RU75497U1 - CABLE FLEXIBLE POWER ARMORED - Google Patents

Abstract

The utility model relates to the field of electrical engineering, namely to the design of armored flexible power cables, which are designed to power electric motors from transistor converters to a voltage of 1 kV AC at a frequency of 50 Hz. The armored flexible power cable contains conductive multi-wire copper conductors with PVC insulation, twisted into a core, a shield, waist insulation, armor, and a protective sheath of PVC. In the cable, the armor is made in the form of a longitudinally applied corrugated steel coated tape, covered with at least one inner layer of a hydrophobic aggregate. The cable may further comprise, under the protective sheath, a release layer of polymer film superimposed on the outer layer of the hydrophobic aggregate over the armor. The cable has good mechanical protection, is more resistant to bending. 9 p.formulas, 1 illustration.

Description

The utility model relates to the field of electrical engineering, namely to the design of armored flexible power cables, which are designed to power electric motors from transistor converters to a voltage of 1 kV AC at a frequency of 50 Hz.

The prototype is a flexible cable with copper stranded conductors, with insulation made of PVC compound. Insulated cable conductors with a number of conductors up to 5 have a distinctive color. The insulation of the zero conductors is made in blue, and the grounding conductors are made in green and yellow colors. A screen in the form of a braid of copper wires is superimposed on top of twisted isolated conductors. The cable can have armor from two steel galvanized tapes. The shell is made of PVC compound. The cable is designed for stationary connection of electric motors with frequency converters. (Catalog of Kolchuginsky Zavod Electrocable OJSC. KGVEV, KGVEVng cables at 0.66; 1 kV. TU 16. K 01-30-2002. M. 2006, p. 34-35).

The cable has disadvantages: limited laying due to low moisture resistance, insufficient mechanical protection and poor protection against rodents, as well as insufficient flexibility.

The present utility model is based on the task of creating such a flexible armored power cable, in which a new implementation of structural elements, their new combination would provide the cable with virtually unlimited laying conditions, and increase bending resistance.

The problem is solved in that in a flexible power armored cable containing conductive multi-wire copper conductors with PVC insulation, twisted into a core, a shield, belt insulation, armor, a protective sheath of PVC, according to a utility model, the armor is made in the form of a longitudinally laid corrugation steel coated tape coated with at least one inner layer of hydrophobic aggregate.

Due to the implementation of the armor in the form of a longitudinally overlapping corrugated steel coated tape, the cable has several advantages. Corrugated steel tape is more resistant to bending and is a good protection against rodents. The inner polymer sheath serves as a pillow for armor, and the coating with at least one inner layer of hydrophobic aggregate additionally seals the cable and improves its flexibility.

In addition, there is the possibility of various cable options: for laying in cable ducts, in soil, water, inside the building, including in conditions of high fire hazard.

Steel corrugated tape can be made with zinc coating or tinned, which reliably protects the steel tape from corrosion (even in the absence of hydrophobic filler) and increases the service life of the cable.

Corrugated steel tape can be laminated on both sides, while the polymer layer is welded with it when a plastic sheath is applied and the armor becomes airtight at the overlap.

The screen can be made in the form of a braid or winding of copper wires, which increases the shielding efficiency and the flexibility of the cable.

The screen can be made of copper tape or foil, which increases the efficiency of shielding.

The cable may additionally contain a separating layer of polymer film under the protective sheath, which eliminates the contamination of the extruder head with a hydrophobic filler and greatly facilitates the technology of applying the protective sheath.

In each conductive core, the central wire or core of said wires can be coated with a depleted heat-resistant grease, which increases the flexibility of the cable. In addition, electrical losses are reduced, due to the presence of a lubricant film on the surfaces of the wires, even with bends, electrical contact between them is eliminated, reducing the surface effect and the proximity effect.

The protective shell may be made of low flammability polyvinyl chloride plastic compound.

The protective shell may be made of polyvinyl chloride

plastic compound with low smoke and gas emission, which significantly increases the fire resistance and reliability of cables.

The proposed cable is schematically shown in cross section in the figure, where a cable of four twisted insulated cores is given. In the figure: 1 - conductive power core, 2 - insulation, 3 - screen, 4 - belt insulation, 5 - hydrophobic aggregate, 6 - armor, 7 - separation layer, 8 - protective shell.

The armored flexible power cable contains conductive multi-wire copper conductors 1 with insulation 2 made of PVC compound, twisted into a core, screen 3, waist insulation 4, armor 6, protective sheath 8 made of PVC compound. In the cable, the armor 6 is made in the form of a longitudinally laid corrugated steel coated tape, covered with at least one inner layer of hydrophobic aggregate 5.

Example. The armored flexible power cable (Fig.) Contains three main conductors with a cross section of 3 × 70 mm ² and a zero core with a cross section of 35 mm ² . Copper cores 1 are multi-wire with continuous insulation 2 of polyvinyl chloride plastic compound, applied on an extruder. Each insulated core 1 has a screen 3 in the form of a winding made of copper foil 0.06 mm thick. Four insulated cores 1 are twisted on a twisting machine into a core having a belt insulation 4 of PVC compound overlaid on an extruder. Armor 6 is made in the form of longitudinally superimposed with overlapping corrugated tinned steel tape. Under the armor 6 and on top of it, one inner layer and one outer layer of hydrophobic aggregate 5 are applied respectively. A separating layer 7 of a polyethylene terephthalate film is applied to the outer layer of the hydrophobic aggregate 5 along the armor 6. The cable is covered with a protective sheath 8, which, like the belt insulation 4, is made of low flammability polyvinyl chloride plastic compound.

When laying the cable in water or in water-saturated soils, a protective sheath 8 made of polyethylene is applied over the laminated steel armor 6, while the polymer layer of the armor 6 is welded with it when the sheath 8 is applied and the armor 6 becomes airtight at the overlap and is moisture barrier.

Claims (9)

1. Armored flexible power cable, containing conductive multi-wire copper conductors with PVC insulation, twisted into a core, screen, waist insulation, armor, protective sheath of PVC compound, characterized in that the armor is made in the form of a longitudinally applied corrugated steel with a coating tape coated with at least one inner layer of hydrophobic aggregate. 2. The cable according to claim 1, characterized in that the screen is made in the form of a braid or winding of copper wires. 3. The cable according to claim 1, characterized in that the screen is made of copper tape or foil. 4. The cable according to claim 1, characterized in that the steel corrugated tape is made with zinc coating or tinned. 5. The cable according to claim 1, characterized in that the steel corrugated tape is laminated on both sides. 6. The cable according to claim 1, characterized in that it further comprises, under the protective sheath, a separation layer of polymer film superimposed on the outer layer of the hydrophobic aggregate on the armor. 7. The cable according to claim 1, characterized in that in each conductive core, the central wire or core of said wires is coated with depleted heat-resistant grease. 8. The cable according to claim 1, characterized in that the protective sheath is made of low flammability polyvinyl chloride plastic compound. 9. The cable according to claim 1, characterized in that the protective sheath is made of PVC compound with reduced smoke and gas emission.