The present disclosure relates to a power cable and an intermediate connection structure, for connection thereof, which is capable of preventing the concentration of stress on a soldered part, which is configured to join a metal sheath of the power cable and a metal sheath restoration layer of the intermediate connection structure while ensuring airtight or watertight sealing therebetween, preventing deformation of or damage to the soldered part due to stress applied thereto, and minimizing thermal history in the power cable during the formation of the soldered part.

The object of the invention is a protecting device for an elongated flexible member, the protecting device acting as a protection against biting and chewing on the elongated flexible member and being placed on at least a part of the elongated flexible member, wherein the protecting device is a spring made of wire or an array of rings arranged coaxially on a connecting element, the pitch of the spring or the distance between adjacent rings being respectively in the range of 0.05 cm to 5 cm; and an elongated flexible member with a protecting device.

The object of the invention is a protecting device for an elongated flexible member, the protecting device acting as a protection against biting and chewing on the elongated flexible member and being placed on at least a part of the elongated flexible member, wherein the protecting device is a spring made of wire or an array of rings arranged coaxially on a connecting element, the pitch of the spring or the distance between adjacent rings being respectively in the range of 0.05 cm to 5 cm; and an elongated flexible member with a protecting device.

In an electronic cable embodiment, a shielding tape includes a first metallic layer having a first orientation along which micro-fractures are predisposed to form, and a second metallic layer having a second orientation along which micro-fractures are predisposed to form. The first and second orientations have a non-zero transverse relation with respect to each other. An adhesive is disposed between the first and second metallic layers. Metallic solids are dispersed throughout the adhesive so as to define the adhesive with electrically conductive material characteristics.

In an electronic cable embodiment, a shielding tape includes a first metallic layer having a first orientation along which micro-fractures are predisposed to form, and a second metallic layer having a second orientation along which micro-fractures are predisposed to form. The first and second orientations have a non-zero transverse relation with respect to each other. An adhesive is disposed between the first and second metallic layers. Metallic solids are dispersed throughout the adhesive so as to define the adhesive with electrically conductive material characteristics.

Communication cable including insulated conductors and a composite tape having an insulative layer and a conductive layer. The composite tape includes first and second lateral sections that are folded over each other to form a shielding tape. The shielding tape includes opposite inner and outer sides that are formed from the first and second lateral sections, respectively, and a folded edge that joins the inner and outer sides. The conductive layer defines the inner side, the outer side, and the folded edge. The shielding tape is wrapped helically about the insulated conductors a plurality of times along a length of the communication cable to form a plurality of wraps. The inner side of a subsequent wrap of the shielding tape overlaps a portion of the outer side of a prior wrap of the shielding tape.

A high voltage alternative current cable is provided having mechanically reinforced electric conductor, by having a reinforcement member at the centre of the conductors of the cable, where the reinforcement member is made of one or more low or non-magnetic steel wires, one or more wires of CuNiSi precipitation alloy, or one or more aluminium wires made of an EN AW-1xxx, EN AW-2xxx, EN AW-5xxx, AW-6xxx, EN AW-7xxx, or EN AW-8xxx alloy, according to the European aluminium standard.

A high voltage alternative current cable is provided having mechanically reinforced electric conductor, by having a reinforcement member at the centre of the conductors of the cable, where the reinforcement member is made of one or more low or non-magnetic steel wires, one or more wires of CuNiSi precipitation alloy, or one or more aluminium wires made of an EN AW-1xxx, EN AW-2xxx, EN AW-5xxx, AW-6xxx, EN AW-7xxx, or EN AW-8xxx alloy, according to the European aluminium standard.

The objective of the present invention is to prevent a deterioration in communication performance A shielded electrically conductive path (A) is provided with a shielded terminal (25) including an inner conductor (26), and an outer conductor (28) enclosing the inner conductor (26), a shielded electric cable (10) including a core wire (12) affixed to a rear end portion of the inner conductor (26), a braided wire (15) enclosing the core wire (12), and a sheath (18) enclosing the braided wire (15), and a sleeve (20) attached to the outer circumference of a front end portion of the sheath (18), wherein, in the front end portion of the shielded electric cable (10): the braided wire (15) extending from a front end (18F) of the sheath (18) is folded back toward the rear to cover the outer circumference of the sleeve (20); a crimping portion (30) of the rear end portion of the outer conductor (28) is crimped to the sleeve (20) while enclosing the outer circumference of a folded back portion (17) of the braided wire (15); and a front end (20F) of the sleeve (20) is positioned forward of the front end (18F) of the sheath (18) in the front-rear direction.

Disclosed is a cable assembly including at least one conductor and a metal sheath disposed over the at least one conductor, the metal sheath including a continuous strip of metal having a plurality of revolutions. A first revolution of the plurality of revolutions may include a first section having a curved profile extending into an interior cavity of the metal sheath, and a second section extending from the first section, the second section extending along a lengthwise axis, wherein a length of the second section, along the lengthwise axis, is at least two times as large as a diameter of the first section when the metal sheath is in a linear configuration. The first revolution may further include a third section extending from the second section, the third section including a free end terminating within a recess defined by a curved profile of a first section of an adjacent revolution.