RU43102U1 - COAXIAL POWER CABLE - Google Patents

Abstract

The utility model relates to the field of electrical engineering and is intended for use in the transmission and distribution of electrical energy in power and lighting networks. Cable 1 contains an internal single-core 2 and an external multicore conductor 4 with insulation 3 between them, as well as an external dielectric protective sheath 5 made of plastic with the inclusion of a steel core. According to a utility model, the external protective dielectric sheath 5 contains steel conductors in the form of armor conductive reinforcement 6. Moreover, the cross-sectional area of reinforcement 6 is 4.0-30.0% of the cross-sectional area of conductive conductors 2 and 4. The reinforcement 6 is placed with the possibility of electrical contact with an external multicore conductor 4.

Description

The utility model relates to the field of electrical engineering and is intended for use in the transmission and distribution of electrical energy in power and lighting networks.

Coaxial cables of various purposes are known, for example, geophysical, radio-frequency, superconducting, etc. (1, 2, 3). So coaxial geophysical cable according to (4), is intended for work and research in oil and gas wells. The cable contains a central conductive core isolated from each other, a conductive copper braid, and two-brew wire armor. The central core is made of coils of copper wire with a cross-sectional area of at least 1.5 mm and equal to the cross-sectional area of the current-carrying braid. The cable design provides the transmission of high electrical power the possibility of using it, both as a measuring and power.

A disadvantage of the known design is the large mass of linear meter of cable, which excludes its use when laying overhead lines, due to significant sagging and the danger of breakage.

A power cable for identifying generated, transmitted and consumed electricity is also known (5). The cable contains in cross section two subregions of materials, one of which is a conductor and the other

- dielectric. Part of the boundary line of the section and / or part of the boundary line of the subregions of the conductor and / or dielectric is made in the form of a fragment of an oblique conical section of a straight circular cone. This design provides an asymmetric arrangement of the cores in the cable cross-section relative to the screen or the longitudinal axis of the cable and increases its electrical frequency characteristics due to the individual parameters of the cross-section.

The disadvantage of this cable design is the complex manufacturing technology, as well as a narrow special application - for accounting and control of the parameters of the transmitted energy and its use for ordinary transmission and supply of electric energy to consumers is not economically justified.

An electric cable has been proposed for energy transfer at high powers (6). The cable contains insulated conductive conductors, one of which is used as a neutral conductor, while the latter is shunted by third-party conductive parts. The location of the neutral conductor obeys a certain empirical relation, which includes the distance a ₁₂ between the centers of gravity of the cross sections of the neutral conductor and the nearest phase core and its perimeter P of the cross section. This embodiment of the electric cable, when the insulated conductive conductors are grouped into four conductors, one of which is used as the neutral conductor, eliminates its overheating when the cross section is reduced due to the creation of special conditions for the current distribution during a single-phase short circuit. At the same time, it becomes possible to limit the cross section of the zero conductor from above, the value of which does not exceed 30% of the phase conductor cross section.

The disadvantage of the design is the relatively large mass of linear meter of cable length and, as a result, the possibility of significant sagging, which increases the risk of breakage when laying overhead lines.

Closest to the proposed technical solution is a coaxial cable for the distribution of electrical energy in power networks, which is selected as a prototype (7). The cable contains internal single-core and external multicore conductors, insulated from each other by a dielectric sheath made of plastic. The external stranded conductor is enclosed in a protective dielectric sheath, also made of plastic. The conductors are made of aluminum, while the number of cores N in the external multicore conductor is at least 30 pieces, and their number is related to the cross section s of the internal single-core conductor by the empirical ratio: 3N = 113-2s. This design allows you to increase the strength of the conductor to reduce its sagging when laying overhead lines.

However, a significant drawback of the cable is its significant stretching and sagging during operation on overhead lines, which reduces reliability and safety.

The objective of the utility model is to eliminate these drawbacks; including elimination of sagging, increased reliability and safety during operation on overhead power lines.

The problem is solved in that in a coaxial power cable containing an internal single-core and external multicore conductive conductors with insulation between them and an external dielectric protective sheath made of plastic with the inclusion of a steel core, according to a utility model, the external protective dielectric sheath contains steel wires in the form of an armor conductive reinforcement with area. the cross-section is 4.0-30.0% of the cross-sectional area of the conductive conductors, while the fittings are evenly spaced around the perimeter of the cable, protected by a corrosion-resistant coating and made with the possibility of electrical contact with an external multicore conductor.

The internal single-core and external stranded conductors are made of aluminum or copper wire.

The anticorrosive coating of the armor armature is made of zinc or chromium.

The outer dielectric protective sheath and the insulation between the inner and outer conductors are made of PVC compound.

The insulation between the inner and outer conductors is made of PVC compound, and the external dielectric sheath is made of a composition of silanol crosslinkable polyethylene.

The proposed design of the coaxial power cable is characterized by increased tensile strength, not much residual elongation under tension due to the special shape of the location of the steel armor reinforcement and the optimal choice of the ratio of its cross section to the cross section of conductive conductors.

The essence of the utility model is illustrated by the drawing, where figure 1 shows a cross-sectional view of the cable.

Cable 1 contains an internal single-core conductor 2, with insulation 3, separating it from a multi-core external conductor 4, enclosed in an external dielectric sheath 5 with armored steel reinforcement 6, the wires of which 7 are placed in a layer of a multi-core external conductor 4.

For the manufacture of cable using the following materials:

- aluminum or copper wire;

- galvanized steel wire;

- polyvinyl chloride plastic compound;

- a composition of silanol-crosslinked polyethylene.

As insulation, it is possible to use other equivalent materials that provide the required characteristics of the finished product.

Coaxial power cable is made as follows. An insulating dielectric layer 3 is extruded onto the continuously supplied internal single-core conductor 2. Then, an inner multicore conductor 4, as well as steel wires 7 of the power reinforcement 6, on which zinc or chrome coating is preliminarily applied, are placed in a single layer around the obtained insulated conductor 2 with insulation 3 not shown). Steel wires 7 of the reinforcement are evenly distributed around the circumference around the single-core conductor 2 on the insulation surface 3 and tightly laid between the wires of the multi-core conductor 4 with electrical contact between them, as well as a percentage in the range of 4.0-30.0% of the cross-sectional area of the conductive conductors . The value of the latter is selected depending on the cutoff of the cable being manufactured. The ends of the wires 7 of the steel reinforcement 6 and the stranded conductor 4 are fixed on the insulation surface 3, and then the outer dielectric sheath 5 is extruded from above. The insulation 3 and dielectric sheath 5 are made, as described above, from polyvinyl chloride plastic compound (GOST 5960-72 “Polyvinyl chloride plastic compound for insulation) and protective sheaths of wires and cables. Technical conditions "). The dielectric sheath 5 can also be made on the basis of a composition of silanol-crosslinked polyethylene that meets the necessary requirements for electrical resistance (GOST 23286-78 "Cables, wires and cords. Norms of insulation thicknesses, shells and voltage tests"). The finished cable is wound on a drum (not shown in the drawing) and sent to the warehouse.

Table 1 shows some characteristics of the cable according to the proposed utility model.

Table 1. Nominal cross section of external and internal conductors, mm (*) Nominal thickness, mm Max outer diameter mm Insulation of the inner conductor Protective dielectric sheath of the outer conductor

6/6 1,0 1,5 9.5 8/8 1,0 1,5 10.0 10/10 1,0 1,5 10.5 16/16 1,0 1,5 13.0 (*) Note: The lower limit of the deviation from the nominal thickness of insulation for the inner conductor is - (0,1 + 0,1δ _iz1), and an external insulation for the outer insulating shell - (0,1 + 0,15 δ _ob2), where δ _iz1 and δ _ob2 - insulation thickness of the conductors of the internal and external, respectively.

Table 2 presents the test results of prototypes of a 6/6 mm coaxial power cable manufactured in accordance with the utility model for the main technical parameters. The tests were carried out in accordance with the requirements of the relevant GOSTs and Technical requirements for cable electrical products by an independent body accredited by the central factory laboratory of Moldav-cable CJSC.

Table 2. Controlled Qty Parameter value parameter samples Normalized Actual length m 1 2 3 1 2 3 4 1. Structural elements: 3x1 - cross section of the inner and outer conductors, mm ² 3 6/6 6 6 6 External conductor - number of wires, incl. 32 32 32 32 - booking 4 4 4 4 fittings. 0.5 ± 0.01 0.630 0.633 0.635 - nominal diameter, mm Nominal diameter of the inner conductor, mm 2.73 ± 0.04 2.73 2.74 2.75 Nominal insulation thickness, mm 1.20-0.22 + not ogre. 1.21 1.12 1.20 Nominal shell thickness, mm 1.90-0.385 + not ogre. 1.83 1.96 1.96

2. Peak voltage, kV at construction length 20/17 ± 5% No breakdown of insulation and shell 3. Electrical resistance of conductors: 3 × 5 - internal conductor Ohm per 1 km no more than 5.11 4.85 4.87 4.85 - external conductor, Ohm per 1 km 5.11 4.98 4.97 4.98 4. Electrical insulation resistance: - insulation of the inner conductor not less than 1 × 10 ⁶ 10.6 × 10 ⁶ 25 × 10 ⁶ 20 × 10 ⁶ - shell 18 × 10 ⁶ 18 × 10 ⁶ 18.7 × 10 ⁶ 20.7 × 10 ⁶ 5. Cold resistance 3 × 1.5 Exposure 2 hours at -50 ° С ± 3 ° С no cracks, No cracks 2000V for 5 min without breakdown No breakdown; 6. Nonproliferation 5 × 0.6 burning fifty 310 315 307 310 318 distance from the lower edge of the upper clamp to the upper border for damage, not less than, mm burning does not extend 7. Bending test roller diameter - 10d 3 × 0.65 No break No wire break Π / 2 bend 8. Tensile strength, MPa 3 × 0.2 no less than 3848 4422 4483 4576 1 9. Voltage test 3 × 5 2000 V 5 min without breakdown No breakdown

As can be seen from table 2, the coaxial cable manufactured according to the utility model is characterized by high mechanical and electrical properties and meets all safety requirements for such products.

The use of armoring reinforcement within the specified limits significantly increases the ultimate tensile force of the cable and significantly reduces its elongation under tension and, accordingly, minimizes sagging under operating conditions on overhead power lines.

The proposed coaxial power cable has passed production tests and is currently used in industrial conditions for the installation of lighting networks, distribution and transmission power lines.

Sources of information:

1. RU №2001110661 A, IPC ⁷ Н 01 В 11/18, G 01 V 3/18, (14) 2003.03.27.

2. RU No. 1595247 C, IPC ⁵ H 01 B 11/18, (14) 1994.07.30.

3. RU No. 2087956 C1, IPC ⁵ H 01 B 12/14, (14) 1997.08.20.

4. RU No. 2200999 C2, IPC ⁷ H 01 B 11/18, G 01 V 3/18, (14) 2003.03.20.

5.RU No. 2144711 C1, MPK ⁷ H 01 B 9/00, 3/00, (22) 03/11/99.

6. RU No.2113740 C1, IPC ⁶ Н 01 В 9/00, (46) 06/20/98, (22) 12/14/94.

7. RU No. 33669 U1, IPC ⁷ H 01 B 9/04, (22) 02.17.2003, (46) 10.27.2003 Bull. No. 30 (prototype).

Claims (5)

1. Coaxial power cable containing an internal single-core and external multicore conductive conductors with insulation between them and an external dielectric sheath made of plastic with the inclusion of a steel core, characterized in that the external protective dielectric sheath contains steel wires in the form of armor conductive reinforcement with a cross-sectional area 4.0-30.0% of the cross-sectional area of conductive conductors, while the fittings are evenly placed around the perimeter of the cable, protected by anti-corrosion m coated and made with the possibility of electrical contact with an external multicore conductor. 2. The cable according to claim 1, characterized in that the internal single-core and external multicore conductors are made of aluminum or copper wire. 3. The cable according to claim 1 or 2, characterized in that the anticorrosive coating of the armor armature is made of zinc or chromium. 4. The cable according to claim 1, characterized in that the outer dielectric protective sheath and the insulation between the inner and outer conductors is made of polyvinyl chloride plastic compound. 5. The cable according to claim 1, characterized in that the insulation between the inner and outer conductors is made of polyvinyl chloride plastic compound, and the outer dielectric protective sheath is made of a composition of silanol crosslinkable polyethylene.