RU211043U1 - POWER ELECTRIC CABLE - Google Patents

Abstract

The utility model relates to cable technology, namely to the designs of power electric cables used for the transmission and distribution of electrical energy in stationary electrical installations. The design of a power electrical cable with polymer insulation and residential grounding is proposed, used for the transmission and distribution of electrical energy in stationary electrical installations, in which the main conductors of the cable are made of copper, and the neutral conductor and the ground conductor are made of aluminum alloy, which allows to reduce the price and to obtain increased thermomechanical characteristics of the cores, to increase the reliability of the contact of the cable connection point. The proposed utility model makes it possible to create a new power cable with a zero core with high performance and thermomechanical characteristics, more technologically advanced, with improved quality and reliability. 7 w.p. f-ly, 2 ill.

Description

The utility model relates to cable technology, namely to the designs of power electrical cables with polymer insulation, zero residential and residential grounding, used for the transmission and distribution of electrical energy in stationary electrical installations. Cables designed for the transmission and distribution of electrical energy in stationary installations for a rated alternating voltage of 0.66 kV at a frequency of 50 Hz or a constant rated voltage of 1 kV, for a rated alternating voltage of 1 kV at a frequency of 50 Hz or a constant rated voltage of 1.5 kV, as well as for rated alternating voltage 3 kV, frequency 50 Hz, including in hazardous areas.

The closest in technical essence of the utility model and taken as a prototype is an electric power cable (utility model patent RU No. 166985, IPC N01V 9/00, publ. twisted into a core, an inner polymeric sheath over the core and a protective cover, wherein the conductive conductors are made of copper, and the ground conductor is made of aluminum.

The technical problem and disadvantage of the prototype is the high cost of the cable, reduced reliability and the impossibility of ensuring high manufacturability of the cable connection due to the execution of the ground conductor made of aluminum.

The technical objective of the utility model is to create a new power electric cable with a lower cost and with higher operational and thermomechanical characteristics of the cores, with improved quality and reliability, more technologically advanced, with the ability to maintain electrical contact reliability for a long time.

The design of a power electrical cable with polymer insulation and residential grounding is proposed, used for the transmission and distribution of electrical energy in stationary electrical installations, in which the main conductors of the cable are made of copper, and the neutral conductor and the ground conductor are made of aluminum alloy, which allows to reduce the price and to obtain increased thermomechanical characteristics of the cores, to increase the reliability of the contact at the cable connection point.

The technical problem is solved due to the fact that in a power cable with a zero core, containing the main current-carrying cores made of copper, a grounding conductor, while each of the cores is insulated with polymer insulation, the insulated cores are twisted into a core, a sheath and an outer the protective cover, according to the utility model, additionally contains a conductive neutral conductor, on which polymer insulation is applied, while the main conductive conductors are multi-wire, and the ground conductor and the neutral conductor are made of aluminum alloy with improved thermomechanical characteristics, and the cross section of the ground conductor and the conductive neutral conductor is not less than the cross section of the main conductive cores, and the gaps between the conductive cores and the sheath are filled with bundles of non-hygroscopic fibrous material.

In addition, according to the utility model, the ground conductor is made of aluminum alloy using alloying elements with the following ratio of alloying elements, wt. %: iron 0.26-0.32, nickel 0.02-0.04, zirconium 0.1-0.4.

In addition, according to the utility model, the polymer core insulation is made of PVC or cross-linked polyethylene or ethylene-propylene elastomer.

In addition, according to the utility model, the shell is made of lead or aluminum.

In addition, according to the utility model, the shell is made of plastic, rubber or thermoplastic elastomer.

In addition, according to the utility model, the outer protective cover is made in the form of armor made of galvanized steel tapes, or aluminum alloy tapes, or armored wires, for example, galvanized steel or aluminum alloy.

In addition, according to the utility model, the outer protective cover is made of a polymer shell or fibrous materials.

In addition, according to the utility model, the main current-carrying cores, the grounding current-carrying core, the neutral current-carrying core are made in a round or sector shape.

In FIG. 1 shows a cross section of a power cable with insulated sector-shaped conductors twisted together.

In FIG. 2 shows a cross-section of a power electric cable with round-shaped insulated cores twisted together.

The device contains the main current-carrying conductors made of copper (1), a conductive neutral conductor (2) and a conductive earth conductor made of aluminum alloy (3), while each of the conductors is insulated with polymer insulation (4), the insulated conductors are twisted into a core, over the core there is a sheath (5), an outer protective cover (6), while the cross section of the ground conductive conductor and the neutral conductor is not less than the cross section of the main conductive conductors, and the gaps between the conductive conductors and the sheath are filled with bundles of non-hygroscopic fibrous material (not shown).

The manufacturing technology of the cable according to the utility model is implemented as follows.

On the copper main (1) conductors, the neutral (2) conductor and the earth conductor (3) from an aluminum alloy of a five-core cable, polymer insulation (4) is made of polyvinyl chloride plastic compound of reduced fire hazard or cross-linked polyethylene, or a polymer composition that does not contain halogens. Insulation (4) must be extruded (pressed out), fit snugly to each conductive core, and, if necessary, be separated from the conductive core without damaging the core and the insulation itself. Insulated cable cores must have a distinctive color or marking. Moreover, the cross section of the zero current-carrying core and the grounding current-carrying core is not less than the cross-section of the main current-carrying cores of the cable. Then the insulated conductors of the cable are twisted into a core. Next, a sheath (5) made of metal or polymeric materials is applied over the twisted cores. Perhaps between the insulation and the cores, the imposition of a bonding separating winding (not shown). To give the cable a round shape, the inner and outer gaps between the insulated cores must be filled. The internal gap for a cable sheathed in PVC and polyethylene must be filled with a bundle (not shown) of non-hygroscopic fibrous material, or a bundle (not shown). It is possible to use a harness made of polyvinyl chloride plastic compound or unvulcanized rubber, as well as from water-blocking threads. The filling of the outer gaps between the insulated conductors must be carried out simultaneously with the sheathing (insulated conductors with a nominal cross section of up to 10 mm inclusive can be twisted without filling the internal gap between them). The sheath must be molded from plastic, rubber or thermoplastic elastomer, or made from lead or aluminium. On top of the shell, an outer protective cover is applied in the form of armor (6) from two galvanized steel tapes or aluminum alloy tapes, or from armored wires, for example, galvanized steel or aluminum alloy. The use of aluminum alloy armor strips is allowed. Armor should be applied in a continuous layer.

Due to the fact that the electric power cable is quite versatile, it can be connected both to stationary objects and to mobile installations and used in mines, underwater lines, explosive premises, power plants, in private houses and apartment buildings, on railways, railway stations, in airports, agricultural facilities, industrial plants, administrative buildings, construction sites, etc. The service life of such cables is at least 30 years, subject to the conditions of transportation, storage, laying (installation), and the operation of cables is not limited by the service life, but is determined by their technical condition.

In accordance with GOST 15150, comprehensive tests of the power electric cable under normal climatic conditions were carried out to check the design and structural dimensions, check the strength, electrical parameters and resistance to mechanical stress. All tests were successful, a positive result was achieved.

The technical result of the claimed utility model is the creation of a cable with higher performance and thermomechanical characteristics of the cores, more technologically advanced, with improved quality and reliability, by maintaining electrical contact for a long time.

Thus, the claimed power electric cable with the above distinctive features, together with the known features, is new, industrially applicable and subject to legal protection as a utility model.

Claims (8)

1. A power cable with a zero core, including main current-carrying cores made of copper, a grounding conductor, while each of the cores is insulated with polymer insulation, the insulated cores are twisted into a core, a sheath and an outer protective cover are located on top of the core, characterized in that it additionally contains conductive neutral conductor, on which polymer insulation is applied, while the main conductive conductors are multi-wire, and the ground conductor and the neutral conductor are made of aluminum alloy with improved thermomechanical characteristics, and the cross section of the ground conductive conductor and the conductive neutral conductor is not less than the cross section of the main conductive conductors, and the filling the gaps between the conductive cores and the sheath are made of bundles of non-hygroscopic fibrous material. 2. The cable under item 1, characterized in that the ground conductor is made of aluminum alloy using alloying elements in the following ratio of alloying elements, wt. %: iron 0.26-0.32, nickel 0.02-0.04, zirconium 0.1-0.4. 3. The cable according to claim 1, characterized in that the polymer insulation of the cores is made of polyvinyl chloride plasticate, or cross-linked polyethylene, or ethylene-propylene elastomer. 4. Cable according to claim 1, characterized in that the sheath is made of lead or aluminum. 5. Cable according to claim 1, characterized in that the sheath is made of plastic, rubber or thermoplastic elastomer. 6. Cable according to claim 1, characterized in that the outer protective cover is made in the form of armor made of galvanized steel tapes, or aluminum alloy tapes, or armored wires, for example, galvanized steel or aluminum alloy. 7. Cable according to claim 1, characterized in that the outer protective cover is made of a polymer sheath or fibrous materials. 8. The cable according to claim 1, characterized in that the main conductive cores, the grounding conductor, the neutral conductor are round or sector-shaped.

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