WO2020225629A1

WO2020225629A1 - Electrical cable for control and monitoring circuits

Info

Publication number: WO2020225629A1
Application number: PCT/IB2020/053711
Authority: WO
Inventors: Геннадий Мещанов; Михаил Шолуденко; Евгений ВАСИЛЬЕВ; Любовь Лаппо; Вера ЛАНКИНА; Ирина Хвощевская
Priority date: 2019-05-06
Filing date: 2020-04-20
Publication date: 2020-11-12

Abstract

The utility model relates to conducting equipment. A cable comprises a core 4, surrounded successively by a core covering 6, a shield 7, and a jacket 9 made of a thermoplastic material. The core 4 is configured in the form of four-pair strands 3 twisted together. Each of said strands 3 is formed by conductors 1 twisted into pairs and provided with insulation 2. The technical result is increased reliability.

Description

Electrical cable for control and monitoring circuits

The technical field to which the utility model belongs

The utility model relates to electrical engineering, in particular to the construction of electrical cables, mainly for control circuits, monitoring and data transmission in industrial, transport and energy facilities, in particular, in nuclear power facilities.

State of the art

A large number of electrical cable designs are known in the art.

As the closest analogue, a well-known electric cable was selected containing a core, outside of which belt insulation, a screen and a sheath made of thermoplastic material are sequentially located, the said core is made in the form of twisted bundles, each of which is formed by twisted in pairs and insulated conductors

(RU83875, published 03.02.2009). The disadvantage of this known cable is the lack of stability of functional and mechanical parameters in conditions of high seismic activity.

Disclosure of the essence of the utility model

The technical problem solved by this utility model is to create a low-current electrical cable with high operational reliability under conditions of intense dynamic loads.

The achieved technical result consists in improving the operability of the cable by increasing the stability of electromechanical parameters, in particular the transient attenuation, and the fire safety of the cable under conditions of prolonged high-intensity dynamic loads caused, for example, by seismic activity.

The specified technical result is achieved in that the electric cable for control and monitoring circuits contains conductive cores equipped with insulation from a thermoplastic material, said conductive conductors are twisted in pairs to form at least eight pairs, said pairs of conductive conductors are twisted together to form, of at least two four-pair bundles forming the cable core, over which a belt insulation made of polymer material, a screen and a sheath made of thermoplastic material are sequentially located, while the ratio of the twisting pitch of said conductive conductors in a pair to the twisting pitch of said pairs in each four-pair bundle is 0.1 to 0.8. The specified technical result is also achieved by the fact that the core is spirally wrapped with a fastening element made of synthetic material with a pitch of not more than 300 mm.

The specified technical result is also achieved by the fact that each four-pair bundle is spirally wrapped with a fastening element made of synthetic material with a pitch of not more than 300 mm.

The specified technical result is also achieved by the fact that each fastening element in the four-pair beams has its own color.

The specified technical result is also achieved by the fact that the insulation of each conductive core within one four-pair beam has its own color.

The specified technical result is also achieved by the fact that each conductive core within one four-pair bundle contains the identifier of this bundle, which makes it possible to establish the belonging of this conductive conductor to a specific bundle.

The specified technical result is also achieved by the fact that a thermal barrier made of mica tape or fiberglass is located on top of each conductive core.

The specified technical result is also achieved by the fact that the screen is made of metal or metal-polymer.

A distinctive feature of the design of an electric cable in accordance with this utility model is the optimal selection of the twisting steps of the elements forming the core.

Brief Description of Drawings

Figure 1 shows a cross-section of a cable. Implementation of the utility model

In modern conditions, computerized means of control, monitoring and data transmission are widely used in automation systems, telemechanics, measuring and test complexes and control systems in various fields. The reliability and safety of such systems is determined by the reliability and safety of electrically conductive equipment. One of the most critical in terms of safety requirements is the field of nuclear energy. Products intended for operation at nuclear power plants must maintain their high functional and operational reliability under any external influences.

Recent accidents related to nuclear power facilities show that one of the most dangerous external influences is seismic activity. Requirements for equipment in conditions of seismic activity are established by various regulations, norms and rules in the field of the use of atomic energy (for example, Design Norms for Seismic-Resistant Nuclear Power Plants NP-031-01).

The main reason for the loss of operability or fire safety properties by electrically conductive equipment is the destruction of protective coatings, shells, insulation, etc. The mechanics of destruction of coatings made of polymer materials has its own laws. Destruction begins in places of the highest concentration of mechanical stresses (in places of maximum surface friction) and then local fractures cover neighboring areas, causing destruction of conductive materials, cable failure or fire.

Mechanical stresses and deformations appear primarily at the points of contact of conductors, which in turn is determined by the twist parameters. The present utility model is based on a combination of optimal stranding parameters for all components of the core.

As shown in Fig. 1, the electric cable comprises a core 4, on top of which a belt insulation 6 made of a polymer material, a shield 7 and a sheath 9 of a thermoplastic material are arranged in series. The core 4 is made of four-pair beams 3. The core can be formed as two or a large number of four-pair beams 3 (Fig. 1 shows a variant with three beams). Four-pair beams 3 are also twisted together by unidirectional or multidirectional twisting with a certain pitch. Synthetic threads or tapes can be used as fastening element 5. Advantageously, each fastening element in the beams was made in a different color to facilitate identification of the beams on long lines.

Each of the bundles 3 is formed by conductive conductors 1 twisted in pairs and provided with insulation 2 of thermoplastic material 1. Insulation 2 can be made, for example, of a halogen-free thermoplastic polymer composition. The most appropriate number of pairs in the bundle is four, as shown in FIG. 1.

The ratio of the twisting pitch of said conductive cores 1 in a pair to the twisting pitch of said pairs in a four-pair bundle 3 is from 0.1 to 0.8. It has been experimentally established that the stability of the electromechanical properties of the cable under dynamic loads, especially the transient attenuation, depends on the location and size of the centers of mechanical stress concentration. With the specified ratio of the twisting steps, the stability of the crosstalk is achieved under dynamic loads on the cable. When the value of the specified ratio is less than 0.1, the crosstalk attenuation increases due to a large number of turns of fastening elements and a high degree of compression of conductive conductors. Above 0.8, the core diameter becomes unstable. In this case, the shield 7 and the casing 9 exert uneven pressure on different sections of the conductive cores 1, which leads to the formation of mechanical stress concentrators. In addition, this range provides an optimal balance of flexibility and mechanical strength of the cable.

It is also advisable to insulate each core within one bundle with a different color to facilitate installation and integrity testing.

Each strand within one bundle may additionally contain an identifier of this bundle, which makes it possible to establish the vein's belonging to a particular bundle.

A thermal barrier made of mica tape or fiberglass can be located outside each conductor. This ensures the stability of the electromechanical parameters of the cable at high temperatures.

The belt insulation 6 can be made of polymeric material.

Conducting conductors 1 can be made single-wire or multi-wire. The insulation 2 and the casing 9 are expediently made of a halogen-free thermoplastic polymer composition. The screen 7 is expediently made of a metal or metal-polymer tape (for example, from an alumopolymer tape) with a thickness of at least 0.05 mm. It is advisable to lay a tinned copper contact wire under the screen 7 (wire cross-section is shown by position 8) with a diameter of 0.3 mm to 0.6 mm.

The cable in accordance with the present invention can be manufactured using known industrial equipment using known technologies. The utility model works as follows.

Carry out the laying of the cable and its connection to electrical devices. The color scheme of conductive conductors and fastening elements allows for quick connection on long lines.

The specified ratio of the steps of twisting conductive conductors into pairs and pairs into four-pair beams, allows to ensure the stability, first of all, of the transient attenuation, as well as other structural, electrical, mechanical, physicomechanical parameters of the cable and to maintain its performance under the influence of earthquakes, vibrations and dynamic loads of any other origin.

Claims

Utility model formula

1. An electrical cable for control and monitoring circuits, containing conductive conductors, provided with insulation of thermoplastic material, said conductive conductors are twisted in pairs to form at least eight pairs, said pairs of conductive conductors are twisted together to form at least two four-pair bundles forming the cable core, on top of which a belt insulation made of polymer material, a screen and a sheath made of thermoplastic material are sequentially located, while the ratio of the twisting pitch of the said conductive conductors in a pair to the twisting pitch of the mentioned pairs in each four-pair bundle is from 0.1 to 0.8.

2. Cable according to claim 1, characterized in that the core is spirally wound with a fastening element made of synthetic material with a pitch of not more than 300 mm.

3. Cable according to claim 1, characterized in that each bundle is spirally wound with a fastening element made of synthetic material with a pitch of not more than 300 mm.

4. Cable according to claim 3, characterized in that each fastening element in the bundles has its own color.

5. Cable according to claim 1, characterized in that the insulation of each core within one bundle has its own color.

6. A cable according to claim 5, characterized in that each core within one bundle contains an identifier of this bundle, which makes it possible to establish the identity of the conductor to a specific bundle.

7. A cable according to claim 1, characterized in that a thermal barrier made of mica tape or fiberglass is located outside each conductive core.

8. Cable according to claim 1, characterized in that the screen is made of metal or metal-polymer.