RU180985U1 - Shielded power cable - Google Patents

Abstract

The utility model relates to the field of electrical engineering, namely to the cable industry, in particular to the design of power shielded cables designed for transmission and distribution of electric energy in stationary installations to a rated voltage of 10 kV AC with a frequency of up to 150 Hz. The power cable contains symmetrically arranged copper conductive conductors, on top of which a three-layer insulation is applied, on top of which a screen is applied. The first and third insulation layers are made of extrudable electrically conductive material, the second insulation layer is made of cross-linked ethylene-propylene rubber. On top of the twisted conductive conductors, an inner shell is applied, made with filling the gaps between the conductive conductors, on top of which a two-layer combined screen is applied. The central gap between the conductors is filled with polymer material. The outer shell is made of cold-resistant polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission. The technical result is the provision of increased noise immunity of the cable to improve the properties of electromagnetic compatibility and increase the service life of the cable. 8 s.p. f-ly, 1 ill.

Description

Technical field

The utility model relates to the field of electrical engineering, namely to the cable industry, in particular to the design of power shielded cables designed for transmission and distribution of electric energy in stationary installations to a rated voltage of 10 kV AC with a frequency of up to 150 Hz.

State of the art

Known cable shielded flexible (patent RU No. 78602 publ. 11/27/2008), containing three main conductive wires of equal cross section with rubber insulation, individual shields for the core and insulation, an auxiliary core with insulation of a more rigid material and an uninsulated ground wire. Over the twisted main conductive conductors, auxiliary conductors and ground conductors, a polyethylene terephthalate film winding is applied, over which a sheath made of cold-resistant thermoplastic elastomer, which does not spread combustion, with an oxygen index of 28, is applied.

Known power cable for voltage 6-35 kV (patent RU No. 138403 publ. 03/10/2014), single or three-core, with conductive conductors of round or sector shape, containing conductive core (s), a polymer screen for the core, insulation, a polymer screen for extrusion insulation, damping layer, metal wire shield, separation layer, armor and protective sheath. The conductive polymer screen for the core and insulation is made of materials that can be used for a long time at a temperature of at least 105 ° C for 40 years; for a short time, but not less than 100 hours per year, operated at a temperature of at least 140 ° C, and withstand at short circuits a temperature of at least 300 ° C.

A three-core power cable selected for the prototype (patent RU No. 152230 publ. 05/10/2015) contains conductive wires, layers are sequentially laid on top of each core: the first conductive screen, insulation, the second conductive screen, a layer of conductive tape and a metal screen. Conductors with the above layers are twisted into the core either directly or around a bundle extruded from a polymer material. Over the core, either a separation layer, an inner shell and an outer shell, or a separation layer, an inner shell, armor and an outer shell, or an inner shell and an outer shell, or an inner shell, armor, and an outer shell are sequentially applied. The insulation is made of ethylene propylene rubber with a reinforcing hydrophobic filler, said first and second electrically conductive screens are made of ethylene propylene rubber.

The disadvantages of the known technical solutions include the fact that the cables are designed to operate at an industrial frequency of alternating current and have insufficient noise immunity during operation as part of frequency-controlled electric drives, due to imperfect design and materials used in the cables.

Utility Model Essence

The technical result of the implementation of the utility model is to provide increased noise immunity of the cable to improve the properties of electromagnetic compatibility and increase the service life of the cable.

The technical result is achieved in that in a shielded power cable containing three conductive cores, insulation, insulation screen, inner and outer sheath, according to the proposed solution, the first and third insulation layers are made of extrudable electrically conductive material, the second insulation layer is made of cross-linked ethylene-propylene rubber moreover, on top of the inner shell there is a two-layer combined screen, the central gap between the symmetrically located conductive cores is filled with polymer material.

The first layer of the combined screen can be made in the form of a winding made of copper or aluminum foil, or of a composite material based on copper or aluminum foil.

The second layer of the combined screen can be braided from copper or tinned copper wires.

The insulation screen can be made in the form of a winding of electrically conductive fabric wrapped in copper wires.

The insulation screen can be made in the form of a winding of electrically conductive fabric and copper wires imposed by a concentric layer.

The inner shell can be made of cold-resistant PVC compound of reduced fire hazard with low smoke and gas emission.

The inner shell may be made of a cold-resistant halogen-free polymer composition.

The outer shell can be made of cold-resistant PVC compound of reduced fire hazard with low smoke and gas emission.

These features are significant and interconnected with the formation of a stable set of essential features sufficient to solve the aforementioned technical result.

The applicant is not aware of the design of power shielded cables, representing the totality of all the features that characterize the claimed utility model, which indicates the novelty of the claimed facility.

The proposed design of the utility model is illustrated in the figure, which shows the cable in cross section.

Utility Model Implementation

The power cable contains flexible copper conductive conductors 1 located symmetrically. Conductors 1 have a core class of at least 5 according to GOST 22483-2012. On top of the conductive conductors 1, a three-layer insulation is applied, including the first layer 2 of extrudable electrically conductive material, the second layer 3 of cross-linked ethylene-propylene rubber, and the third layer 4 of extrudable electrically conductive material. On the surface of the insulation there is a screen 5 made by winding from an electrically conductive fabric and a concentric winding of copper wires. On top of the twisted conductors is an inner shell 6 made of cold-resistant polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission or a cold-resistant polymer composition that does not contain halogens. The inner sheath 6 is made with filling the gaps between the conductive cores to give the cable a round shape and eliminate air gaps. On the inner shell 6 is a two-layer combined screen, the first layer 7 of which is made by winding from copper or aluminum foil, or a composite material based on copper or aluminum foil. The second layer 8 of the combined screen is braided from copper or tinned copper wires. The outer shell 9 is made of cold-resistant polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission. To fill the air space in the center of the cable is a filler 10 made of polymer material.

Due to the use of a two-layer combined shield, protection against internal and external electromagnetic interference of the insulation is provided, which, in order to reduce the effect of the high-frequency electric field, is made of extrudable electrically conductive material and cross-linked ethylene-propylene rubber having low dielectric constant, and an increased noise immunity of the cable is achieved.

The claimed utility model is industrially applicable, since its implementation requires materials and technologies known from the prior art today.

The cable construction described in this example and shown on graphic materials is not the only one possible to solve the above technical result and does not exclude other variants of its manufacture containing a combination of features included in the independent claims of the utility model.

Claims (9)

1. Shielded power cable containing three conductors, insulation, insulation screen, inner and outer sheath, characterized in that the first and third layers of insulation are made of extrudable electrically conductive material, the second insulation layer is made of cross-linked ethylene-propylene rubber, and over the inner sheath a two-layer combined screen is made, the central gap between the symmetrically located conductive cores is filled with polymer material. 2. Shielded power cable according to claim 1, characterized in that the first layer of the combined screen is made in the form of a winding made of copper or aluminum foil. 3. Shielded power cable according to claim 1, characterized in that the first layer of the combined screen is made of composite material based on copper or aluminum foil. 4. Shielded power cable according to claim 1, characterized in that the second layer is braided from tinned copper or copper tinned wires. 5. Shielded power cable according to claim 1, characterized in that the insulation screen is made in the form of a winding of electrically conductive fabric wrapped in copper wires. 6. Shielded power cable according to claim 1, characterized in that the insulation screen is made in the form of a winding of electrically conductive fabric and copper wires superimposed in a concentric layer. 7. Shielded power cable according to claim 1, characterized in that the inner sheath is made of cold-resistant polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission. 8. Shielded power cable according to claim 1, characterized in that the inner sheath is made of a halogen-free polymer composition that is cold resistant. 9. Shielded power cable according to claim 1, characterized in that the outer sheath is made of cold-resistant polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission.

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