Abstract: A connector for a conductor of a power cable includes a hollow outer member configured to at least partially surround an exposed section of the conductor and configured to exert a force in an axial direction onto at least one electrically conductive inner member, and at least one electrically conductive inner member configured to be interposed between the outer member and the conductor, and configured to exert a force in a radial direction onto the conductor in response to the force in an axial direction.

Abstract: A system for plugging a fibre optic cable into a fibre optic receptacle includes: a base element having at least one base port, and an adapter unit having at least one adapter, the at least one adapter and the at least one base port being spaced of a predetermined length. The system includes a cable adaptor associated with the fibre optic cable, the cable adaptor including a connector for being plugged into the adapter; an anchoring device for anchoring the fibre optic cable to said base port, and a connector retaining element for receiving the connector and a cable end portion, the connector retaining element defining the predetermined length and removably engaging with the anchoring device. A cable adaptor for a fibre optic cable and a method of installing a fibre optic cable into a fibre optic receptacle, especially into a joint closure, are also described.

Abstract: A cable loop device for use in optical systems may have a front side and a reverse side and may include at least one work area, at least one fiber storage area arranged on the front side, at least one cable storage area disposed on a periphery of the cable loop device, and a guide track configured to route at least one optical fiber between the front side and the reverse side. An optical joint may include one or more base ports disposed through a base of the optical joint and at least one cable loop device mounted within the optical joint. An optical network may include one or more optical cables and at least one optical joint.

Abstract: An adapter device for applying a fiber-optic monitoring system to a component to be monitored includes a shell adapted to surround the component to be monitored, the shell having a rounded exposed surface onto which a first optical fiber of the fiber-optic monitoring system can be wrapped.

Abstract: A pressure relief valve for blown fiber closures is provided having constituent components fabricated from plastic. An adaptor is provided for connection to a blown fiber closure, and a body welded to this adaptor, is provided to enclose a piston and a spring within, such that they are protected from the ingress of silt and water. The piston is arranged to provide a double seal such that a pressure relief valve plug and an opening in the enclosing body are closed or opened simultaneously to prevent the ingress of silt and/or water on the one hand and the unhindered escape of pressurized fluid on the other.

Abstract: A cable loop device (100) is provided for use in optical systems for storing, routing and distributing optical cables and fibre within optical networks, optical hardware and optical joints thereof. The cable loop device (100) includes one or more work areas (106), one or more fibre storage areas (102), a plurality of guide tracks (120a-120c), and at least one cable storage area (11O), where the at least one cable storage area (110) is disposed on the periphery of the cable loop device (100) for looping optical cable and the fibre guide tracks (120a, 120b) connect the cable storage (110), fibre storage (102) and work (106) areas together. A routing device (300) is provided for use with the cable loop device (100) for routing optical fibre from the routing device (100) through to a third portion of guide tracks (120c) disposed through the cable loop device (100) for splicing to fibres therein.

Abstract: An optical fiber drop cable for suspension installation includes electrical conductors and at least one optical fiber. An electrically non-conductive reinforcing sleeve houses the conductors and the or each optical fiber. The reinforcing sleeve is housed in sheathing. In addition to or instead of the optical fiber or optical fibers, the reinforcing sleeve may house one or more elongate containers, preferably plastic tubes, for housing optical fibers.

Abstract: A method of installing electrical cabling by securing an electrical cable clip to a structure using a fixing element that passes through the clip into the structure, subsequently inserting one or more electrical cables into a cable receiving channel defined by the clip and securing the electrical cables in that channel. The structure will typically be the wall of a building or the like and the fixing element is preferably a nail that is fired through the base portion of the electrical cable clip by means of a nail gun.

Abstract: A method of determining the position of a blockage (192, 392) in a passage (15, 313) having a first end and a second end. The method comprises blowing a sealing device (200) into the passage to form a seal adjacent the blockage (192, 392), then blowing a gas into the passage from the first end, making at least one measurement concerning the gas blown into the passage from the first end and determining a distance D between the first end and the sealing device using the at least one measurement.

Abstract: An optical fiber unit having a sheath and a plurality of optical fiber elements loosely housed in the sheath. The sheath is coated with particles of an adherence reducing substance and has a radial thickness that is not substantially greater than 0.3 mm. The coating of adherence reducing particles is applied as a liquid coating. The liquid coating is a dispersion of the particles and heat is applied to evaporate the liquid content of the liquid coating to produce a dry coating of particles on the sheath.

Abstract: An optical fibre installation includes (i) a part defining an inlet for optical fibres that has a through-hole for the passage of optical fibres and an associated mating region for a push-fit connector, (ii) an optical fibre cable connected to an adapter that defines a connection region having a predetermined cross-section for mating with a push-fit connector and (iii) a push-fit connector having a first end, a second end, a through-passage extending between those ends and a seal associated with the first end. The second end of the push-fit connector is push-fit connected to the connection region of the adapter and the first end of the push-fit connector is push-fit connected with the mating region of the inlets in such a way that the seal sealingly engages the inlet defining part. The arrangement is such that optical fibres from the optical fibre cable can be directed through the push-fit connector and the through-hold of the inlet.

Abstract: An apparatus (12) is provided for use in determining a length at least representative of the length of a tube that defines a passage in an optical fibre cable (10) along which an optical fibre unit can be installed by blowing. The apparatus (12) comprises a pressure reservoir (32) in which a gas at a known pressure can be stored, outlet piping (34) connected with the pressure reservoir (32) and having an outlet end spaced from the reservoir for connection to a tube of the optical fibre cable (10). The apparatus has a pressure detecting arrangement (42) for detecting gas pressure in a tube connected with the outlet end of the outlet piping (34).

Abstract: A method of determining a length Ld at least representative of the length of a passage along which an optical unit or cable is to be installed by blowing, comprises the steps of flowing a pressurised gas into the passage at a substantially constant pressure P1 and substantially constant flow rate Vf until gas pressure within the passage reaches a predetermined level P2. The time period tf during which the pressurised gas was flowed into the passage is determined and then the length Ld is determined by reference to the time period tf.

Abstract: An optical fiber assembly includes: a component defining at least one inlet for optical fibers, an adapter, an optical fiber cable connected to the adapter, and a push-fit connector. The component includes a through-hole for passage of the optical fibers and an associated mating region to engage the push-fit connector. The optical fiber cable connected to the adapter defines a connection region with a predetermined cross-sectional shape for mating with the push-fit connector. The push-fit connector includes a first end, a second end, and a through-passage extending between the first and second ends. The first end is push-fit connected with the mating region. The second end is push-fit connected to the connection region. Optical fibers from the optical fiber cable can be directed through the push-fit connector and the through-hole. A method of installing optical fibers in a joint housing is also disclosed.