Abstract: A telecommunication optical fiber cable possesses a longitudinal central cavity that receives micromodules of optical fibers positioned in parallel. A jacket surrounds the central cavity and a sheath is positioned on the inner periphery of the jacket. A lubricant is provided in the central cavity. The cable, which may contain more than 100 optical fibers, is suitable for an outdoor installation and enables a micromodule to be extracted over substantial lengths.

Abstract: A cutter tool for cutting at least one optical fiber arranged freely in a cavity of a telecommunications cable, the tool including a cutting element and a tube, the cutting element being adapted to form a snare around at least one optical fiber to be cut, the snare providing two strands of filament adapted to be introduced in the tube, and the tool enabling an optical fiber branch connection to be made over a long distance through an existing tapping window.

Abstract: A telecommunication optical fiber cable possesses a longitudinal central cavity that receives micromodules of optical fibers positioned in parallel. A jacket surrounds the central cavity and a sheath is positioned on the inner periphery of the jacket. A lubricant is provided in the central cavity. The cable, which may contain more than 100 optical fibers, is suitable for an outdoor installation and enables a micromodule to be extracted over substantial lengths.

Abstract: Disclosed is a method accessing one or more optical fibers in a telecommunication cable in a way that considerably reduces the risk of damaging the optical fibers. To avoid inadvertent damage caused by a cutting tool, the method includes moving optical fibers and/or micromodules away from the area on the cable that is to be cut.

Abstract: Disclosed is a method accessing one or more optical fibers in a telecommunication cable in a way that considerably reduces the risk of damaging the optical fibers. To avoid inadvertent damage caused by a cutting tool, the method includes moving optical fibers and/or micromodules away from the area on the cable that is to be cut.

Abstract: A conductor module (M) comprises a jacket (E) tightly accommodating, in the manner of tubing, at least two flexible conductors (C). The conductors (C) are coated with a small amount of oil (H) having a viscosity strictly less than 100 millipascal second (mPa.s) so as to allow control of the slippage of the jacket (E) in relation to the conductors (C) and longitudinal impenetrability inside the module (M).

Abstract: The invention relates to the field of processes for the production of an optical transmission cable as well as to the apparatus for carrying out such a process. The method is a process for producing an optical transmission cable from at least one tube (1) inside of which a plurality of optical fibers (2) are arranged, and strengthening elements (3, 4, 5), one of the said strengthening elements, constituting a central strengthening member (4), being arranged at the center of said cable and certain strengthening elements constituting peripheral strengthening members (3), said tube (1) being twisted about said central strengthening member (4) using a tubular machine so as to form a peripheral layer around said central strengthening member (4), the peripheral strengthening members (3) and the tube (1) having diameters sufficiently close to each other to ensure said peripheral layer is homogeneous.

Abstract: The invention relates to a cable having a substantially gastight metal tube receiving at least one optical conductor and a hydrogen-absorbent substance. The inside face of the tube is covered with a layer of a catalyst substance such as nickel or chromium for catalyzing the reaction whereby the hydrogen-absorbent substance absorbs hydrogen. Said layer is itself covered with at least one layer of hydrogen-absorbent substance which constitutes a filler material for filling the tube, or which merely forms a layer deposited on the layer of catalyst substance.

Abstract: The invention relates to the field of processes for the production of an optical transmission cable as well as to the apparatus for carrying out such a process. The method is a process for producing an optical transmission cable from at least one tube (1) inside of which a plurality of optical fibers (2) are arranged, and strengthening elements (3, 4, 5), one of the said strengthening elements, constituting a central strengthening member (4), being arranged at the center of said cable and certain strengthening elements constituting peripheral strengthening members (3), said tube (1) being twisted about said central strengthening member (4) using a tubular machine so as to form a peripheral layer around said central strengthening member (4), the peripheral strengthening members (3) and the tube (1) having diameters sufficiently close to each other to ensure said peripheral layer is homogeneous.

Abstract: The invention relates to the field of electrical insulators, and in particular to the field of electrical insulators for optical phase conductors (OPPCs). The electrical insulator comprises a dielectric rod (1) having at least one slot (10), a flexible optical fiber cable (2) situated in the slot (10), a dielectric material (8) filling the slot (10) and holding the cable (2) in the slot (10) without stressing it, and a dielectric covering (3) surrounding the rod (1) and presenting outwardly-directed projections (30) in the form of skirts, the entire space situated between the rod (1) and the cable (2) being filled with said dielectric filler and holding material (8).

Abstract: A conductor module (M) comprises a jacket (E) tightly accommodating, in the manner of tubing, at least two flexible conductors (C). The conductors (C) are coated with a small amount of oil (H) having a viscosity strictly less than 100 millipascal second (mPa.s) so as to allow control of the slippage of the jacket (E) in relation to the conductors (C) and longitudinal impenetrability inside the module (M).

Abstract: The invention relates to the field of electrical insulators, and in particular to the field of electrical insulators for optical phase conductors (OPPCs). The electrical insulator comprises a dielectric rod (1) having at least one slot (10), a flexible optical fiber cable (2) situated in the slot (10), a dielectric material (8) filling the slot (10) and holding the cable (2) in the slot (10) without stressing it, and a dielectric covering (3) surrounding the rod (1) and presenting outwardly-directed projections (30) in the form of skirts, the entire space situated between the rod (1) and the cable (2) being filled with said dielectric filler and holding material (8).

Abstract: A telecommunications or power transport cable is structurally reinforced by incorporating at least one reinforcing wire or armoring having one or more layers of wires. The cable includes at least one reinforcing wire or armoring wire and/or optionally a tube made out of a composite steel having a steel core of a standard type covered in a layer of stainless steel.

Abstract: The invention relates to a method of manufacturing a tubular member made of synthetic material, the method being of the type in which the tubular member is extruded. In the method, during extrusion of the tubular member, the extruded synthetic material is subjected to a flow of water in liquid or steam form that comes into contact with the inside or the outside surface of the tubular member in such a manner as to form crevices in the surface of the tubular member that comes into contact with the flow of water. The extruded synthetic material is preferably subjected to a flow of water in liquid form. The surface including the crevices forms a low-friction surface. Application to making optical fiber cable networks in which the cables are inserted into tubes by carrying or blowing methods.

Abstract: The invention relates to a cable having a substantially gastight metal tube receiving at least one optical conductor and a hydrogen-absorbent substance. The inside face of the tube is covered with a layer of a catalyst substance such as nickel or chromium for catalyzing the reaction whereby the hydrogen-absorbent substance absorbs hydrogen. Said layer is itself covered with at least one layer of hydrogen-absorbent substance which constitutes a filler material for filling the tube, or which merely forms a layer deposited on the layer of catalyst substance.

Abstract: The invention relates to a cable having a substantially gastight metal tube receiving at least one optical conductor and a hydrogen-absorbent substance. The inside face of the tube is covered with a layer of a catalyst substance such as nickel or chromium for catalyzing the reaction whereby the hydrogen-absorbent substance absorbs hydrogen. Said layer is itself covered with at least one layer of hydrogen-absorbent substance which constitutes a filler material for filling the tube, or which merely forms a layer deposited on the layer of catalyst substance.

Abstract: The invention relates to a cable having a substantially gastight metal tube receiving at least one optical conductor and a hydrogen-absorbent substance. The inside face of the tube is covered with a layer of a catalyst substance such as nickel or chromium for catalyzing the reaction whereby the hydrogen-absorbent substance absorbs hydrogen. Said layer is itself covered with at least one layer of hydrogen-absorbent substance which constitutes a filler material for filling the tube, or which merely forms a layer deposited on the layer of catalyst substance.

Abstract: The invention relates to an optical fiber cable including an outer sheath containing a plurality of optical fibers separated into at least two optical fiber modules, each of said modules consisting of a module sheath surrounding a respective group of optical fibers. According to the invention, the module sheath is formed by a film of plastics material. The film is, for example, wrapped widthwise around the group of optical fibers, a first face of the film being superposed on and fixed to a second face of the film over a portion of given width of said film.

Abstract: The invention relates to a method of manufacturing a tubular member made of synthetic material, the method being of the type in which the tubular member is extruded. In the method, during extrusion of the tubular member, the extruded synthetic material is subjected to a flow of water in liquid or steam form that comes into contact with the inside or the outside surface of the tubular member in such a manner as to form crevices in the surface of the tubular member that comes into contact with the flow of water. The extruded synthetic material is preferably subjected to a flow of water in liquid form. The surface including the crevices forms a low-friction surface. Application to making optical fiber cable networks in which the cables are inserted into tubes by carrying or blowing methods.

Abstract: A telecommunications or power transport cable is structurally reinforced by incorporating at least one reinforcing wire or armoring comprising one or more layers of wires. The cable includes at least one reinforcing wire or armoring wire and/or optionally a tube made out of a composite steel having a steel core of a standard type covered in a layer of stainless steel.