RU66857U1 - MANDAR HEAT-RESISTANT CABLE - Google Patents

Abstract

The claimed technical solution relates to cables with mineral insulation, used mainly at facilities operating in extreme conditions: nuclear power plants, shipbuilding, metallurgy, aerospace devices, etc. industrial and civilian facilities of increased danger. In one block cable, both power and signal cables can be laid, which have various functional purposes: control, signal, thermocouple, heat-sensitive, heat-resistant or other cable options. The performance characteristics of the inventive cable are not violated by a possible exposure at the same time: radioactive radiation, elevated temperatures, vibration, accelerations. At the same time, due to the possibility of manufacturing subcables thin and with individual pressure glands, it became possible to perform the inventive block cables with backup lines. Multi-core heat-resistant cable, made of separate subcables twisted together, if necessary - in a cylindrical spiral. Each of the subcables contains one or several conductive cores made of corrosion-resistant, heat-resistant materials: either copper, or copper alloys, or aluminum or aluminum alloys in a heat-resistant shell, isolated from each other and shells with a mineral filler, while subcables equipped with individual pressure glands or special terminators.

Description

The claimed technical solution relates to cables with mineral insulation - both power and signal cables, used mainly at facilities operating in extreme conditions: nuclear power plants, shipbuilding, metallurgy, aerospace devices, etc. industrial and civilian facilities of increased danger. The performance characteristics of the inventive cable are not violated by a possible exposure at the same time: radioactive radiation, elevated temperatures, vibration, accelerations.

A multicore cable is known, the manufacturing method of which is given in WO 0029117.

A cable is a metal sheath inside of which one, or several copper, steel or aluminum conductors are insulated from each other by mineral insulation.

The disadvantages of this cable are:

- its high rigidity - it is designed for fixed laying and allows only fixed bends;

- the construction length of cables of large sections - for example 1 × 400, is limited to 44 m;

- the cable is designed for relatively short-term operation at temperatures from 250 degrees C;

- the number of conductive wires in the cable is not more than 19.

Closest to the claimed is a "multi-core heat-resistant cable" - a patent for utility model No. 53069. The essence of this technical solution lies in the fact that the multi-core heat-resistant cable is made of individual subcables twisted together and fastened at the end with a tip. Each of the subcables contains one or more conductive cores made of copper or heat-resistant alloy, in a heat-resistant shell, and isolated from the shells with a mineral filler. From the description of this cable and the drawings, given as an illustration, it is clear that this block cable consists of the same subcables.

The disadvantages of this cable are that all the leads of the current-carrying conductors are united by one tip, and all subcables in the coils have the same diameter, and as a result, with an increase in the number of coils, the rigidity of the block cable construction increases, and as a result, the bending radius increases.

Tasks solved during the development of this technical solution:

- the creation of a cable, with reduced, in comparison with known cables, overall dimensions, while maintaining the required performance characteristics:

resistance of current-carrying conductors, corrosion, radiation resistance, fire resistance, resistance to vibrations and to the effects of elevated temperatures;

- creation of a multicore cable - with the number of cores in a wide range (up to 500 and more), and with increased flexibility, with the possibility of multiple bends when tracing it, while the bending radius should be no more than 70 mm and increased building length - the building length should be not less than 200 m;

- a combination of different types of subcables in one block cable, which have various functional purposes: power, control, signal, thermocouple, heat-sensitive, heat-resistant, or other cable options.

The technical results of the proposed technical solution are:

1. to increase the flexibility of the block cable, with the achievement of the minimum allowable bending radii - which provides more convenient tracing and installation. This result is achieved due to the fact that, as a rule, subcables of smaller diameters are located either in the intermediate or external layers, and subcables of large diameters are located in the central part of the block cable;

2. the ability to move the block cable - the connection object in different planes by increasing its flexibility, achieved by folding, if necessary, the block cable into a cylindrical spiral;

3. in the possibility of lengthening the block cable, rolled into a cylindrical spiral, to compensate for temperature effects;

4. to facilitate the installation of the block cable due to the fact that the permissible number of bends per 100 m of the route increases several times due to increased flexibility (cables can be bent in any plane repeatedly);

5. the possibility of combining in one block cable various types of subcables made independently of other subcables that have various functional purposes: power, control, signal, thermocouple, heat-sensitive, heat-resistant or other cable options, even after laying, the block cable can be transformed from a control to a power, or a combination thereof, or vice versa;

6. to increase reliability during operation in various extreme conditions (at high and low temperatures, at high pressure, in vacuum, in conditions of increased radiation) - due to the use of mineral insulation, in combination with the use of conductive cores and shells of various materials, resistant to the above factors, as well as due to the installation of pressure glands on this cable;

7. to the block cable, after its installation in the system, an additional connection can be made, because it is possible to manufacture it with backup lines;

8. Depending on the technical requirements, while maintaining increased flexibility and ease of installation, a cable with increased radiation resistance and fire resistance up to a temperature of 1400 degrees can be made. C and above through the use of heat-resistant materials;

9. “jacketing” operation can be performed with the block cable — the cable can be fully or partially protected by an additional sheath.

An image of a block cable is shown in FIG.

Figure 1 - cross section of a block cable with the number of subcables equal to 7 × 1.5 + 16 × 0.35.

where: 1 - conductive core with a cross section of 1.5 mm ² :

2 - isolation;

3 - shell;

4 - conductive core with a cross section of 0.35 mm ² ;

5 - insulation

6 - shell

The claimed technical solution is that: the design of the multi-core heat-resistant cable (hereinafter referred to as the block cable) is individual cables twisted into a block by known methods (hereinafter referred to as subcables), at the ends of the subcables there are terminal fittings or pressure leads.

Subcables are equipped with individual pressure glands, or special terminators.

Block cables, based on the technical requirements of flexibility, can have several types of coils. In this case, as a rule, subcables of smaller diameters are located either in the intermediate or in the outer layers, which can significantly increase the flexibility of the block cable. Moreover, the resulting block cable may consist of subcables intended for power lines, for communication lines, or for transmitting signals of a different purpose, i.e. a combination of various functions is achieved, which were previously performed by specialized cables, characterized by certain properties.

The block cable is made from a combination of one or multi-core subcables having the same or different number of current-carrying conductors, which can be round, or transformed, coated, with or without plating.

Subcables use conductive cores made of copper, copper alloys, aluminum, or aluminum alloys, heat-resistant, corrosion-resistant, or other

alloys insulated from the shell with mineral insulation, where not only copper and copper alloys can be used for the sub-cable shells, but also other materials, including those that are long-term resistant to aggressive environments and high temperatures, for example, stainless steel or its alloys, nickel-based alloys as well as alloys with molybdenum additives, etc. In a multicore heat-resistant cable, to increase its heat resistance, subcables can have several shells.

The block cable can be made in the form of a cylindrical spiral - to increase flexibility and compensate for elongation under thermal influences, as well as with possible movements of one of the connection objects.

Examples of block cable:

1. The block cable consists of 7 subcables with a cross-section of conductors 1.5 mm ² and 16 subcables with a cross-section of conductors 0.35 mm ² . The shells of the subcables are made of alloy 321 (08X18H10T), the inside of the shell is MgO mineral insulation, the core material is copper or copper alloys.

The outer diameter of the SK ₇ -1 × 1.5-3 mm.

Outer diameter CK ₁₆ -1 × 0.35-2 mm.

The overall overall dimension of the structure is a diameter of 13–13.1 mm. Cable construction length can exceed 200 meters. The minimum bending radius of the block cable is 70 mm.

2. The block cable consists of 7 subcables with a cross-section of conductors 1.5 mm ² and 18 subcables with a cross-section of conductors 0.35 mm ² . The sub-cable sheaths are made of alloys with special properties, ХН78Т, 316L, Inconel 600 or ЭП 747, with uniform or combined insulation, inside the shell - MgO mineral insulation, core materials are made of nickel or steel alloys, including corrosion-resistant and heat-resistant.

In subcables, MgO, Al ₂ O ₃ , SiO ₂ , BeO, HfO ₂ , or other materials with insulating properties intended for use in cables operating in a specified temperature range can be used as insulation. Current-carrying conductors may have additional coating or cladding.

The construction length of the block cable can reach over 200 m.

The block cable has high flexibility and can withstand prolonged exposure to high temperatures, aggressive environments at elevated temperatures, and also have vibration resistance, radiation resistance, fire resistance and impact resistance.

Claims (14)

1. A multi-core heat-resistant cable is made of separate subcables twisted together, where each of the subcables consists of: a heat-resistant sheath filled with mineral insulation, and one or more conductive cores made of corrosion-resistant heat-resistant materials: either copper or copper alloys or aluminum or aluminum alloys, while the mineral filler serves as an insulator between current-carrying conductors and the sheath, and the subcables are equipped with terminators and individual pressure glands. 2. A multi-core heat-resistant cable according to claim 1, characterized in that it has several coils, while subcables of smaller diameters are located either in the intermediate or in the outer coils. 3. A multi-core heat-resistant cable according to claim 1, characterized in that the block cable is made in the form of a cylindrical spiral to increase flexibility and compensate for elongation under temperature effects, as well as with possible movements of one of the connection objects. 5. Stranded heat-resistant cable according to claim 1, characterized in that it contains subcables with sheaths made of copper. 6. Stranded heat-resistant cable according to claim 1, characterized in that it includes subcables with shells made of copper alloys. 7. Stranded heat-resistant cable according to claim 1, characterized in that it contains subcables with sheaths made of aluminum. 8. Stranded heat-resistant cable according to claim 1, characterized in that it contains subcables with shells made of aluminum alloys. 9. Stranded heat-resistant cable according to claim 1, characterized in that it contains subcables with sheaths made of steel. 10. Stranded heat-resistant cable according to claim 1, characterized in that it contains subcables with sheaths made of steel alloys. 11. The multi-core heat-resistant cable according to claim 1, characterized in that in one block cable, the subcables consist of one or more power and / or signal and / or thermocouple and / or heat-sensitive and / or heat-resistant cables. 12. Stranded heat-resistant cable according to claim 1, characterized in that the operation of "jacketing" can be performed with a block cable. 13. Stranded heat-resistant cable according to claim 1, characterized in that the sheaths of the subcables are multilayer. 14. Stranded heat-resistant cable according to claim 1, characterized in that the current-carrying conductors in subcables are round in shape or can be transformed. 15. Stranded heat-resistant cable according to claim 1, characterized in that the current-carrying conductors are made with a coating or plating.