RU20193U1 - FLEXIBLE CABLE - Google Patents

Description

The utility model relates to the field of electrical engineering, in particular to cable technology, and can most effectively be used as a current lead in electric networks of alternating and direct voltage to mobile machines and mechanisms.

To protect the insulation of conductive cores from the harmful effects of light, moisture, various chemicals, as well as to protect against mechanical damage, the cables are sheathed. Known cable containing twisted conductive conductors, each of which is coated with rubber insulation and located on top of the twisted insulated conductive conductors sheath, made also of rubber (TU 16.K73.05-93). Rubber shells are highly resistant to tensile, bending and shock loads, and also protect the insulation of the cores from solar radiation and other atmospheric influences.

However, over time, rubber shells lose their elastic and physico-mechanical properties and their electrical parameters decrease due to aging of the rubber, which occurs under the influence of various factors (high temperature, the presence of oxygen, ozone, light, etc.) and is due to oxidative degradation of rubber contained in rubber.

Recently, in the manufacture of flexible cables, thermoplastic elastomers, combining the properties of rubber and thermoplastics, are increasingly used. The main advantages of thermoplastic elastomers are strength, elasticity, wear resistance, as well as the possibility of processing on equipment for plastics.

Known cable containing conductors twisted in one direction, each of which is coated with insulation from thermoplastic elastomer based on high-pressure polyethylene or block copolymer of propylene with ethylene, and located on MKKIN01V7 / 04 Flexible cable

the top of twisted conductive conductors a sheath of PVC compound. (Certificate for utility model of the Russian Federation No. 13516 dated 11/01/99. Published on 04/20/2000).

The use of thermoplastic elastomers can significantly simplify the manufacturing technology, facilitate the design of the cable and reduce its cost due to the lower density of the material and the complexity of manufacturing the cable compared to rubber.

A power cable is also known, in which not only the insulation, but also the sheath is made of thermoplastic elastomer based on high-pressure polyethylene or block copolymer of propylene with ethylene. The cable contains a synthetic film located between twisted conductors and the sheath. (Certificate for the utility model of the Russian Federation No. 15810 dated 06/14/2000 published on 10/11/2000).

The latter is the closest to the claimed utility model and adopted as a prototype.

A cable with an insulation and a sheath made of thermoplastic elastomer based on high-pressure polyethylene or a block copolymer of propylene with ethylene has insufficient flexibility and is less resistant to short-circuit currents.

One of the main requirements for the cables of the claimed type is increased flexibility in the conditions of repeated bending and torsion deformations that have occurred during the operation of cables, including at low temperatures.

The objective of the proposed utility model is to create a cable that is resistant to short circuit and which would have increased resistance to mechanical deformation, especially at low temperatures to minus and less susceptible to thermo-oxidative aging.

The problem is solved in that the cable contains twisted conductive conductors, each of which is coated with rubber insulation, and a sheath of styrene thermoplastic elastomer with polymer and mineral fillers located on top of the twisted conductive conductors. In addition, the cable contains a film of

polyethylene terephthalate located between twisted conductive conductors and the sheath.

The inventive utility model differs from the prototype in that the insulation of the conductive core is rubber;

- the protective shell is made of styrene thermoplastic elastomer with the addition of polymer and mineral fillers; the film is made of polyethylene terephthalate.

The proposed utility model combines the advantages of rubber and thermoplastic elastomers. The insulation of conductive conductors made of rubber is more resistant to short-circuit currents and primarily perceives loads arising from short-circuit currents, and also provides increased flexibility to the cable. The sheath made of thermoplastic elastomer protects the rubber more effectively from external influences, providing increased flexibility at low temperatures, while the overall flexibility of the cable is also higher than if the insulation and the sheath were made of thermoplastic elastomer. In addition, styrene thermoplastic elastomers with the addition of polymer and mineral fillers have good physical, mechanical and dielectric characteristics, higher resistance to thermo-oxidative aging at elevated operating temperatures, and have high elasticity, especially

at low temperatures, and wear resistance than thermoplastic elastomers based on high-pressure polyethylene or block copolymer of propylene with ethylene.

The utility model is further illustrated by an example of a specific implementation. The figure shows the cross section of a flexible cable of the proposed design.

The cable contains three main conductive conductors 1, coated with rubber insulation 2, and a grounding conductor 3 with rubber insulation 4. Twisted conductors are covered with a film of 5 polyethylene terephthalate, over which a protective sheath 6 made of styrene thermoplastic elastomer with the addition of polymer and mineral fillers is applied.

(

Claims (2)

1. A flexible cable containing conductors that are twisted in one direction, each of which is coated with insulation, and a sheath made of thermoplastic elastomer located on top of twisted conductors, characterized in that the insulation is made of rubber, the sheath is made of styrene thermoplastic elastomer with the addition of polymer and mineral fillers. 2. The flexible cable according to claim 1, characterized in that it further comprises a film of polyethylene terephthalate located between twisted conductive conductors and the sheath.