SU516138A2 - End cutting high-voltage cable - Google Patents

Description

(54) END CLUTCH OF HIGH-VOLTAGE CABLE

one

The invention relates to electrical engineering, high-voltage and; pulse technology, and may find application in high-voltage structures containing high-voltage pulsed cables, in particular, in the manufacture of cable terminations for high-energy storage devices, which place increased demands on the reliability of all elements, and also: to their size and inductance.

According to the main author. St. No. 352348 is known for terminating a high-voltage cable, the conductive core of which is covered with a main insulation layer and a semiconducting layer that is in electrical contact with a current-conducting shell made in the form of a conductor protruding beyond the edge of the shell with the said layers. In addition, the core is connected by a conductive jumper with the edge of the semiconducting edge removed from the shell: lo. This design of cuts is quite reliable in operation. However, in some cases it is advisable to make it possible to manufacture terminal cable cuts for the same "nominal voltages in a pulsed mode, having even lower inductance due to the reduction in length while maintaining the radial dimensions. Minimum radial dimensions of puppy length while maintaining radial

it is necessary to withstand in the case of cutting, in cable collectors of low-inductance capacitive energy storage with a large number of parallel-connected cables.

The aim of the invention is to provide a length reduction and an inductive 1 STD cutter while maintaining its radial dimensions. In order to achieve this goal, a layer of insulating material is predominantly applied directly onto the semiconductor layer in the form of a film.

Panesenps on the surface of a semiconducting layer of a high resistivity dielectric film makes it difficult to develop a discharge along the surfaces of the semiconductor layer and determines the possibility of further reducing the length of the insulating part of the groove or increasing the discharge voltage, and therefore reliability while maintaining the length.

It was experimentally established that the thickness of the additionally applied dielectric film does not play a significant role in order to achieve the effect of increasing discharge voltages. When the film thickness was changed from 0.5 to 5 mm, the discharge voltages remained almost the same. so that the film thickness exceeds a certain critical, providing shielding

processes of secondary emission of electrons from the nolaud pdego layer. Such a minimum thickness d, as was established experimentally, for polyethylene is: 0.05-0.1 mm.

Thus, the deposition of a small thickness of the dielectric layer on the surface of the blunt-through layer of the cable cutting contributes to the increase in discharge stresses on the surface without significantly increasing the radial dimensions of the cutting. This is of great importance for cable collectors of accumulators consisting of a large number of cables, since reducing the length of the grooves without reducing the number of attached cables per unit length of the collector reduces the inductance of the collector as a whole.

The drawing schematically shows the proposed end cutting cable.

The end cuts are made in the form of a current-carrying conductor 1, covered with a layer of basic insulation 2 and a semiconducting layer 3, which is in electrical contact with the current-carrying sheath 4. The surface of the semiconductor layer is covered with a dielectric film 5 immediately adjacent to its outer surface. The cable lug 6 is pressed onto the current-carrying core 1, electrically connected by means of a conductive bridge 7 to the edge of the semiconducting layer, and has a protrusion covering the edge of the die film f 2 3 8

electrician, remote from the end of the conductive sheath. The potential rings 8 are soldered to the cable lug and the current-carrying sheath provided with a current-collecting clamp 9. In case of the absence of the potential rings 8, the edge of the dielectric film is advisable to lead the node to the edge of the current-carrying sheath.

Works cable terminations

in the usual way.

When impulse voltage is applied to the cable core relative to its conductive sheath, the cuts allow current to flow from the core to the load and reverse

current through the cable sheath while maintaining a high electric strength between the core and the edge of the sheath during the entire voltage pulse duration, which can have both aperiodic and oscillatory shapes.

Claims (1)

Invention Formula Kontseva cutting high-voltage cable auth. St. 352348, characterized in that, in order to provide the possibility of reducing the length and inductance of the groove while maintaining its radial dimensions, a layer of an insulating material is predominantly applied in the form of a film. / 7