RU195769U1 - HIGH FREQUENCY SYMMETRIC CABLE WITH A SCREEN BASED ON CARBON NANOTUBES - Google Patents

Abstract

The claimed utility model relates to cable technology, namely to the design of high-frequency balanced cables. A high-frequency balanced cable includes a core consisting of at least one pair of twisted conductive conductors. Moreover, each conductive core is made of twisted metal wires and coated with insulation. A screen is superimposed on top of a pair of twisted conductive conductors. Moreover, the core is enclosed in an outer polymer shell. In this case, the screen, over a pair of insulated conductive wires twisted into a pair, is superimposed in the form of a winding tape, which is made of synthetic paper with carbon nanotubes and on which an external metal coating 1-5 microns thick is applied. A significant improvement in the electrical parameters of a high-frequency balanced cable is provided. 6 c.p. f-ly, 1 ill.

Description

The claimed utility model relates to cable technology, namely to the design of high-frequency balanced cables.

The cable is intended for manning space-rocket systems having integrated distributed and parallel information-computing and control systems that work in real time using Space Wire technology, aerospace and military equipment and provide digital and analog signals with operating alternating voltage up to 200 In (350 V DC), frequencies up to 600 MHz with a speed of 2 to 400 Mbit / s.

A high-frequency symmetrical cable is known from the prior art, including a core consisting of at least one pair of twisted conductive wires, each conductive core made of twisted metal wires and coated with insulation, and a braided shield is applied over a pair of twisted conductive wires metal wires, and the core is enclosed in an outer polymer shell (RU 169338, 03/15/2017, prototype).

Due to the use of a pair of screen made of metal wires in a known cable design, the cable structure is significantly heavier. In addition, the electrical parameters of a known cable, such as the attenuation coefficient and the attenuation of shielding, may not satisfy the increased requirements for the electrical parameters of cables intended for manning space-rocket systems of aerospace and military equipment.

The problem to which the claimed utility model is directed is to eliminate the shortcomings of the closest analogue.

The technical result consists in improving the electrical parameters of a high-frequency balanced cable.

A high-frequency symmetrical cable comprising a core consisting of at least one pair of twisted conductive wires, each conductive core made of twisted metal wires and coated with insulation, and a screen overlaid on top of a pair of twisted conductive wires, the core being enclosed in an outer polymer shell , characterized in that the screen, on top of twisted into a pair of insulated conductive conductors, is superimposed in the form of a winding tape, which is made of synthetic paper with carbon nanotr abrasions and on which an external metal coating 1-5 microns thick is applied.

According to the claimed utility model, conductive conductors are made compacted by 5 ÷ 12% in diameter.

According to the claimed utility model, the outer metal coating deposited on top of synthetic paper is made of copper or silver, or aluminum.

According to the claimed utility model, insulated conductive conductors are twisted in pairs together with two cordes, while the corners are made of fluoroplastic.

According to the claimed utility model, the diameter of each cordele in a pair of twisted conductive conductors is 0.7-0.9 of the diameter of one insulated conductive core.

According to the claimed utility model, the conductive wires are made of tinned copper or of copper or bronze silver-plated wires (brand BrHTsrK).

According to the claimed utility model, the insulation of each conductive core is made of semi-air fluoroplastic and imposed by the method of physical foaming during extrusion or in the form of a winding with a porous tape.

The claimed utility model is illustrated by drawings.

The figure shows the claimed cable in cross section.

A high-frequency symmetrical cable includes a core consisting of at least one pair of twisted conductive conductors 1. Each conductive core is twisted from tinned copper or from silver or bronze silver-plated wires (brand BrKhTsrK) coated with insulation 2. Each conductive core is compacted for 5 ÷ 12% in diameter. In this case, the insulation 2 of each conductive core can be made of semi-air fluoropolymer imposed by the method of physical foaming during extrusion or in the form of a winding with a porous tape. The insulated conductive conductors are twisted together with two 3 fluoroplastic cords, for example polytetrafluoroethylene or perfluoroalkoxide polymers. Moreover, the diameter of each cordele in a pair of twisted conductive conductors is 0.7-0.9 of the diameter of one insulated conductive core. Over the insulation of a pair of conductive conductors twisted into a pair, a screen 4 is made, made in the form of a winding with a tape made of synthetic paper with carbon nanotubes, on which an external metal coating 1-5 μm thick made of copper or silver or aluminum is applied. On top of the screen 4, an outer shell 5 of polyurethane or polyvinylidene fluoride or fluoroethylene propylene was applied by extrusion.

A high-frequency balanced cable is manufactured using serial technological equipment. The conductive core 1 is twisted from seven silver-plated copper wires or tinned copper wires. In this case, after twisting, the conductive conductors are compacted by 5-12% in diameter by pulling each core through a calibration device. Due to the compaction of current-carrying conductors, stability and uniformity of signal transmission are ensured, as well as a reduction in cable diameter while maintaining the value of the signal attenuation level and electrical resistance of the core, which generally improves its electrical parameters. After twisting and sealing, insulation 2 from a semi-air fluoroplastic is applied to each conductive core by the method of physical foaming during extrusion or by the method of winding with a fluoroplastic porous tape. Two insulated conductive conductors 1 are twisted together with two fluoroplastic cords 3, for example polytetrafluoroethylene or perfluoroalkoxide polymers. In this case, the diameter of one core 3 in a twisted pair of conductive conductors is 0.7-0.9 of the diameter of one insulated conductive core and is optimal for ensuring equidistance of the shield 4 from the pair and the symmetry of the conductors in the pair, both in the case of linear cable laying and in places of its possible bends. In the case of an increase or decrease in the diameter of the corbel beyond the specified range, the screen 4 is more susceptible to deviations from the round shape during laying and operation of the cable, which leads to a deterioration in the stability of its electrical parameters. On top of a pair of conductive wires twisted together with cordels, a screen 4 is applied in the form of a winding with a ribbon of synthetic paper with carbon nanotubes on which an external metal coating 1-5 microns thick of copper or silver or aluminum is applied. The presence of a metal coating provides the screen 4 with the necessary level of electrical resistance. In this case, the range of thicknesses of the metal coating is chosen optimal and if it is applied with a thickness of less than 1 μm, the metal coating does not fulfill its function, and in case of exceeding 5 μm causes an increase in the mass of the shield 4 in comparison with the mass of the braid of the individual shield of the cable prototype. On top of the screen 4, the outer shell 5 of polyurethane or polyvinylidene fluoride or fluoroethylene propylene is applied by extrusion or in the form of a winding tape.

To confirm receipt of the claimed technical result, measurements were made of the electrical parameters of the claimed cable and prototype.

Thus, due to the screen of a pair of twisted conductive cores made in the form of a winding tape made of synthetic paper with carbon nanotubes on which an external metal coating 1-5 μm thick made of copper or silver or aluminum is applied, a significant improvement in the electrical parameters of the high-frequency balanced cable is ensured.

Claims (7)

1. A high-frequency symmetrical cable comprising a core consisting of at least one pair of twisted conductive wires, each conductive core made of twisted metal wires and coated with insulation, and a screen is laid over a pair of twisted conductive wires, the core being enclosed in an external polymer shell, characterized in that the screen, over twisted into a pair of insulated conductive conductors, is superimposed in the form of a winding tape, which is made of synthetic paper with carbon nanotubes E and to which is applied an external metal coating thickness of 1-5 microns. 2. A high-frequency symmetrical cable according to claim 1, characterized in that the conductive conductors are made compacted by 5-12% in diameter. 3. The high-frequency symmetrical cable according to claim 1, characterized in that the external metal coating deposited on top of synthetic paper is made of copper or silver, or aluminum. 4. The high-frequency symmetrical cable according to claim 1, characterized in that the insulated conductive conductors are twisted in pairs together with two corders, while the corners are made of fluoroplastic. 5. A high-frequency symmetrical cable according to claim 1, characterized in that the diameter of each cordele in a pair of twisted conductive conductors is 0.7-0.9 of the diameter of one insulated conductive core. 6. A high-frequency symmetrical cable according to claim 1, characterized in that the conductive conductors are made of tinned copper or of copper or bronze silver-plated wires (brand BrHTsrK). 7. The high-frequency symmetrical cable according to claim 1, characterized in that the insulation of each conductive core is made of semi-air fluoroplastic and imposed by the method of physical foaming during extrusion or in the form of a winding with a porous tape.

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