Telecommunications closures and systems and associated methods of moving or lifting the telecommunications closures. The closures are provided with one or more protruding gripping features which can be gripped by hand and/or with a tool in order to move or lift the closure without having to grip a telecommunications cable entering the closure.

The invention relates to a strain relief for a cable harness, which is used to connect a part to electrical and/or electronic components, wherein the cable harness has at least two wires and wherein a stop component, is provided, which is made of plastic and tightly encloses the wires such that the stop component (20) is fixed immovably on the wires. The invention also relates to a part with a housing, a cable harness, which is guided into the housing, and a strain relief according to one of the preceding claims, wherein the housing has a receiver for the stop component, in which the latter is received in a positively-locking manner in at least one tensile direction.

A cable connecting structure includes three three-phase power cable pairs respectively including a pair of power cables that are mutually connected, three insulating rubber connecting tubes covering connecting sections of the three three-phase power cable pairs, respectively, a steel pipe accommodating portions of each of the three three-phase power cable pairs, and the three rubber connecting tubes, and a heat dissipation material. The heat dissipation material is provided between the steel pipe and each of the three rubber connecting tubes, and makes contact with the steel pipe and each of the three rubber connecting tubes. The heat dissipation material includes a heat dissipating metal that has a melting point lower than a melting point of the steel pipe.

A wiring structure (10) includes: a fixed member (14); a movable member (12) which moves rectilinearly with respect to the fixed member (14); a wire material (16) which connects the movable member (12) and the fixed member (14); a movable guide (18) over which the wire material (16) is stretched and which can move rectilinearly with respect to the fixed member (14); and a movement mechanism (20) which causes the movable guide (18) to move, in conjunction with the rectilinear movement of the movable member (12), rectilinearly in a direction in which the loosening or tightening of the wire material (16) caused by the rectilinear movement of the movable member (12) is offset.

The invention relates to an attenuation element and to a cable including an attenuation element. The attenuation element includes a resiliently deformable body having a first end and a second end opposite the first end. The body has a length that is defined by the distance between the first end and the second end in a direction parallel to a longitudinal axis of the body. The body has at least one cavity, which extends from the first end to the second end. The at least one cavity is provided in the body in such a way that the length of the at least one cavity is greater than the geometric length.

The invention relates to an attenuation element and to a cable including an attenuation element. The attenuation element includes a resiliently deformable body having a first end and a second end opposite the first end. The body has a length that is defined by the distance between the first end and the second end in a direction parallel to a longitudinal axis of the body. The body has at least one cavity, which extends from the first end to the second end. The at least one cavity is provided in the body in such a way that the length of the at least one cavity is greater than the geometric length.

A wire holding member is a wire holding member for holding a wire in which an outer circumference of a core wire is covered by an insulating covering, the wire holding member including: a front wall that includes an insertion hole having an inner diameter larger than an outer diameter of the core wire so as to allow the core wire to be passed therethrough; an upper extending piece and a lower extending piece that extend rearward from a plurality of different end edges of the front wall, and that are to be disposed around the insulating covering; and an upper holding portion and a lower holding portion that protrude from rear end portions of the upper extending piece and the lower extending piece toward the insulating covering, and that clamp an outer surface of the insulating covering, wherein at least the upper and lower extending pieces and the upper and lower holding portions are made of a metal.

A splice assembly for engaging a conductor includes a brush configured to engage the conductor. The brush includes a housing having a first portion and a second portion. The housing defines a housing axis extending between the first portion and the second portion. The first portion defines a cavity having an open end. The second portion defines a bore. A diameter of the cavity is larger than a diameter of the bore. The cavity and the bore are configured to receive the conductor therethrough. The brush further includes a brush member secured within the cavity and positioned proximate the open end.

Grounding assemblies for cables entering telecommunications enclosures. The grounding assemblies include a cable fixation subassembly and a grounding subassembly that are electrically coupled together to ground strength members and a conductive shield of a cable. The cable fixation subassembly can fixate the cable such that the strength members lie in a plane that is at a non-zero angle relative to each of a horizontal reference plane and a vertical reference plane.

An offshore system including: a dynamic submarine power cable, a bend stiffener having a lower end and a top end, the bend stiffener having a central channel extending from the lower end to the top end, the central channel receiving the dynamic submarine power cable with a radial spacing between an inner surface of the central channel and an outer surface of the dynamic submarine power cable along the length of the dynamic submarine power cable arranged in the bend stiffener, the radial spacing forming a longitudinal water channel between the bend stiffener and the dynamic submarine power cable, and an offshore structure tube connected to the bend stiffener, wherein the offshore structure tube has an inner tube channel in fluid communication with the longitudinal water channel, and wherein A) the offshore structure tube has a through-opening extending from the inner tube channel through a wall of the offshore structure tube to enable water flowing from the lower end through the bend stiffener to exit the offshore structure tube via the through-opening to provide water cooling of the dynamic submarine power cable in the bend stiffener, or B) the bend stiffener has a radial through-opening arranged within of a total axial length of the bend stiffener, defined by a distance between the lower end and the top end, from the top end to enable water flowing from the lower end through the bend stiffener to exit the bend stiffener via the radial through-opening to provide water cooling of the dynamic submarine power cable in the bend stiffener.