An integral, unitary cover assembly for covering an electrical connection between first and second electrical cables each having a primary conductor and a neutral conductor, includes an elastomeric inner sleeve, an elastomeric outer sleeve surrounding the inner sleeve, and a collapsible duct assembly interposed radially between the inner and outer sleeves. The inner sleeve defines a cable passage to receive the electrical connection and the primary conductors of the first and second cables. The duct assembly includes an outer duct sleeve member defining a first passage and an inner retention member disposed in the first passage. The retention member defines a second passage configured to receive at least one of the neutral conductors therethrough. The duct sleeve member is flexible. The retention member maintains the duct sleeve member in an open configuration when the retention member is disposed in the first passage. The duct sleeve member is selectively collapsible about the at least one neutral conductor from the open configuration to a collapsed configuration by withdrawing the retention member from the first passage.

An integral, unitary cover assembly for covering an electrical connection between first and second electrical cables each having a primary conductor and a neutral conductor, includes an elastomeric inner sleeve, an elastomeric outer sleeve surrounding the inner sleeve, and a collapsible duct assembly interposed radially between the inner and outer sleeves. The inner sleeve defines a cable passage to receive the electrical connection and the primary conductors of the first and second cables. The duct assembly includes an outer duct sleeve member defining a first passage and an inner retention member disposed in the first passage. The retention member defines a second passage configured to receive at least one of the neutral conductors therethrough. The duct sleeve member is flexible. The retention member maintains the duct sleeve member in an open configuration when the retention member is disposed in the first passage. The duct sleeve member is selectively collapsible about the at least one neutral conductor from the open configuration to a collapsed configuration by withdrawing the retention member from the first passage.

The present invention relates to an electrical device (1, 20, 30) comprising a cross-linked layer (3, 4, 5) obtained on the basis of a cross-linkable polymer composition comprising a polymer material and particles with polyhedric structure, characterized in that the particles have a melting point of at most 200° C.

An integral, unitary cover assembly for covering an electrical connection between first and second electrical cables each having a primary conductor and a neutral conductor includes an inner elastomeric sleeve, an outer elastomeric sleeve, and a collapsible duct. The inner elastomeric sleeve defines a cable passage to receive the electrical connection and the primary conductors of the first and second cables. The outer elastomeric sleeve surrounds the inner sleeve. The collapsible duct is interposed radially between the inner and outer sleeves. The duct defines a neutral conductor passage configured to receive at least one of the neutral conductors therethrough. The duct is selectively collapsible from an initial open configuration to a collapsed configuration about the at least one neutral conductor.

An integral, unitary cover assembly for covering an electrical connection between first and second electrical cables each having a primary conductor and a neutral conductor includes an inner elastomeric sleeve, an outer elastomeric sleeve, and a collapsible duct. The inner elastomeric sleeve defines a cable passage to receive the electrical connection and the primary conductors of the first and second cables. The outer elastomeric sleeve surrounds the inner sleeve. The collapsible duct is interposed radially between the inner and outer sleeves. The duct defines a neutral conductor passage configured to receive at least one of the neutral conductors therethrough. The duct is selectively collapsible from an initial open configuration to a collapsed configuration about the at least one neutral conductor.

Some embodiments include a flexible, pressure-balanced cable assembly. The cable assembly has a tubular-shaped flexible outer sleeve that surrounds an electrical cable. A plurality of seals is positioned along the length of the flexible sleeve within the space formed between the inner surface of the flexible sleeve and the outer surface of the electrical cable. The seals partition the space into a plurality of individual chambers. Each chamber is filled with dielectric fluid. The seals are independently and bi-directionally movable in response to a pressure difference between the inside of the cable assembly and the external environment thereby balancing the pressure between the inside of the cable assembly and the external environment.

Some embodiments include a flexible, pressure-balanced cable assembly. The cable assembly has a tubular-shaped flexible outer sleeve that surrounds an electrical cable. A plurality of seals is positioned along the length of the flexible sleeve within the space formed between the inner surface of the flexible sleeve and the outer surface of the electrical cable. The seals partition the space into a plurality of individual chambers. Each chamber is filled with dielectric fluid. The seals are independently and bi-directionally movable in response to a pressure difference between the inside of the cable assembly and the external environment thereby balancing the pressure between the inside of the cable assembly and the external environment.

A method for creating a composite cable having at least one advanced termination on at least one end. An advanced termination is added to an end of a short synthetic tensile strength member. The strength of the tensile strength member and termination is then tested. Once tested satisfactorily, the short cable is spiced onto a long cable of the same type using prior art splicing techniques. The union of the short cable and the long cable creates a “composite” cable having a advanced termination on at least one end. In most applications it is preferable to set the length of the short cable so that the interwoven splice will exist at a desired location.

A mold includes a first electrode on which a looped conductor of an electric wire is placed, the looped conductor being an exposed conductor of the electric wire from which a coating is removed and having an overlap portion at which different parts of the exposed conductor overlap each other, a hole forming jig provided upright on the first electrode to extend through an inner hole of the looped conductor, a wire holding jig arranged to surround the first electrode, and a second electrode having a conductor pressing protrusion configured to be fitted in a conductor molding groove defined by the first electrode and the wire holding jig to press and heat the looped conductor. The wire holding jig has a plurality of separable holding jigs configured to hold the looped conductor between the separable holding jigs from a direction perpendicular to an axis of the hole forming jig.

A mold includes a first electrode on which a looped conductor of an electric wire is placed, the looped conductor being an exposed conductor of the electric wire from which a coating is removed and having an overlap portion at which different parts of the exposed conductor overlap each other, a hole forming jig provided upright on the first electrode to extend through an inner hole of the looped conductor, a wire holding jig arranged to surround the first electrode, and a second electrode having a conductor pressing protrusion configured to be fitted in a conductor molding groove defined by the first electrode and the wire holding jig to press and heat the looped conductor. The wire holding jig has a plurality of separable holding jigs configured to hold the looped conductor between the separable holding jigs from a direction perpendicular to an axis of the hole forming jig.