A plug contact for an electrical charging connector includes: a contact element having a contact area with at least one spring-loaded contact means, and a connection area for connecting an electrical conductor; a cooling element arranged at least in some areas around the contact area; and a heat-conducting element arranged between the cooling element and the contact element. The heat-conducting element is elastic and thermally and mechanically contacts the cooling element and the contact element.

A temperature probe assembly for a cooking appliance includes a receiving body that has a perimeter wall and a recessed surface that is defined by the perimeter wall. The recessed surface includes a plurality of pins. A first coupling member is operably coupled to the recessed surface of the receiving body. A connector is selectively and rotatably coupled to the receiving body. The connector has a body and a plurality of rings disposed on the body. A second coupling member is operably coupled to the body of the connector proximate to the plurality of rings. A temperature probe is operably coupled to the connector via a wire.

An electrical connector for charging has a connector base, a first conductive terminal, a second conductive terminal, and an insulation base. The first conductive terminal is mounted in the connector base and has an upper chamber and a lower chamber. The second conductive terminal is located in and coaxial with the first conductive terminal and is electrically isolated from the first conductive terminal. The insulation base is mounted between the first and the second conductive terminals. An end of the second conductive terminal is located in the upper chamber and another end protrudes out of a bottom of the insulation base. The insulation base has at least one first groove lower than an imaginary datum plan and at least one platform higher than the imaginary datum plane and coaxial with the first groove. By the first groove and the platform, the creepage distance is increased.

An electrical connector for charging has a connector base, a first conductive terminal, a second conductive terminal, and an insulation base. The first conductive terminal is mounted in the connector base and has an upper chamber and a lower chamber. The second conductive terminal is located in and coaxial with the first conductive terminal and is electrically isolated from the first conductive terminal. The insulation base is mounted between the first and the second conductive terminals. An end of the second conductive terminal is located in the upper chamber and another end protrudes out of a bottom of the insulation base. The insulation base has at least one first groove lower than an imaginary datum plan and at least one platform higher than the imaginary datum plane and coaxial with the first groove. By the first groove and the platform, the creepage distance is increased.

The present disclosure provides a concentric conductor for conducting electrical power from a source to a receiving system or load. The concentric conductor includes one or more conducting tubes interior to an outer tube, extending concentrically around a central axis. The conducting tubes are affixed a head-end interface and a connector assembly at either end of the concentric conductors.

A work machine powered electrically by a conductor rod contacting power rails along a haul route. The conductor rod has a central passageway coupling a head to a tip. A barrel extending from the head and an arm extending from the tip have concentric tubular conductors radially offset from each other and slidably mated together. The concentric tubular connectors maintain physical and electrical contact as the conductor rod extends and contracts so that contact with electrical power is maintained despite lateral movements caused by steering or road conditions.

A work machine, such as a hauler at a mining site, includes a conductive linkage connected to a conductor rod for receiving multiple poles of electrical power from a current collector sliding on a surface of a power rail. The conductive linkage includes trailing arms substantially parallel to each other and attached by lower joints to the current collector and by upper joints to the conductor rod. The lower joints and the upper joints have multiple axes of rotation and enable the trailing arms to move laterally and vertically with respect to the surface of the at least one power rail in response to movement of the work machine, while conducting the electrical power from the current collector to the conductor rod.

Devices and systems having a plug and socket connection for resisting or preventing liquid, moisture, vapor, and the like, from contacting the internal electrical circuitry, is provided. Such an electrical device includes a power source socket coupled to a connector and a cap seal coupled to the connector. The power source socket further includes power source wires and the connector includes power distribution wires. The connections between the power source socket and the connector, between each pair of connectors, and between the connector and the cap seal are sealed to exclude moisture/liquid from causing shorting, as is described in more detail below.

A work machine, such as a hauler at a mining site, includes a conductor rod housing concentric metal tubes for receiving electrical power from a contactor sliding on a power rail. A connection assembly includes lugs branching orthogonally from respective ones of the concentric metal tubes to an exterior of the conductor rod. The lugs include ball-and-socket joints configured to enable semi-spherical movement of the lugs at the exterior with respect to the joints. When attached to the contactor via conductive arms, the connection assembly provides multiple degrees of freedom for the conductor rod relative to the contactor and avoids detachment of the contactor from the power rail.

A shield terminal includes a first outer conductor and a second outer conductor. The first outer conductor includes a barrel portion that is electrically connected to a shield portion of an electric wire, and an engaging portion capable of engaging with a housing, and the second outer conductor includes a main body portion and an extension portion extending rearward from the main body portion. A rear end portion of the extension portion is sandwiched between the barrel portion and the electric wire. A fastener portion is formed on a front side of the second outer conductor relative to the rear end of the extension portion, and a fastening portion capable of coming into contact with the fastener portion in a direction of rotation about the engaging portion is formed forward of the engaging portion of the first outer conductor.