The invention relates to a silicone rubber composition having specific dielectric properties which can be used as insulator material in high voltage direct current applications and a method for the manufacture of cable accessories like cable joints. The invention comprises as well a method for the determination of the optimum dielectric properties and the related amount of dielectric active additives.

A field grading composite body includes a polymeric matrix and a particulate filler distributed within the polymeric matrix. Particles of the particulate filler include a core formed from a semiconductor material, an oxide mixed layer deposited on the core, and conducting oxide layer. The conducting oxide layer deposited on the oxide mixed layer to provide an electrical percolation path through the polymeric matrix triggered by strength of an electric field extending through the field composite body. Conductors and methods of making field grading composite bodies for conductors are also described.

A power cable termination system including: a power cable having a power cable conductor and a power cable insulation system configured to electrically insulate the power cable conductor, a termination cable having a termination cable conductor and a termination cable insulation system configured to electrically insulate the termination cable insulation system, wherein the termination cable is at least one order of magnitude shorter than the power cable, wherein the termination cable conductor has an electrical resistance which is lower than the electrical resistance of the power cable conductor and/or the termination cable insulation system has a higher insulation resistance per unit length than the power cable insulation system, a joint configured to join the power cable and the termination cable, and a cable termination device configured to terminate the termination cable.

Provided are devices, methods and systems. A cover system may include a unitary cold shrinkable, tubular, elastomeric cover sleeve defining a cover sleeve through passage that is configured to receive the electrical cable. The cover sleeve may include a first type of stress control element and a second type of stress control element that is different from the first type of stress control element. A holdout maintains the cover sleeve in an expanded state in which the cover sleeve is elastically expanded and when removed, permits the cover sleeve to radially contract to a contracted state about the electrical cable. The first type of stress control element includes a geometric stress cone that includes an electrically conductive and/or semiconductive portion that is configured to conductively engage a semiconductor layer of the electrical cable. The second type of stress control element includes a high-K stress relief element.

The present disclosure describes an electrical cable accessory system for covering an electrical cable and/or cable connection. The electrical cable accessory system includes a pre-expanded cable accessory unit and a time-temperature indicator associated with the pre-expanded cable accessory unit. The pre-expanded cable accessory unit includes a pre-expanded cable accessory formed of an elastomeric material and a removable holdout mounted within the elastomeric cable accessory, wherein the holdout is operative to maintain the elastomeric cable accessory in an expanded state and to permit the elastomeric cable accessory to elastically contract when the holdout is removed from the elastomeric cable accessory. The time-temperature indicator is configured to undergo a visible change in appearance in response to a cumulative heat exposure and signal to a viewer when the elastomeric material of the pre-expanded elastomeric cable accessory unit has experienced a threshold cumulative heat exposure. Methods including the same are also described herein.

An arc proof cover with an integrated window is disclosed. The arc proof cover comprises a body and cover composed of arc and track resistant material. The body includes a first end, second end, and at least one window. In a closed position, the cover is placed over the at least one viewing window. A locking mechanism secures the closed position of the cover. When the locking mechanism is disengaged, the cover can be moved to allow visual inspection of the connectors within the arc proof cover. The body further includes an opening along its length which allows for the wrapping and unwrapping of the arc proof cover around the connectors of an assembled cable accessory.

An arc proof cover with an integrated window is disclosed. The arc proof cover comprises a body and cover composed of arc and track resistant material. The body includes a first end, second end, and at least one window. In a closed position, the cover is placed over the at least one viewing window. A locking mechanism secures the closed position of the cover. When the locking mechanism is disengaged, the cover can be moved to allow visual inspection of the connectors within the arc proof cover. The body further includes an opening along its length which allows for the wrapping and unwrapping of the arc proof cover around the connectors of an assembled cable accessory.

A sealed cabled assembly includes a cable and a cable moisture seal assembly. The cable includes a cable subcore, a metal shield layer surrounding the cable subcore, and a jacket surrounding the metal shield layer. The cable subcore includes an electrical conductor surrounded by an electrical insulation layer. The cable moisture seal assembly includes a sealant, a electrically conductive jumper member, and an outer sleeve. The cable includes a sealing region section extending from a first axial end to a second axial end, and in which a section of the jacket and a section of the metal shield layer are removed to expose a section of the cable subcore. The insulation layer and the conductor extend through the sealing region section. First and second sections of the jacket extend away from the sealing region section in first and second opposed directions, respectively. First and second sections of the metal shield layer extend away from the sealing region section in the first and second opposed directions, respectively. The outer sleeve surrounds the sealing region section. The sealant is disposed radially between the cable subcore and the outer sleeve, and engages the cable subcore to form a moisture barrier in the sealing region section between the first and second sections of the jacket. The jumper member electrically connects the first and second sections of the metal shield layer.

In an arrangement for connecting a high-voltage or very-high-voltage power cable comprising an insulative external jacket to an equipment element comprising an external surface by means of an insulative layer, the insulative layer consists of a composite material resistant to traction in the longitudinal direction of the cable and attached to said external jacket and to the external surface.

In an arrangement for connecting a high-voltage or very-high-voltage power cable comprising an insulative external jacket to an equipment element comprising an external surface by means of an insulative layer, the insulative layer consists of a composite material resistant to traction in the longitudinal direction of the cable and attached to said external jacket and to the external surface.