The invention relates to an assembly (14) of a cable-connecting device (10) and a multi-core cable (11), which form a mechanical, explosion-proof connection to each other. For this purpose, the cable-connecting device (10) has a plastically deformable outer sleeve (18) having a crimping section (23). A hollow cylindrical inner sleeve (19) made of elastically deformable material is arranged between a cable sheath (13) made of elastomer and the crimping section (23). An elastic deformation of the inner sleeve (19) and of the cable sheath (13) is caused by radially plastically deforming the crimping section (23). Any gaps (40) present within the cable sheath (13) are closed due to the radial forces in the crimping section (23) such that spark-gap-free contact between the cable sheath (13) and the cores (12) of the cable (11) and between the cable sheath (13) and the inner sleeve (19) is ensured.

The invention relates to an assembly (14) of a cable-connecting device (10) and a multi-core cable (11), which form a mechanical, explosion-proof connection to each other. For this purpose, the cable-connecting device (10) has a plastically deformable outer sleeve (18) having a crimping section (23). A hollow cylindrical inner sleeve (19) made of elastically deformable material is arranged between a cable sheath (13) made of elastomer and the crimping section (23). An elastic deformation of the inner sleeve (19) and of the cable sheath (13) is caused by radially plastically deforming the crimping section (23). Any gaps (40) present within the cable sheath (13) are closed due to the radial forces in the crimping section (23) such that spark-gap-free contact between the cable sheath (13) and the cores (12) of the cable (11) and between the cable sheath (13) and the inner sleeve (19) is ensured.

The disclosure relates to a cable sequence for wiring of an electrical circuit with a series arrangement of a plurality of pre-assembled cables, each of which has a first cable end and a second cable end which lies opposite the first cable end, wherein each of the pre-assembled cables has a conductor and a conductor insulation, and wherein the cable ends are processed for the wiring of an electrical circuit in such a manner that a respective conductor end is insulation-free at the first cable end and at the second cable end, and connections between adjacently arranged pre-assembled cables in the series arrangement, wherein, by means of the connections, in each case a first cable end of a pre-assembled cable, produced beforehand as free cable end, and a second cable end of a next pre-assembled cable in the series arrangement, produced beforehand as free cable end, are connected to one another. Furthermore, a method for producing a cable sequence for wiring an electrical circuit and the use of a cable sequence are provided.

The disclosure relates to a cable sequence for wiring of an electrical circuit with a series arrangement of a plurality of pre-assembled cables, each of which has a first cable end and a second cable end which lies opposite the first cable end, wherein each of the pre-assembled cables has a conductor and a conductor insulation, and wherein the cable ends are processed for the wiring of an electrical circuit in such a manner that a respective conductor end is insulation-free at the first cable end and at the second cable end, and connections between adjacently arranged pre-assembled cables in the series arrangement, wherein, by means of the connections, in each case a first cable end of a pre-assembled cable, produced beforehand as free cable end, and a second cable end of a next pre-assembled cable in the series arrangement, produced beforehand as free cable end, are connected to one another. Furthermore, a method for producing a cable sequence for wiring an electrical circuit and the use of a cable sequence are provided.

It is an object of the present invention to ensure a high water-stopping property of a wire harness including a waterproofing connector section that is molded from a resin, by suppressing a variation in the outer size of a seal section of the connector section. The connector section is made from a first synthetic resin that is insert-molded with a part of a terminal fitting of the terminated electric cable used as an insert section. A water-stopping section is made from a second synthetic resin that is insert-molded with a section extending from a part of the terminal fitting to an insulation coating of the terminated electric cable used as an insert section. The seal section is made from the second synthetic resin that is insert-molded with a part of the connector section used as an insert section. The second synthetic resin is softer than the first synthetic resin.

Ocean floating installations (1) are disposed on the ocean. The ocean floating installations (1) float on the ocean with the lower part of the ocean floating installations (1) being fixed to the seabed by mooring ropes (11). Each of the ocean floating installations (1) is connected at a connection part (5a) to a cable (3), which is a first cable. Each of the cables (3) is connected at a connection part (5b) to a cable (7), which is a second cable. In other words, the ocean floating installations (1) are connected to each other by the cables (3) and the cable (7). A connection is established with the cables (7) at the connection parts (5b) located on the seabed. In other words, the cables (7) are installed on the seabed.

An electric device includes a housing and a cable. The housing has a pipe bracket disposed on the housing. The pipe bracket includes an interior pathway extending from a free-end of the pipe bracket into the housing. The free-end of the pipe bracket has teeth thereon. The cable has a union nut and a sleeve. The sleeve has a crimped section attached to the cable such that the crimped section is non-displaceable. The sleeve further has a toothed annular surface. In an installed state of the cable to the housing, a feedthrough portion of the cable extends through the interior pathway of the pipe bracket and into the housing. The union nut encompasses the sleeve and is attached to the pipe bracket to thereby press the toothed annular surface of the sleeve against the teeth of the pipe bracket such that the cable is fixed rotationally to the housing.

Continuously transposed conductor (“CTC”) cables are described. A CTC cable may include a plurality of electrically insulated strands connected in parallel at their ends. Additionally, each strand may include one or more conductors and an extruded insulation layer formed at least partially around the one or more conductors.

A power distributor including a first conductive coupling device electrically coupled to a bare-wire non-terminating section of a first conduit. A second conductive coupling device is electrically coupled to a terminating end of a second conduit. The first conduit is a larger gauge than the second conduit. A fuse electrically connects the first conductive coupling device and the second conductive coupling device. A housing encases the first and second conductive coupling devices and the fuse.

An electricity storage device including: plural electricity storage modules, each including an electricity storage module case, plural electricity storage cells housed in the electricity storage module case, and external terminals; an electricity storage case in which the plurality of electricity storage modules are arranged and housed; plural wire harnesses connected to the external terminals of the electricity storage modules; and a vibration damping material provided in a space region between one surface of the electricity storage case and, among the plurality of wire harnesses, at least a wire harness including the longest length extending in an arrangement direction of the electricity storage modules, wherein the wire harness including the longest length extending in the arrangement direction of the electricity storage modules is biased toward a side of the electricity storage module case by the one surface of the electricity storage case, through the vibration damping material.