A butt closure base includes a base housing extending along a longitudinal axis between a first outer surface and a second outer surface, the base housing defining a plurality of cavities between the first and second outer surfaces, the plurality of cavities aligned in an annular array. A first gel is disposed in each of the plurality of cavities. The butt closure base further includes a plurality of wedge assemblies, each of the plurality of wedge assemblies removably insertable into one of the plurality of cavities. Each of the plurality of wedge assemblies includes an outer cover, a second gel, and a main pressure plate in contact with the second gel. The main pressure plate is movable along the longitudinal axis to apply pressure to the second gel.

A gel sealing device includes a gel sealing block (5) which provides a sealing section (22) through which the elongate parts (13, 14) extend. The gel sealing block (5) includes an upper flange (11) and a lower flange (12) with a support section (11a, 12a, 12b) disposed therebetween. The upper and lower flanges (11, 12) sandwiches, in direction of extension of the elongate parts (13, 14), a gel inner ring (7) supported by said support section (2) and a gel outer ring (6, 10a) covering the gel inner ring (7) in a radial direction extending transverse to said extension direction. The gel inner ring (7) and the gel outer ring (6, 10a) are made of a gel sealing material.

An electrical connection box includes a case including a frame that holds electronic components and a cover that blocks an opening portion of the frame, a power supply connection portion provided inside the case, an external power supply being connected to the power supply connection portion, and a cover portion that covers the power supply connection portion from above, in which the cover portion has a hole portion that communicates a space portion on a side of the power supply connection portion with respect to the cover portion with a space portion above the cover portion inside the case, and is configured to detachably hold a component.

An electrical connection box includes a case including a frame that holds electronic components and a cover that blocks an opening portion of the frame, a power supply connection portion provided inside the case, an external power supply being connected to the power supply connection portion, and a cover portion that covers the power supply connection portion from above, in which the cover portion has a hole portion that communicates a space portion on a side of the power supply connection portion with respect to the cover portion with a space portion above the cover portion inside the case, and is configured to detachably hold a component.

This installation has at least one electric cable (12) having three conductors. At least one cable duct contains at least one section of the cable (12) and at least one connection chamber (10) in which two sections of the cable (12) are connected by means of a connection joint (14). The cable (12) is a helical assembly of the three conductors which comprises neither armouring nor sheath around this assembly.

A transition joint which blocks insulating oil by connecting a three core HPFF cable and a three core XLPE cable is provided. The transition joint includes three epoxy units which connect independently three first cable cores constituting the three core HPFF cable and three second cable cores constituting the three core XLPE cable, respectively. Each of the epoxy units includes a center electrode connecting an electrode of the first cable core and an electrode of the second cable core, and an epoxy molding part implemented in the form of surrounding an outer wall of the center electrode in order to block the center electrode from the insulating oil.

The present disclosure relates to an electrical cable assembly with a connector, in particular a trunk line cable assembly for a photovoltaic system, and to an assembly consisting of a module inverter and the trunk line cable assembly connected thereto, and also relates to a photovoltaic system comprising a plurality of photovoltaic modules and module inverters and AC side cabling between the module inverters and the trunk line cable assemblies, wherein the drop lines are connected to the trunk line cable by means of the connector, wherein the junction is enclosed by a two-piece connector housing which includes strain relief means for the trunk line cable and is optionally additionally overmolded.

The present disclosure relates to an electrical cable assembly with a connector, in particular a trunk line cable assembly for a photovoltaic system, and to an assembly consisting of a module inverter and the trunk line cable assembly connected thereto, and also relates to a photovoltaic system comprising a plurality of photovoltaic modules and module inverters and AC side cabling between the module inverters and the trunk line cable assemblies, wherein the drop lines are connected to the trunk line cable by means of the connector, wherein the junction is enclosed by a two-piece connector housing which includes strain relief means for the trunk line cable and is optionally additionally overmolded.

A connection assembly includes an adapter to be mounted to a rear part of a subsea sensor, a sensor port being located in the adapter, through which at least a first and a second sensor connection are led to the subsea sensor; a first port for providing a connection to a first of the subsea cables; and a second port for providing a connection to a second of the subsea cables. A first penetrator is arranged in the first port to provide a liquid tight seal between an interior space of the adapter and a duct connected to the first port leading the first sensor connection through the first port, and a second penetrator is arranged in the second port providing a liquid tight seal between the interior space of the adapter and a duct connected to the second port and leading the second sensor connection through the second port.

A connection assembly includes an adapter to be mounted to a rear part of a subsea sensor, a sensor port being located in the adapter, through which at least a first and a second sensor connection are led to the subsea sensor; a first port for providing a connection to a first of the subsea cables; and a second port for providing a connection to a second of the subsea cables. A first penetrator is arranged in the first port to provide a liquid tight seal between an interior space of the adapter and a duct connected to the first port leading the first sensor connection through the first port, and a second penetrator is arranged in the second port providing a liquid tight seal between the interior space of the adapter and a duct connected to the second port and leading the second sensor connection through the second port.