RU2388189C2 - Heat-resistant cable with alternation of "cold" and "hot" zones (three versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to cable items intended for use mainly in nuclear power engineering. According to the first version, cable consists of metal heat-resistant corrosion-resistant shell filled with mineral insulation and also of current conductor installed coaxially inside shell. Conductor is made of current-conducting material with high specific electric resistance and has various diametre in "cold" and "hit" zones, besides transfer from one zone to the other one is arranged as stepped. In cable according to the second version conductor is arranged as combined, with application of bimetal in zones with lower electric resistance. In cable according to the third version conductor is made as combined, with application of bimetal in "cold" zones, and with various diametre of current conductor in "cold" and "hot" zones, besides transfer from one zone to another one is arranged as stepped.

EFFECT: invention provides for highest accuracy of conductor division into zones and achievement of higher temperatures difference in "cold" and "hot" zones.

18 cl, 5 dwg, 3 ex

Description

This technical solution relates to the cable industry.

The design of cable products intended for use mainly in nuclear energy is claimed.

Heat-resistant cables with mineral insulation are known (See V.F. Suchkov, V.I. Svetlova, E.E. Finkel "Heat-resistant cables with magnesian insulation", M., Energy, 1969, p.3). The disadvantage of these cables is that they have constant heating over the entire length.

Cable products are known, namely tubular electric heaters, containing a heating element in the form of a wire of an alloy with high specific resistance, having leads at the ends and protected by an insulating filler, on top of which there is a metal sheath (this technical solution is described in WO 2005/117530). Such cable products have different heating at the end sections and in the heating zone. Different heating of the cable end sections is due to the fact that this cable is divided into zones - the heating element and the terminal sections - terminals. Each cable terminal is made of a low resistivity material mounted on the end of the heating element.

The disadvantage of this technical solution is that in this cable product there is only one heating - “hot” section of the cable.

Another significant drawback is that there is a rather long transition section between the “cold” and “hot” sections, in which the temperature gradually changes from low to high.

In the technology for the nuclear industry, there is a need for cable products with alternating “cold” and “hot” zones of a given length on different cable sections while maintaining a constant value of the outer diameter of the cable product over the entire length.

The authors solve this problem by using a cable with mineral insulation, having a sheath of corrosion-resistant heat-resistant alloys of steel, made in three versions.

TECHNICAL RESULT

The conductive conductor of the heat-resistant cable (hereinafter - the cable) is made of known materials - metals or their alloys with high electrical resistivity. Moreover, the claimed technical result according to the first embodiment is achieved by performing a conductive conductor having a sharp difference in the diameters of the conductive conductor in the “cold” and “hot” zones, i.e. the transition between the zones is made stepwise. The length of the "hot" zone is maintained with a given accuracy and has a deviation from the specified size of not more than ± 5 mm. The outer diameter of the cable remains unchanged along its entire length. The number of “cold” and “hot” zones and their sizes, as well as the temperature in these zones, is determined based on the technical requirements of operation. “Cold” and “hot” zones alternate in the order established by the customer, depending on the task assigned to the cable manufacturer. The current leads of the cable product are “cold”.

Figure 1 and Figure 2 presents the image of a heat-resistant cable with alternating "cold" and "hot" zones.

Figure 3 is a longitudinal section of a conductive conductor of a heat-resistant cable with alternating "cold" and "hot" zones, made in accordance with the first embodiment.

A heat-resistant cable is claimed to be used in internal reactor control systems, with alternation of “cold” and “hot” zones of a given length over various cable segments, while maintaining a constant outer diameter of the cable within 1.5 mm.

The cable consists of a sheath made of corrosion-resistant and / or heat-resistant alloy of steel filled with mineral insulation, and a conductive conductor located coaxially inside the sheath. The conductive conductor is made of a material with a high electrical resistivity. In the “cold” and “hot” zones, the conductive conductor has a different diameter, and the transition from a larger diameter to a smaller diameter is made stepwise.

Due to this, the electrical resistance of the sections of "cold" and "hot" zones differs from each other within the specified limits of the length of these zones. The dimensions of the “cold” and “hot” zones are set in accordance with the technical requirements. Conducting conclusions of a cable product are made "cold".

Execution example

A heat-resistant cable with alternating “cold” and “hot” zones is made 17.8 m long, while maintaining the outer diameter of the cable product within 1.5 mm. The insulation is made of MgO or Al ₂ O ₃ . The conductive conductor can be made of nichrome or nickel and its alloys, steel alloys, 204 alloys, copper alloys. The diameter of the conductive conductor in the "cold" zone is 0.6 mm, in the "hot" - 0.3 mm. The number of zones and their extent are established by the customer's technical requirements.

Heat-resistant cable with alternating "cold" and "hot" zones (second option)

The analogs for the cable made according to the second embodiment are the same analogues as for the cable according to the first embodiment.

TECHNICAL RESULT

In the technology for the nuclear industry, there is a need for cable products with alternating “cold” and “hot” zones of a given length on different cable sections while maintaining a constant value of the outer diameter of the cable product over the entire length.

The authors solve this problem by using a cable with mineral insulation, having a sheath of corrosion-resistant steel alloys. Moreover, the claimed technical result according to the second embodiment is achieved by performing a conductive conductor having the same diameter in “cold” and “hot” zones. Moreover, this conductor is made using bimetal in cold zones. Due to this, the length of the "hot" zone is performed with a given accuracy and may deviate from a given size along the length of not more than ± 5 mm. The outer diameter of the cable remains unchanged along its entire length. The number of “cold” and “hot” zones and their sizes, as well as the temperature in these zones, is determined based on the technical requirements of operation. “Cold” and “hot” zones alternate in the order established by the customer, depending on the task assigned to the cable manufacturer. The current leads of the cable product are “cold”.

A longitudinal section of a conductive conductor of a heat-resistant cable with alternating “cold” and “hot” zones made in accordance with the second embodiment is shown in FIG. 4, where 1 is a conductive layer of material with high electrical resistivity, 2 is a conductive layer of material with low electrical resistivity electrical resistance.

A heat-resistant cable is claimed to be used in internal reactor control systems, with alternation of “cold” and “hot” zones of a given length over various cable segments, while maintaining a constant outer diameter of the cable within 1.5 mm. The cable consists of a metal sheath made of corrosion-resistant materials filled with mineral insulation and a conductive conductor located coaxially inside the sheath. The conductive conductor is made combined with the use of bimetal in "cold" zones. In "cold" zones, the conductive conductor is made of an inner layer of a conductor with a higher electrical resistivity, for example, nichrome, and an outer layer having a lower electrical resistivity, using copper or alloy 204.

The diameter of the layer of a conductive conductor with a high electrical resistivity is 0.3 mm, the diameter of a conductive conductor with a low electrical resistivity in the outer layer is 0.6 mm. By alternating the bimetallic sections and the sections of the conductive conductor with high resistance, “cold” and “hot” zones are created. In both “cold” and “hot” zones, the conductive conductor has the same diameter.

The dimensions of the “cold” and “hot” zones are set in accordance with the technical requirements.

Conducting conclusions of a cable product are made "cold".

The materials used to create the “cold” and “hot” zones of the cable are selected depending on the operating temperatures.

Execution example. The second embodiment of a heat-resistant cable with alternating "cold" and "hot" zones

The "hot section" of the conductive cable conductor is made of nichrome (X20N80-N), and the "cold section" of the conductive conductor is made:

- from the inner layer - a conductor of nichrome with higher resistance,

and an outer layer having a lower resistance, using copper or alloy 204.

The diameter of the inner conductor is 0.3 mm, and the thickness of the upper layer is 0.15 mm.

A heat-resistant cable with alternating “cold” and “hot” zones is made 15.5 m long, while maintaining the outer diameter of the cable product within 1.5 mm.

The insulation is made of MgO or Al ₂ O ₃ .

Heat-resistant cable with alternating "cold" and "hot" zones (third option)

The analogs for the cable made according to the third embodiment are the same analogues as for the cable according to the first embodiment.

TECHNICAL RESULT

In the technology for the nuclear industry, there is a need for cable products with alternating “cold” and “hot” zones of a given length on different cable sections while maintaining a constant value of the outer diameter of the cable product over the entire length within 1.5 mm.

The authors solve this problem by using a cable with mineral insulation, having a sheath of corrosion-resistant materials.

The conductive cable conductor is made of known materials with high electrical resistivity. Moreover, the claimed technical result according to the third embodiment is achieved by performing a conductive conductor combined, using bimetal having different electrical resistivity of the “cold” and “hot” zones, while having a sharp difference in the diameters of the conductive conductor to “cold” and “ hot zones, i.e. the transition between the zones is made stepwise. Due to this, the length of the "hot" zone is performed with a given accuracy and may deviate from a given size along the length of not more than ± 5 mm.

A third embodiment of a longitudinal section of a conductive conductor of a heat-resistant cable with alternating “cold” and “hot” zones is shown in FIG. 5, where 1 is a conductive layer of material with high electrical resistivity, 2 is a conductive layer of material with low electrical resistivity.

A heat-resistant cable is claimed to be used in internal reactor control systems, with alternation of “cold” and “hot” zones of a given length over various cable segments, while maintaining a constant outer diameter of the cable within 1.5 mm. The cable consists of a sheath made of corrosion-resistant materials filled with mineral insulation, and a conductive conductor located coaxially inside the sheath. The conductive conductor is combined: in the "hot" zones it has a high electrical resistivity, and in the "cold" zones the conductor is made of bimetal, where the inner layer of the bimetal is a continuation of the conductive conductor of the "hot" zone and has a high resistivity, and the external one is low specific electrical resistance.

In “cold” and “hot” zones, the conductive conductor has a different diameter.

A sharp difference is created between the diameters of the conductive conductor in the “cold” and “hot” zones, i.e. the transition between the zones is made stepwise. At the same time, the best result is achieved compared to cables manufactured according to the first and second options.

The outer diameter of the cable remains unchanged along its entire length.

The number of “cold” and “hot” zones and their sizes, as well as the temperature in these zones, is determined based on the technical requirements of operation.

“Cold” and “hot” zones alternate in the order established by the customer, depending on the task assigned to the cable manufacturer.

Conducting conclusions of a cable product are carried out "cold".

The materials used to create the “cold” and “hot” zones of the cable are selected depending on the operating temperatures.

Execution example

A heat-resistant cable with alternating “cold” and “hot” zones is made 15.2 m long, while maintaining the outer diameter of the cable product within 1.5 mm.

The insulation is made of MgO or Al ₂ O ₃ . The "hot section" of the conductive cable conductor is made of nichrome (X20N80-N), and the "cold section" of the conductive conductor is made:

- from the inner layer - from nichrome, a conductor with a higher electrical resistivity,

and an outer layer having a lower electrical resistivity, using copper or alloy 204.

The diameter of the inner conductor is 0.3 mm, and the diameter of the conductor along the upper layer is 0.6 mm.

According to the first, second and third options, the heat-resistant cable can be transformed and made U-shaped with a combination of symmetrically located “cold” and “hot” zones.

Claims (18)

1. The cable used in the internal reactor control systems, with the outer diameter of the cable product not exceeding 1.5 mm, consisting of a metal heat-resistant corrosion-resistant sheath filled with mineral insulation, as well as a conductive conductor located inside the sheath coaxially, while the conductor made of conductive material with high electrical resistivity and has a different diameter in the “cold” and “hot” zones, and the transition from a larger diameter to a smaller step process. 2. The cable according to claim 1, characterized in that the length of the zones is different. 3. The cable according to claim 1, characterized in that the "hot" and "cold" zones alternate in the prescribed manner. 4. The cable according to claim 1, characterized in that the length of the "hot" zones is performed with a deviation in length of not more than ± 5 mm. 5. The cable according to claim 1, characterized in that it is transformed into an element with double addition and with the combination of symmetrically located "cold" and "hot" zones. 6. The cable according to claim 1, characterized in that its current-carrying terminals are made "cold". 7. The cable used in the internal reactor control systems with the outer diameter of the cable product not exceeding 1.5 mm, consisting of a metal heat-resistant corrosion-resistant sheath filled with mineral insulation, as well as a conductive conductor of constant cross section located inside the sheath coaxially, with This conductor is made combined: in "hot" zones it has a high electrical resistivity, and in "cold" zones the conductor is made of bimetal, where the inner layer of bimetal is It is a continuation of the conductive conductor of the “hot” zone and has a high resistivity, while the external one has a low resistivity. 8. The cable according to claim 7, characterized in that the length of the zones is different. 9. The cable according to claim 7, characterized in that the "hot" and "cold" zones alternate in the prescribed manner. 10. The cable according to claim 7, characterized in that the length of the "hot" zone is performed with a deviation in length of not more than ± 5 mm. 11. The cable according to claim 7, characterized in that it is transformed into an element with double addition and with the combination of symmetrically located "cold" and "hot" zones. 12. The cable according to claim 7, characterized in that its current-carrying terminals are made "cold". 13. The cable used in the internal reactor control systems with the outer diameter of the cable product not exceeding 1.5 mm, consisting of a metal heat-resistant corrosion-resistant sheath filled with mineral insulation, as well as a conductive conductor having a different diameter in the “cold” and "Hot" zones, and the transition from a larger diameter to a smaller one is made stepwise;
the conductive conductor is located inside the shell coaxially and is combined: in the "hot" zones it has a high electrical resistivity, and in the "cold" zones the conductor is made of bimetal, where the inner layer of the bimetal is a continuation of the conductive conductor of the "hot" zone and has a high resistivity, and the outer layer of bimetal is made of a material with a lower electrical resistivity. 14. The cable according to item 13, wherein the length of the zones is different. 15. The cable according to item 13, wherein the "hot" and "cold" zones alternate in the prescribed manner. 16. The cable according to item 13, wherein the length of the "hot" zone is performed with a deviation in length of not more than ± 5 mm. 17. The cable according to item 13, characterized in that it is transformed into an element with double addition, with a combination of symmetrically located "cold" and "hot" zones. 18. The cable according to item 13, characterized in that its current-carrying conclusions are made "cold".

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