Abstract: A power cable joint includes splices and extra-length portions of first and second optical fibers which are included in respective first power cable and second power cable, and a cable joint sleeve (100). The abovementioned splices and extra-length portions are accommodated in an organizer (10) that includes a tray (20) having a recessed area (22) and configured to shapingly fit to an outer surface (101) of the cable joint sleeve (100). In particular, splices and extra-length portions of optical fibers are housed in an upper surface (21) of the tray (20). The organizer (10) further includes a fastener (40) configured to secure the tray (20) to the outer surface (101) of the cable joint sleeve (100) and a cover (50) configured to at least partially cover the upper surface (21) of the tray (20).

Abstract: A splice holder tray has a splice holder section that includes a plurality of inclined channels. Each of the plurality of inclined channels includes a first portion presenting a cross section area that is measured on a reference plane, two opposite lateral openings, and a top opening and a bottom opening. The bottom opening has an area smaller than the cross section area.

Abstract: An optical connector adapter assembly includes a first optical connector including a first optical connector body; an adapter body extending along a longitudinal direction between a first end and a second end, the adapter body defining a passing through channel extending along the longitudinal direction and configured to receive the first optical connector body at the first end and a second optical connector at the second end. The assembly includes a first locking arrangement to lock the first optical connector with respect to the adapter body along the longitudinal direction; the first locking arrangement including one or more locking elements associated with the adapter body and extending inside the passing through channel along the longitudinal direction towards the first end; a locking portion associated with the first optical connector body and configured to engage with the locking elements; and a retaining element arranged outside the first optical connector body.

Abstract: A fiber separation tool is provided. The fiber separation tool includes a fin configured to maintain the fiber separation tool in a parallel orientation with respect to a plurality of fibers, a hook tip at a first end of the fin, wherein the hook tip is configured to separate the plurality of fibers, a blade disposed in the fin above the hook tip, wherein a portion of a cutting edge of the blade protrudes from a blade opening in the fin, and wherein the blade is configured to slice through a bonding material connecting the plurality of fibers, a lip at each side of the blade opening, wherein the lip is configured to prevent individual fibers of the plurality of fibers from contacting the blade, and a pivot point configured to guide the fiber separation tool between the individual fibers.

Abstract: An optical-fiber ribbon includes intermittent gaps along its longitudinal length in which no bonding material is present across the width of the optical-fiber ribbon. These intermittent gaps without bonding material (e.g., adhesive beads) help to reduce or eliminate bonding-material interference as the optical-fiber ribbon is positioned within an alignment chuck during preparations for mass-fusion splicing.

Abstract: An electrical cable for vertical applications includes a core having a length L, a sheath surrounding the core and extending through the whole length L and a reinforcing jacket surrounding the sheath and in direct contact therewith. The reinforcing jacket is made of concentric layers including a first layer longitudinally extending from a first cable end (the proximal or upper cable end, in use) towards a second cable end (the distal or lower cable end, in use) substantially along the whole length L. The reinforcing jacket also includes at least one further layer longitudinally extending from the first cable end towards the second cable end for a length shorter than L. At least one layer of the reinforcing jacket is a circumferentially closed metal tube.

Abstract: A cable contains a core including a transmissive element and a coating layer made of a coating material. The coating material contains, with respect to the total weight of polymeric materials present in the composition, (i) 70% to 95% by weight of a recycled linear low density polyethylene (r-LLDPE); and (ii) 5 to 30% by weight of an ethylene-vinyl acetate copolymer (EVA). The coating layer shows mechanical properties comparable to those of a virgin polymer composition and better, both before and after ageing, than recycled polymer-based compositions containing recycled LLDPE but free from EVA. The EVA may be added to the r-LLDPE or, alternatively, be already contained in the r-LLDPE as a result of previous LLDPE use. The cable may further contain a skin layer placed around and in direct contact with the coating layer based on r-LLDPE.

Abstract: An optical-fiber ribbon includes optical fibers (e.g., reduced-diameter optical fibers) arranged in parallel within optical-fiber units, wherein at least one adjacent pair of optical-fiber units is separated by a longitudinal adhesive-free spacing for a portion of the optical-fiber ribbon's length. Typically, each adjacent pair of optical-fiber units is separated by an adhesive-free spacing for a respective portion of the optical-fiber assembly's longitudinal length. In an exemplary embodiment, longitudinal adhesive-free spacings effectively increase the width of an optical-fiber ribbon formed of reduced-diameter optical fibers so that the optical-fiber ribbon achieves a more conventional optical-fiber ribbon width, thereby facilitating mass-fusion splicing using standard splicing equipment.

Abstract: A fiber management system for managing and distributing optical fibers comprises at least one supporting element, at least one splice tray pivotally mounted on the supporting element around a pivot axis (X), distributing elements for routing incoming fiber modules toward the splice tray and for routing outgoing fiber modules away from the splice tray, the distributing elements being oriented along respective routing directions transverse to the pivot axis. At least one guiding channel is provided on the supporting element for guiding at least the incoming fiber modules toward the splice tray along a direction substantially parallel to the pivot axis (X), and a retention block acts into the guiding channel between a plurality of retention positions wherein each retention position of the retention block defines a respective passageway for the incoming fiber modules.

Abstract: An armoured power cable (10) comprises a cable core (11) and an armour layer (21) comprising a plurality of armouring wires (22) laid around the cable core (11), wherein at least 10% of the armouring wires (22) are wavy wires (23) having a zig-zag shape laying on the outer surface of the cable core (11).

Abstract: High density optical fiber distribution sub-rack comprising: a chassis for housing a plurality of shelves, the chassis comprising at least two shelf storage areas placed side by side with each other, at least one shelf housed in one of the at least two storage areas of the chassis, the at least one shelf having an internal hollow seat for connection modules, the at least one shelf comprising one or more connection modules having a plurality of adapters for interconnection optical fibers, the connection modules being arranged in the internal hollow seat of the at least one shelf at the frontal face of the at least one shelf, wherein the at least one shelf is guided so as to be movable towards the external of the chassis by the succession of a translation movement and a rotation movement of the at least one shelf.

Abstract: The present disclosure relates to an armoured AC cable comprising at least one core comprising an electric conductor, and an armour surrounding the at least one core and comprising ferromagnetic wires, wherein the ferromagnetic wires are permanently magnetized with a remanent magnetic field which is uniform or variable along the cable length L. The present disclosure also relates to a process for producing an armoured AC cable, a method for improving the performances of an armoured AC cable, and a method for reducing losses in an armoured AC cable.

Abstract: A power cable and a process of manufacturing a power cable, where the power cable includes a core containing stranded electrically conductive wires that are impregnated with a water-blocking composition, wherein the water-blocking composition contains, based on a total weight of the water-blocking composition: (i) a thermoplastic polymer; and (ii) a positive amount of up to 30 wt % of a crosslinked polymer, where the crosslinked polymer is in the form of a powder having a particle diameter less than 900 ?m and the crosslinked polymer is dispersed in the thermoplastic polymer.

Abstract: The present invention concerns an optical fibre comprising: an optical waveguide comprising a glass core surrounded by a glass cladding; a coating surrounding said optical waveguide comprising a cured polymer material comprising a polyester obtained by esterification of: a reactant A selected from an acid, a triglyceride, or a mixture of triglycerides having a C16-C24 aliphatic chain comprising at least two conjugated double bonds; and a polyol made of at least one monomer comprising at least 3 hydroxyl groups, the polyol being thermally stable up to 300° C. (reactant B). The present invention concerns also the above said polyester coating, a method for coating an optical fibre with said polyester coating and a method for obtaining predetermined mechanical properties of a coating for an optical fibre. The cured polymer forming the coating can be prepared by curing the polyester of the invention either thermally or by radiation.

Abstract: It is disclosed a method for coupling an optical fiber to a fiber optic cable, the fiber optic cable comprising a sheath surrounding an optical core comprising a buffer tube, the optical fiber being loosely contained in the buffer tube. The method comprises: cutting the sheath for a predetermined length thereof and exposing a corresponding portion of the optical core extending outward beyond a butt of the cut sheath; cutting the buffer tube of the exposed optical core and exposing a portion of the optical fiber; using a blocking tube to at least partially surround a section of the exposed portion of the optical fiber; and injecting a sealant into the blocking tube to lock the optical fiber within the blocking tube and couple the optical fiber to the fiber optic cable.

Abstract: The present invention concerns an electric cable (10; 20) comprising: —an electric conductor (11, 21) surrounded with an electrically insulating layer (12, 22) made from a first polymer composition comprising: (a) polyvinyl chloride as a first polymer matrix, (b) an amount up to 45 phr of a plasticizing system consisting of a phthalate plasticizer and a second plasticizer selected from: dialkyl-adipate, dialkyl-sebacate or dialkyl-azelate, wherein the alkyl group contains from 4 to 10 carbon atoms; the first polymer composition having a limiting oxygen index (LOI) up to 30%; and—an outer sheath (13, 24), surrounding the insulating layer (12, 22), made from a second polymer composition comprising: (i) a halogen-free second polymer matrix; and (ii) a halogen-free inorganic flame-retardant filler in amount suitable to impart flame retardant properties to the outer sheath (13, 24).

Abstract: Disclosed is a fire resistant, all dielectric fiber optic cable with high fiber count. The cable comprises a core including a central strength member and buffer tubes containing fibers, arranged around the central strength member. A first mica layer is arranged around the core. A glass yarn layer surrounds the first mica layer and is in direct contact therewith. A inner sheath surrounds the glass yarn layer. A second mica layer surrounds the inner sheath. An outer sheath surrounds the second mica layer. The buffer tubes contain a water-blocking filling material comprising a silicone gel, wherein said silicone gel has a drop point of at least 200° C.

Abstract: An apparatus for manufacturing glass preforms for optical fibers includes a reaction chamber surrounding a deposition region, a holding device for holding a target rod within said deposition region, one or a plurality of deposition burners positioned below said deposition region and configured to direct a high temperature flow of forming glass particles toward said target rod, a hood positioned opposite to the deposition burners with respect to said holding device and configured for discharging soot of un-deposited glass particles, said hood including at least one exhaust port provided at a first end portion thereof and side panels extending from a second end portion thereof toward said first end portion. At least a portion of the side panels of the hood is gas permeable.

Abstract: A medium voltage electric cable is disclosed the cable comprising: a conductor; an inner semi-conductive layer arranged in a radially outer position with respect to the conductor; an insulating layer arranged in a radially outer position with respect to the inner semi-conductive layer and directly contacting the inner semi-conductive layer; an outer semi-conductive layer arranged in a radially outer position with respect to the insulating layer and directly contacting the insulating layer; a wire metal screen arranged in a radially outer position with respect to the outer semi-conductive layer; a filler layer arranged in a radially outer position with respect to the wire metal screen and interpenetrating within the wire metal screen, the filler layer being made from an extruded elastomeric low smoke zero halogen (LSOH) composition comprising a polyethylene homopolymer and/or copolymer having a density lower than 0.

Abstract: An optical fiber splice enclosure includes a cap enclosing an inner volume, the cap having an access opening for accessing the inner volume. The enclosure includes a base removably attached to the access opening of the cap, the base having one or more ports for access of optical cables into the inner volume, and a fiber routing frame mounted on the base and arranged into the inner volume. The enclosure includes a tubular element arranged in the inner volume and surrounding the fiber routing frame. The tubular element has a first edge portion and a second edge portion, the tubular element including first retaining elements arranged at the first edge portion, and second retaining elements arranged at the second edge portion. The tubular element includes a bottom tubular portion proximate to the base, a top tubular portion distal to the base, and one or more frangible lines.