A connection assembly connects at least two subsea cables to a dual output subsea sensor. An embodiment includes an adapter piece mounted to a rear part of the subsea sensor; a sensor port in the adapter piece, through which at least a first sensor connection and a second sensor connection are led to the subsea sensor; a first and second port for respectively providing a connection to a first and second subsea cable; a first penetrator providing a liquid tight seal between an interior space of the adapter piece and a duct connected to the first port; and a second penetrator providing a liquid tight seal between the interior space of the adapter piece and a duct connected to the second port. The sealing provided by the first and second penetrator preventing fluid communication between the respective duct connected to the first and second port, through the adapter piece.

A cable connector including a connector shell including a support and an insert, wherein the insert includes a surface inclined to a cable-to-face direction of the insert so as to re-direct force applied on a face side of the insert sideways toward sides of the connector shell, and the support includes a surface inclined to the cable-to-face direction of the connector shell so as to react to the force, pushing back on the insert, thereby exerting a compression force on the insert. Related apparatus and methods are also described.

A cable connector including a connector shell including a support and an insert, wherein the insert includes a surface inclined to a cable-to-face direction of the insert so as to re-direct force applied on a face side of the insert sideways toward sides of the connector shell, and the support includes a surface inclined to the cable-to-face direction of the connector shell so as to react to the force, pushing back on the insert, thereby exerting a compression force on the insert. Related apparatus and methods are also described.

The disclosure is related to a system and method for monitoring the integrity of fluid filled connector systems. The system includes a connector with a first space and a first measurement probe. A module or a receptacle is connected to the connector and includes first wiring that is coupled with second wiring in the connector. The module or the receptacle includes a second space in fluid connection with the first space. The first space and the second space include a fluid sealed within. The second space includes a second measurement probe. A measurement device is connected to the first measurement probe and the second measurement probe to determine an impedance value across the first space and the second space. The impedance value corresponds to an integrity measure for the system based at least in part on the fluid sealed within.

An electrical connector includes an insulative housing and a number of conductive contacts affixed to the insulative housing. The insulative housing includes a base portion and a tongue portion extending forwardly from the base portion. The tongue portion has a stepped portion abutting with the base portion, a horizontal portion located at a front end of the stepped portion, and a boundary line located between the stepped portion and the horizontal portion. The stepped portion is thicker than the horizontal portion. The horizontal portion has two opposite mating surfaces. Each conductive contact has a contacting portion exposed to the mating surface, a connecting portion affixed to the stepped portion and the base portion, and a soldering portion extending outwardly from the base portion. The contacting portion abutting with the boundary line is covered by insulative materials.

A resilient shielding member for a device (10) is disposed in a facing space (300) between a conductive motor case (10) of a motor (100) and an inverter case (201) of an inverter device (200). The resilient shielding member surrounds first terminal fittings (102) and second terminal fittings (202) connecting the motor (100) and the inverter device (200) over the entire circumference and is formed by integrating a waterproofing component (11) configured to resiliently contact the motor case (101) and the inverter case (201) in a liquid-tight manner over the entire circumference and a shielding component (13) configured to conductively contact the motor case (101) and the inverter case (201).

A resilient shielding member for a device (10) is disposed in a facing space (300) between a conductive motor case (10) of a motor (100) and an inverter case (201) of an inverter device (200). The resilient shielding member surrounds first terminal fittings (102) and second terminal fittings (202) connecting the motor (100) and the inverter device (200) over the entire circumference and is formed by integrating a waterproofing component (11) configured to resiliently contact the motor case (101) and the inverter case (201) in a liquid-tight manner over the entire circumference and a shielding component (13) configured to conductively contact the motor case (101) and the inverter case (201).

A power plug with leakage current protection device, which includes a body formed of an upper cover and a base, a core assembly disposed in the body, a cable assembly attached to the body, a plurality of input insertion plates and output moving contact arms which are assembled with the core assembly, and an insertion plate sleeve disposed on the base, where the input insertion plates pass through the insertion plate sleeve to protrude from the base. The insertion plate sleeve is made of an insulating and temperature resistant material. The power plug has a simple overall structure and can be assembled easily and reliably. It can prevent the safety risk caused by high temperature of the input insertion plates without increasing the size of the plug. It also has low cost, and can be suitably employed in various types of power plugs.

A power plug with leakage current protection device, which includes a body formed of an upper cover and a base, a core assembly disposed in the body, a cable assembly attached to the body, a plurality of input insertion plates and output moving contact arms which are assembled with the core assembly, and an insertion plate sleeve disposed on the base, where the input insertion plates pass through the insertion plate sleeve to protrude from the base. The insertion plate sleeve is made of an insulating and temperature resistant material. The power plug has a simple overall structure and can be assembled easily and reliably. It can prevent the safety risk caused by high temperature of the input insertion plates without increasing the size of the plug. It also has low cost, and can be suitably employed in various types of power plugs.

A plug comprises a plug housing, an electrically conductive plug contact disposed in the plug housing, a contact body cooperating with the plug contact, and a slider displaceably guided in a sliding guide formed on the plug housing. The slider has a ramp surface cooperating with the contact body such that the contact body is pushed against the plug contact when the slider is slid into the plug housing.