RU57044U1 - FLAT CABLE - Google Patents

Abstract

The utility model relates to the field of insulated wires. The flat cable contains twisted multi-wire conductive conductors located in a plane, each surface of which has at least one layer of a first electrical insulation material, at least two strands, a sheath and at least one jumper between said adjacent conductors made of a second electrical insulation material, the shell has two first flat surfaces parallel to the plane of said cores and two second surfaces mated to each of the first surfaces, said The isolated insulated conductors have twisted wires in different directions and are combined into groups, each of which includes at least one mentioned thread and one mentioned core. The shell thickness of each extreme core to the corresponding second surface is greater than the shell thickness from each core to each first flat surface, and at least one longitudinal groove is made on one flat surface opposite the bridge. The technical result consists in increasing the resource by reducing the likelihood of damage to the sides due to random mechanical influences on the surface of the shell.

Description

The utility model relates to the field of insulated wires.

A flat cable is known comprising twisted multi-wire conductive conductors arranged in a plane, each of which has at least one layer of a first electrical insulation material, at least two strands, a sheath and at least one jumper between said adjacent conductors made of a second electrical insulation material, the shell has two first flat surfaces parallel to the plane of the cores and two second surfaces mated to each of the first on top of wires, the mentioned isolated conductors have a twist of wires in different directions and are combined into groups, each of which includes at least one mentioned thread and one mentioned core / Utility Model of the Russian Federation No. 11922, 1999 /.

During operation of this flat cable with random mechanical influences on the surface of the sheath, the probability of damage to the sides is higher than for flat sides.

The technical result, which the utility model aims to achieve, is to increase the resource by reducing the likelihood of damage to the sides due to random mechanical influences on the surface of the shell.

To achieve this result, a flat cable is proposed comprising twisted multiwire conductive conductors located in a plane, each of which has at least one layer of a first electrical insulating material, at least two strands, a sheath and at least one jumper between said adjacent conductors, made of a second insulating material, the shell has two first flat surfaces parallel to the plane of the cores and two

the second surfaces associated with each of the first surfaces, said insulated conductors, have twisted wires in different directions and are combined into groups, each of which includes at least one of said threads and one of said conductors.

The thickness of the shell from each extreme core to the corresponding second surface is greater than the thickness of the shell from each core to each first flat surface, and at least one longitudinal groove is made on at least one flat surface opposite the bridge.

The thickness of the sheath on the flat sides of the cable is 1.3-1.5 times less than the thickness of the sheath on the lateral, rounded sides of the cable.

Operational experience and tests have shown that the side surfaces are most susceptible to mechanical stress from accidental contact with foreign objects during cable movement and installation, and therefore are the most vulnerable point of the cable.

In view of this, it is necessary to increase the mechanical strength of the sheath on the sides, however, with an increase in the thickness ratio of more than 1.5 times, an increase in the total thickness of the cable at the edges is observed (dumbbell effect on the side of the cable), further strengthening of the sides of the cable does not occur.

The tests showed that with a smaller value of the ratio of thicknesses, the probability of breakdown of the insulating material of the shell in the direction of the side with random mechanical influences on the surface of the shell is higher.

The flat cable has an equal number of cores with right and left twisting directions.

The adjacent veins are made with the right and left directions of twisting.

Flat cable has at least two groups of three cores.

The surface of the first electrical insulating material of each core has a release coating.

The surface of the first electrical insulating material of each core is coated with talc.

On the surface of each core two layers of the first electrical insulation material of different colors are applied.

On the outer surface of the layer of the first electrical insulating material of each core is marked, different in color from its surface.

The threads are made of polyamide fiber.

The figure shows a cross section of a flat cable.

The flat cable contains twisted multi-wire conductive conductors 2 located in the plane 1, each of which has at least one layer 3 of the first electrical insulating material, at least two strands 4, the sheath 5, and at least one jumper 6 between the adjacent said conductors 2 made of a second electrical insulating material.

Jumper 6 is necessary to ensure the stability of a flat cable shape under dynamic loads.

The shell 5 has two first flat surfaces A, parallel to the plane 1 of the cores 2 and two second side surfaces B, conjugated with each of the first surfaces A.

Insulated cores 2 have twisted wires in different directions and are combined into groups, each of which includes at least one mentioned thread and one mentioned core.

Conducting cores 2 have different directions of twisting wires.

In the cable, cores 2 with one direction of twisting are located between cores 2 with another direction of twisting.

The flat cable has an equal number of cores 2 with right and left twisting directions.

The adjacent cores 2 are made with right and left twisting directions.

The flat cable has two groups of three cores 2.

In plane 1, the thickness G of the sheath 5 from each extreme core 2 to the corresponding second lateral surface B is greater than the thickness B of the sheath 5 from each core 2 to each first flat surface A, and at least one longitudinal groove is made on each flat surface A opposite the bridge 6 7.

The thickness G of the sheath 5 to each first flat surface A of the cable is 1.3-1.5 times less than the thickness B of the sheath 5 on the lateral, rounded sides of the cable.

Conducting cores 2 are insulated with the first electrical insulating material - polyvinyl chloride plastic compound cable insulating, and the sheath 5, laid on top of parallel laid in groups of insulated conductive cores 2, is made of a second electrical insulating material - polyvinyl chloride plastic compound of a finely filled hose.

The surface of the first electrical insulation material of each core 2 has a release coating 8 of talc in order to avoid welding of the first and second electrical insulation materials in the process of applying the sheath 5.

The surface of the first electrical insulating material of each core is coated 8.

On the surface of the layer 3 of the first electrical insulation material of one color of each core 2, an additional layer of the first electrical insulation material of a different color can be applied.

The presence of a dye in the layer of the first electrical insulating material worsens the dielectric properties, and therefore an additional layer of the first electrical insulating material is performed with a minimum thickness (of the order of 0.1 mm).

It also allows you to reduce the cost of expensive dye without compromising the consumer properties of the cable as a whole.

On the outer surface of the layer 3 of the first electrical insulating material of each core 2 may be marked, different in color from the color of its surface.

The color marking is applied to the insulation of each core in the form of a number from 1 to 6, when performing the insulation of one core with a yellow-green coloring of the insulation, the numbers of the cores are applied from 1 to 5, excluding the yellow-green insulation.

Marking inscriptions containing information on the manufacturer, technical specifications number, year of manufacture are applied on the surface of the cable sheath.

The threads 4 are made of polyamide fiber, in particular, kapron and are designed to rip open the sheath 5 during cable cutting.

Thread 4, laid in each group of cores 2, is designed to rip open the cable sheath 5 when cutting it.

Namely, having cut the sheath 5 with a knife at a small distance (5-10 mm) from the edge, the installer clamps the thread 4 in the tool and pulls it in the transverse direction from the cable, rips the sheath 5 to the desired length (300-400 mm) with a guarantee of maintaining the insulation of the cores 2.

Claims (9)

1. A flat cable containing twisted multi-wire conductive conductors arranged in a plane, each of which is coated with at least one layer of a first electrical insulating material, at least two strands, a sheath and at least one jumper between said adjacent conductors made of a second electrical insulating material, the shell has two first flat surfaces that are parallel to the plane of the cores and two second surfaces associated with each of the first surfaces, said insulated conductors have twisted wires in different directions and are combined into groups, each of which includes at least one mentioned thread and one said core, characterized in that the thickness of the sheath of each extreme core to the corresponding second surface is greater than the thickness of the sheath from each core to each at least one longitudinal groove is made on the first flat surface, and on at least one flat surface opposite the jumper. 2. The flat cable according to claim 1, characterized in that it has an equal number of said cores with right and left twisting directions. 3. The flat cable according to claim 2, characterized in that said neighboring cores are made with right and left twisting directions. 4. The flat cable according to claim 1, characterized in that it has at least two groups of three cores. 5. The flat cable according to claim 1, characterized in that the surface of the layer of the first electrical insulation material of each core has a release coating. 6. Flat cable according to claim 5, characterized in that the release coating is made of talc. 7. The flat cable according to claim 1, characterized in that on the surface of the layer of the first electrical insulation material of one color of each core, an additional layer of the first electrical insulation material of a different color is applied. 8. The flat cable according to claim 1, characterized in that on the outer surface of the layer of the first electrical insulating material of each core is marked, different in color from its surface. 9. The flat cable according to claim 1, characterized in that the threads are made of polyamide fiber.