RU151222U1 - HEAVY-LOADED HEAT-RESISTANT CABLE WITH TERMINAL FITTINGS - Google Patents

Abstract

1. A heavily loaded heat-resistant cable with terminal fittings, consisting of a heat-resistant cable made of a metal sheath filled with mineral insulation, in which a conductive core, which is a "hot" zone, is placed; in this case, the terminal fittings have a metal casing through which the conductive core passes - a continuation of the current-carrying cable core; the terminal box body is hermetically connected to the metal sheath of the cable and filled with mineral insulation; on the end surface of the mineral insulation of the terminal reinforcement there is a seal, characterized in that the range of its operating temperature is in the range from 400 ° C to 500 ° C, the terminal reinforcement is designed to be connected to a power source, while the conductive core passing inside the terminal reinforcement casing includes the hot and cold zones, as well as the transitional section between these zones from 8 to 10 mm in size, where the cross section of the cold zone exceeds the cross section of the hot zone by at least 2 times; the output of the conductive core connected to the power source ends with a "cold" zone; inside the terminal box there is mineral insulation with increased density up to 2.8 g / cm, the volume of which is 4-5 times higher than the volume of mineral insulation inside the cable of the same length as the length of the terminal box. 2. The cable according to claim 1, characterized in that the sealing is performed as follows: inside the terminal fitting body, a layer of insulating sealant is applied above the end face of mineral insulation, then an insulating tube is put on the conductive core, which is pressed on top

Description

The technical solution claimed as a utility model relates to the cable industry and is intended to ensure reliable operation of heat-resistant cables at an operating temperature of 400 ° C to 500 ° C.

Currently, there is an urgent need to complete critical products with mineral insulated cables in metal shells with termination fittings with a given life time for failure with an operating temperature of 400 to 500 ° C.

Known variants of terminal fittings for sealing heat-resistant cables with mineral insulation in copper sheaths of the design ЗК КМЖ 01, 02, 03, designed for operation at a maximum temperature of up to 250 ° C.

Known technical solutions for sealing tubular electric heaters (Tubular electric heaters and installations with their use "Yu. A. Belavin, MA Evstigneev, AN Chernovsky // Text, Belavin Yu.A., Evstigneev MA Chernovskiy A.N., M., Energoatomizdat, 1989, p. 20-22). At the same time, the temperature in the TENa sealing unit is from 200 ° C to 400 ° C, which is completely unacceptable for connecting a heat-resistant cable to power sources and using them at special facilities.

Known electric tubular heater, which can be attributed to cable products with terminal fittings (see (19) RU, (13) U1 (11) 41511 (51) IPC ⁷ F24H 3/04 (54) ELECTRIC HEATER TUBULAR).

The tubular electric heater consists of a heating element in the form of a wire of precision alloys with high specific electrical resistance and a tube of materials with low electrical resistance pressed over it, which is cold leads 0.5 to 3.3 m long. Insulating silicone sealant protects the ends of the electric heater and conclusions. The metal shell is pressed into the ends of the heating element.

The disadvantage of electric heaters of this design, with terminal fittings, are the increased overall dimensions of the “cold” terminals, low current load. The specified design is not intended for operation as part of a responsible facility under extreme conditions and high current loads, significantly exceeding the loads in analogues.

The closest in functionality to the claimed heavy-loaded heat-resistant cable with termination fittings is termination of the cable end with a metal sheath (see (19) RU (11) 2206164 (51) IPC 7 H02G 15/23, (54) Sealed and heat-resistant termination of the cable end with a metal shell). In this cable, the metal cores of the cable are separated from one another and from the sheath by mineral insulation. This seal contains a sealing element with holes for passing the veins, formed by melting during heating and subsequent solidification during cooling of the glass, as well as a gasket placed close to the inner end of the sealing element. A metal sleeve is fitted and sealed on the shell end portion of the shell, in the cavity of which a sealing element and gasket are placed. The sleeve can be planted on the shell until it stops at the end of the shell, while the inner diameter of the sleeve near the end of the shell is less than the inner diameter of the shell.

The technical solutions indicated in the patent (19) RU (11) 2206164 (51) for the sealing of cable ends with mineral insulation in metal sheaths by metal caps have a number of certain disadvantages:

- for different materials of conductors and cable sheaths, as well as for different thicknesses of shells and core diameters, different brands of ceramic may be required, or new design solutions should be used;

- varieties of designs for sealing the ends of heat-resistant cables in steel sheaths from 08X18H9T alloy with copper conductors and magnesian insulation are intended for penetration of these cables by short lengths through strong walls (partitions). At the same time, the operating modes of the cables for current loads and operating temperature do not exceed permissible parameters for the operating personnel environment and are not intended for operation at temperatures from 400 ° C to 500 ° C;

- tubes of alloy 321 (08X18HN9T), dressed on current-carrying conductors, do not have reliable contact with them along the entire length and create conditions for increasing the temperature of the conductive core and possible failure during sufficiently long operation due to oxidative processes that take place along this length tubes;

- terminations do not provide stringent requirements for reliability due to their very high thermal conductivity, and also because of restrictions on the temperature of use, since they can be used in emergency situations at a temperature of no more than 600 ° C.

In order to connect the cable specified in the patent with a tight and heat-resistant termination of the cable end to the power source, an intermediate connector and a power cable of a different design with increased overall dimensions and low temperature of application are used.

The task set for the developers of the claimed design is to create a product with reliable small-sized termination fittings, which would provide without external additional transition devices a temperature drop in the conductive core from 500 ° C to a parameter not exceeding the ambient temperature by more than 50 ° C.

Technical results of the claimed technical solution:

- reduction of the operating temperature from 400 ÷ 500 ° C to a value not exceeding the ambient temperature by more than 45 ° C on the conductive core of the cable connected to the power source without the use of couplings and a larger cable with a decrease in the length of the terminal fittings to a value of no more 250 mm.

The specified technical result is due to the use of the following essential features in the claimed design:

- execution inside the terminal armature of the section of the conductive core of the cable, consisting of "hot" and "cold" zones with a smooth transition between them with a length of 8 to 10 mm, while the cross section of the "cold" zone of the conductive core of the cable exceeds the section of the "hot" zone of this core not less than 2 times, and the withdrawal of the conductive core from the terminal fittings is a “cold” zone;

- the passage of the “cold” output in the mineral insulation sealed up to 2.8 g / cm ³ , which is 4-5 times larger than the volume of the same mineral insulation inside the cable, equal to the length of the terminal box body, which creates an effective heat removal and minimizes as much as possible temperature on the surface of the conductive core to a minimum close to the ambient temperature, while increasing the reliability of the terminal fittings.

An additional increase in reliability is achieved:

- the use of materials of the same chemical compositions for the cases of terminal fittings and cable sheaths;

- the execution of the walls of the body of the terminal reinforcement of corrosion-resistant and heat-resistant alloy with a thickness of 2-3 mm;

- making a tight connection between the sheath of a heavily loaded heat-resistant cable and the body of the terminal fittings using either welding (laser, or argon-arc) or high-temperature soldering, ensuring the operability of the product at a temperature of at least 700 ° C and reliability when exposed to increased radiation on this cable, shock and vibration;

- minimizing the overall dimensions of the terminal reinforcement by reducing the length of the transition between the "hot" and "cold" zones.

The protection of the end surface of the mineral insulation of the terminal reinforcement, which has the definition of "sealing" in the analog, can be carried out in two ways:

- either a layer of insulating sealant is applied over the end face of the mineral insulation inside the terminal box body, then an insulating tube is put on the conductive core, which is pressed from above by the insulating disk. An intermediate washer is superimposed on this disc from above, which is fixed with a nut by connecting to the body of the terminal fittings;

- either cermet with zero porosity and a purity of ceramic material of 99.97%, designed for voltages up to 3 kV and operating temperature up to 900 ° C, is additionally mounted on the case of terminal fittings.

For reference: by the concept of "Armature" we mean special typical details - protective protectors. (Wikipedia)

Description of the claimed technical solution

Heavily loaded heat-resistant cable with terminal fittings, designed to operate at elevated temperatures (from 400 ° C to 500 ° C), connected to a power source, made of a metal sheath filled with mineral insulation, in which a live conductor is placed. Termination fittings have a metal casing filled with mineral insulation, as well as sealing the end surface.

A conductive conductor passes through the terminal fittings - a continuation of the conductive cable core, which inside the cable has an operating temperature in the range from 400 ° C to 500 ° C. At the entrance to the terminal fittings, the conductive core can be considered as a “hot zone”. Inside the terminal fitting case, a transition was made from the “hot” zone of the conductive core to the “cold” one, having a cross section increased in relation to the cross section of the conductive cable core by at least 2 times. At the output of the terminal armature, the conductive core has a “cold” zone. The length of the transition of the conductive core from the "hot" zone to the "cold" is from 8 to 10 mm.

The metal sheath of the cable and the case of the terminal fittings are made of the same material - corrosion-resistant and heat-resistant alloy, for example, from 08Kh18N10T alloy and filled with mineral insulation - for example, MgO or Al ₂ O ₃ .

The wall thickness of the terminal box body can be 2-3 mm.

High density insulation up to 2.8 g / cm ³ , the volume of which is 4-5 times greater than the volume of mineral insulation inside the cable of the same length as the length of the sheathing of the terminal reinforcement, was used inside the terminal box body.

The metal case of the terminal fittings is mounted on top of the metal sheath of the cable and attached to it by either welding (laser or argon-arc) or by high-temperature soldering.

Sealing - protection of the end surface of the mineral insulation of the terminal reinforcement can be carried out as follows:

a) a layer of insulating sealant is applied over the end face of the mineral insulation inside the terminal box body; an insulating tube is put on a conductive core; an insulating disk is laid on top of the insulating sealant layer and the insulating tube, an intermediate washer is placed on it, which is fixed with a nut by connecting it to the end fitting body;

b) metal ceramics with zero porosity and a purity of ceramic material of 99.97%, designed for voltages up to 3 kV and operating temperature up to 900 ° C, is additionally mounted on the case of terminal fittings.

The essence of the utility model is illustrated by the image of the reinforcement in FIG. 1 and 2, where:

1 - current-carrying core of the "cold" zone;

2 - insulating tube;

3 - an intermediate washer;

4 - fixing nut;

5 - an isolating disk;

6 - insulating sealant;

7 - terminal box body;

8 - compacted mineral insulation;

9 - current-carrying core of a heavily loaded cable;

10 - mineral insulation of the cable;

11 - sheath of a heavily loaded cable;

12 - cermets.

Reinforcement example:

1 Termination fittings are mounted on the ends of a square cable with a conductive core of copper alloy with niobium and chromium, mineral insulation of magnesium oxide (MgO) and a sheath of alloy 08X18H10T. The operating temperature of the cable under cyclic loading is in the range from 400 ° C to 500 ° C. The valve body is made of 08X18H10T alloy. Fastening the terminal box body to the cable sheath using high-temperature soldering with a working temperature of up to 700 ° C. The cross section of the “cold” terminal, round in shape, exceeds the cross section of the conductive core inside the cable by 3 times.

Claims (11)

1. A heavily loaded heat-resistant cable with terminal fittings, consisting of a heat-resistant cable made of a metal sheath filled with mineral insulation, in which a conductive core, which is a "hot" zone, is placed; in this case, the terminal fittings have a metal casing through which the conductive core passes - a continuation of the current-carrying cable core; the terminal box body is hermetically connected to the metal sheath of the cable and filled with mineral insulation; on the end surface of the mineral insulation of the terminal reinforcement there is a seal, characterized in that the range of its operating temperature is in the range from 400 ° C to 500 ° C, the terminal reinforcement is designed to be connected to a power source, while the conductive core passing inside the terminal reinforcement casing includes the hot and cold zones, as well as the transitional section between these zones from 8 to 10 mm in size, where the cross section of the cold zone exceeds the cross section of the hot zone by at least 2 times; the output of the conductive core connected to the power source ends with a "cold"zone; inside the terminal box there is mineral insulation with increased density up to 2.8 g / cm ³ , the volume of which is 4-5 times higher than the volume of mineral insulation inside the cable of the same length as the length of the terminal box. 2. The cable according to claim 1, characterized in that the sealing is performed as follows: a layer of insulating sealant is applied on the inside of the terminal reinforcement casing above the end of the mineral insulation, then an insulating tube is put on the conductive core, which is pressed on top by an insulating disk, an intermediate one is applied on top of the disk a washer fixed by a nut by connecting to the body of the terminal fittings. 3. The cable according to claim 1, characterized in that the sealing is performed as follows: metal ceramics with zero porosity and a purity of ceramic material of 99.97%, designed for voltages up to 3 kV and operating temperature up to 900 ° C, are mounted on the case of terminal fittings. 4. The cable according to claim 1, characterized in that the wall thickness of the terminal box body is 2-3 mm. 5. The cable according to claim 1, characterized in that the hermetic connection of the cable sheath with the sheath of the terminal fittings is performed using laser welding. 6. The cable according to claim 1, characterized in that the hermetic connection of the cable sheath with the terminal box body is made using argon-arc welding. 7. The cable according to claim 1, characterized in that the hermetic connection of the cable sheath with the body of the terminal fittings is made using high-temperature soldering. 8. The cable according to claim 1, characterized in that the cable sheath and the terminal box body are made of 08X18H10T alloy. 9. The cable according to claim 1, characterized in that the cable sheath and the body of the terminal fittings are filled with sealed mineral MgO insulation. 10. The cable according to claim 1, characterized in that the cable sheath and the body of the terminal fittings are filled with sealed mineral insulation Al ₂ O ₃ . 11. The cable according to claim 1, characterized in that the cable sheath and the terminal box body are made of the same materials - heat-resistant and corrosion-resistant alloys of the same chemical composition.

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