminal (10) includes a wire barrel (31) to be crimped to the core (41) exposed by removing the coating (42), an insulation barrel (32) to be crimped to the coating (42), and an anticorrosive (50) applied in advance to a surface of the insulation barrel (32) to be held in contact with the coating (40). According to such a configuration, since the anticorrosive (50) is applied in advance to the surface of the insulation barrel (32) to be held in contact with the coating (42) of the aluminum wire (40), the anticorrosive 50 can be filled between the insulation barrel (32) and the coating (42) of the aluminum wire (40) when crimping is performed.

A sealed electrical enclosure for housing an electrical component is provided. In one exemplary embodiment, the sealed electrical enclosure includes a housing, a first and second electrical connector, an actuator, and a terminal. The housing has a sealed interior when a top portion is coupled to a bottom portion. The first electrical connector extends from the sealed interior through the bottom of the housing and is electrically coupled to the electrical component. The actuator extends from the sealed interior through the housing and is configured to manipulate the electrical component. The terminal is electrically coupled to the second electrical connector. The second electrical connector is configured to mate with the first electrical connector. The first and second electrical connectors are configured to be connected and disconnected to attach and remove the housing to and from the terminal.

A sealed electrical enclosure for housing an electrical component is provided. In one exemplary embodiment, the sealed electrical enclosure includes a housing, a first and second electrical connector, an actuator, and a terminal. The housing has a sealed interior when a top portion is coupled to a bottom portion. The first electrical connector extends from the sealed interior through the bottom of the housing and is electrically coupled to the electrical component. The actuator extends from the sealed interior through the housing and is configured to manipulate the electrical component. The terminal is electrically coupled to the second electrical connector. The second electrical connector is configured to mate with the first electrical connector. The first and second electrical connectors are configured to be connected and disconnected to attach and remove the housing to and from the terminal.

A heat dissipation device is presented for an electrical meter socket. The heat dissipation device includes a conduit with a first end configured to be mounted to a first opening in a housing of the electrical meter socket. The heat dissipation device includes a vent cap to cover a second end of the conduit, and may include one or more optional apertures to dissipate heat from the electrical meter socket. The heat dissipation device can also include mesh or screen to keep insects out of the device. An electrical meter socket system is also presented, including the electrical meter socket a heat dissipation device and a connector to connect the device to an opening in a housing of the socket. A method is also presented, for dissipating heat from an electrical meter socket.

A heat dissipation device is presented for an electrical meter socket. The heat dissipation device includes a conduit with a first end configured to be mounted to a first opening in a housing of the electrical meter socket. The heat dissipation device includes a vent cap to cover a second end of the conduit, and may include one or more optional apertures to dissipate heat from the electrical meter socket. The heat dissipation device can also include mesh or screen to keep insects out of the device. An electrical meter socket system is also presented, including the electrical meter socket a heat dissipation device and a connector to connect the device to an opening in a housing of the socket. A method is also presented, for dissipating heat from an electrical meter socket.

A coupling device for an electrical connector that includes a connector shell that has a ratchet engagement and an inner coupling member that has actuating end through which the shell extends. An outer surface of the inner member at the actuating end includes a first locking guide. A spring ratchet member is received in a cavity of the inner member and is configured to engage the ratchet engagement of the shell. An outer sleeve is disposed over the inner member and has an inner surface that has a second locking guide that cooperates with the first locking guide and has a decoupling member. Rotating the outer sleeve in a mating direction rotates the inner member in the mating direction, thereby allowing the ratchet member to engage the ratchet engagement of the shell in a one-way ratchet and preventing the inner member from rotating in an unmating direction.