RU198663U1 - HIGH VOLTAGE CURRENT LIMITING DEVICE - Google Patents

Abstract

The utility model relates to the field of electrical engineering, in particular, to current-limiting devices based on high-temperature superconductivity (hereinafter referred to as HTSC TOU) operating in a liquid nitrogen environment in networks with a voltage of 35-750 kV. In particular, to a decrease in the electric field strength between the current-limiting element and a grounded cryostat and, as a consequence, to an increase in the dielectric strength of the device. High-voltage current-limiting device based on high-temperature superconductivity, containing a cryostat, a current-limiting element located in the cryostat on a central support and consisting of coaxially located current-limiting modules with insulated lead-in and outlet-out current leads, support insulators, where each insulator is made in the form of a solid rod with a groove, one of the ends of the said insulator, and the platform, each of which is provided with a protrusion, while each support insulator is fixed at one end on the central support, and at the other end is attached to the platform with the formation of a "groove-protrusion" connection and is equipped with a protective screen placed on the platform coaxial to the insulator. Thanks to the protective screen, the strength of the electric field generated by the platform near the base of the support insulator is reduced by almost three times, which leads to an increase in the dielectric strength of the current-limiting device with a voltage of up to 750 kV, operating in a liquid nitrogen environment.

Description

AREA OF TECHNOLOGY

The utility model relates to the field of electrical engineering, in particular to current-limiting devices based on high-temperature superconductivity (hereinafter referred to as HTSC TOU) operating in liquid nitrogen in 35-750 kV networks. In particular, to a decrease in the electric field strength between the current-limiting element and a grounded cryostat and, as a consequence, to an increase in the dielectric strength of the device.

LEVEL OF TECHNOLOGY.

Patent RU194013 (ZAO SuperOx) discloses a high-voltage current-limiting device based on high-temperature superconductivity, containing a cryostat, an assembly of coaxially located superconducting current-limiting modules located in a cryostat on a central support, where the assembly is mounted on supporting insulators, while the insulators in each pair are fixed at one end on the central support, and others are attached to the inner surface of the cryostat, as well as supply and output insulated current leads connecting the module assembly to the electrical network. The insulators are attached to the inner surface of the cryostat by means of a strip that is connected to the surface of the cryostat by welding or soldering. In this case, the insulator is made with a groove, and the bar is made with a counter ledge.

As follows from the description of the known utility model, with the chosen geometry of the supporting insulator, the electric field strength becomes less than 2.5 kV / mm already at a distance of 150 mm from the cryostat surface, and decreases as it approaches the cryostat surface.

In this case, there is a danger of an increase in tension at the corners of the platform with a protrusion, which is welded to the inner wall of the cryostat. At these angles, increased values of the electric field intensity appear, which in turn can lead to an electrical breakdown, and therefore to a loss of the electric strength of the HTSC TOU itself with a voltage of up to 750 kV, operating in a liquid nitrogen environment.

All this presents certain technical problems during the operation of the HTSC TOU.

DISCLOSURE OF THE USEFUL MODEL

The task of the utility model is to eliminate these technical problems.

The problem is solved by a high-voltage current-limiting device based on high-temperature superconductivity, containing a cryostat, a current-limiting element located in the cryostat on a central support and consisting of coaxially located current-limiting modules with insulated lead-in and outlet-out current leads, support insulators, where each insulator is made in the form of a groove located at one of the ends of the said insulator, and platforms, each of which is provided with a protrusion, while each support insulator is fixed at one end to the central support, and the other is attached to the platform with the formation of a groove-protrusion connection and is equipped with a protective screen, placed on the platform coaxially with the insulator.

In particular embodiments of the utility model, the task is solved by a high-voltage current-limiting device, in which the protective screen has the shape of a surface of revolution.

In this case, the protective screen of the claimed high-voltage current-limiting device can be one or more toroids located on the platform coaxially with the support insulator.

The protective screen in the declared high-voltage current-limiting device can be made of stainless steel.

In a high voltage current limiting device, the platform can be fixed to the inner wall of the cryostat by welding.

The groove of the support insulator and the protrusion of the platform in the claimed high-voltage current-limiting device may have a conical shape with a rounded top.

The support insulator can be made of fiberglass and can have a partially corrugated outer surface.

The platform can be in the form of a disc.

In a high-voltage current-limiting device, the protective screen can be made removable.

In the grooves of each support insulator of the claimed high-voltage current-limiting device, a cylindrical sleeve with a bottom can be fixed, shielding the said platform protrusion.

BRIEF DESCRIPTION OF DRAWINGS.

FIG. 1 shows a schematic representation of an HTSC TOU.

FIG. 2 shows a schematic representation of a platform with a post insulator assembly.

FIG. 3 shows a schematic representation of a platform with a projection and a protective shield.

Figure 4 shows data illustrating the calculation of the electric field strength without using a protective shield.

Figure 5 shows data illustrating the calculation of the electric field strength using a protective shield.

Positions mean the following.

1. Cryostat

2. Current-limiting element

3. Current limiting module

4. Central support

5. Support insulator

6. Lead current lead

7. Outlet current lead

8. Support insulator groove

9. Coupling sleeve

10. Ledge

11. Flat platform

12. Protective screen

13. Fastener

The essence of the proposed utility model is as follows.

HTSC TOU consists of several basic elements (see Fig. 1): a cryostat (1), consisting of two cylindrical barrels, an internal one filled with a coolant that also performs electrical insulating functions, and an external one, separated by a vacuum cavity; current-limiting element (2), which is an assembly of current-limiting modules (3), coaxially located on the central support (4) and located inside the cryostat, at least on two pairs of support insulators (5).

Each current-limiting module (3) is a bifilar coil made of HTSC wire. The HTSC current-limiting element (2) is at the potential of the high voltage supplied with the help of current leads (6, 7), and the cryostat is grounded.

Support insulators (5) are made in the form of fiberglass rods with a groove (8) on the lower part of the support insulator (5). As a fiberglass, fiberglass can be used, for example, based on epoxy resin and fiberglass. The support rod from such a PCB is easy to manufacture with low economic investment, while it provides the required mechanical strength, has a high degree of fire resistance, and is suitable for operation at extremely low temperatures.

It is advisable that a part of the surface of the support insulator is corrugated.

Support insulators are fixed on the support at one end. Fixation can be carried out as follows: the ends of the support insulators (5) in the form of a cylindrical shape are inserted into the grooves of the bifurcated connecting sleeve (9) installed on the central support (4) of the current-limiting element (2). Opposite ends of insulators (5) with grooves (8) (see Fig. 2) rest on protrusions (10) on a flat platform (11). It is advisable, but not necessary, to make the grooves (8) and protrusions (10) in the form of mutually arranged cones with a smoothed top, which additionally provides easy installation and reliable fixation with a more uniform field pattern and helps to reduce the electric field strength in this zone.

On a flat platform (11) (Fig. 3), a protective screen (12) is rigidly fixed. It is desirable that the screen has the shape of a body of revolution, for example, a toroid.

A screen in the form of a toroid or several equivalent toroids, placed, for example, one above the other, provides the required level of dielectric strength of the device.

It is also desirable that the protective shield is made of stainless steel, which ensures its corrosion resistance and strength in a cryogenic environment, as well as a long service life.

The shield (12) is installed coaxially with both the support insulator (5) and the ledge (10) on the platform (11).

The screen (12) can be removable, which makes it easy to replace if necessary. Fasteners (13) are used to install the screen on the platform (see Fig. 3).

The platform (11) has a flat shape and can be made in the most ergonomic shape in the form of a disk, which is important for the flat surface of the cryostat bottom and allows one to get rid of high values of the electric field strength arising at the corners of platforms made, for example, in the form of a parallelepiped.

The platform (11) is fixed on the inner surface of the cryostat (1) in any possible way; in the claimed utility model, it is attached by welding.

As indicated, the current supply and drainage is carried out by supply (6) and discharge (7) current leads connected at one end with a current-limiting element (2) made of HTSC current-limiting modules (3), and at the other end with an electric network.

In the grooves of each support insulator of the claimed high-voltage current-limiting device, a cylindrical sleeve with a bottom (not shown), shielding the platform protrusion, can be fixed. The presence of a sleeve with a bottom allows to reduce the growth of tension in the region of the "groove-protrusion" connection, which also has a positive effect on the electrical strength of the HTSC TOU.

An example of a utility model implementation.

The protective screens (12) were made of stainless steel AISI 304 and had the shape of toroids. Screens (12) were installed on platforms (11) by welding to fasteners (13). On the platforms, protrusions (10) were also mounted, the shape of which corresponded to the shape of the grooves (8) of the support insulators (5), which made it possible to fix the current-limiting element (2) on the platform (11). Both protrusions and grooves were tapered with a rounded top.

Platforms (11) were welded to the inner surface of the cryostat (1): to ensure reliable fixation of the lower part of the support insulator (5), the platform (11) had a flat, flat base and was welded to the inner surface of the lower part of the cryostat (1), which has a cylindrical shape, on two adjacent edges.

The support insulator (5) with its lower end with a groove (8) was fixed on the protrusion (10).

A current-limiting element (2) was mounted on the central support (4), consisting of current-limiting modules (3) successively threaded onto the support, made in the form of bifilar coils made of HTSC wire.

The upper ends of the cylindrical support insulators (5) were fixed in the grooves of the bifurcated stainless steel connecting sleeve (9) mounted on the central support (4).

A high voltage was applied to the current-limiting device using current leads (6, 7), and the cryostat was grounded.

To assess the effectiveness of the use of protective screens, a computer simulation by the finite element method of three-dimensional models was carried out using the Comsol Multiphysics 5.3a software.

FIG. 4 and FIG. 5 shows the data on the distribution of the electric field strength in the section at the point of attachment of the support insulator to the platform with a conical protrusion for cases without a protective shield near the platform (Fig. 4) and with a protective shield (Fig. 5), respectively, obtained as a result of simulation.

As follows from the given data, the protective shield reduces the strength of the electric field created by the platform near the base of the support insulator by almost three times - from 2.0 kV / mm to 0.7 kV / mm, and the maximum electric field strength in this zone decreases by 10% - from 3.4 kV / mm to 3.1 kV / mm for the applied voltage to the HTSC current-limiting element 460 kV, which is an increased voltage for the class of high-voltage devices 220 kV.

Claims (10)

1. High-voltage current-limiting device based on high-temperature superconductivity, containing a cryostat, a current-limiting element located in the cryostat on a central support and consisting of coaxially located current-limiting modules with insulated lead-in and outlet-out current leads, support insulators, where each insulator is made in the form of a solid rod with a groove, located at one of the ends of the said insulator, and platforms, each of which is provided with a protrusion, while each support insulator is fixed at one end on the central support, and at the other end is attached to the platform with the formation of a "groove-protrusion" connection and is equipped with a protective screen placed on platform coaxially with the insulator. 2. The high voltage current limiting device according to claim 1, wherein the protective shield has the shape of a surface of revolution. 3. High-voltage current-limiting device according to claim 2, in which the protective screen is one or more toroids located on the platform coaxially with the support insulator. 4. The high voltage current limiting device according to claim 1, wherein the protective shield is made of stainless steel. 5. The high-voltage current-limiting device according to claim 1, wherein the platform is attached to the inner wall of the cryostat by welding. 6. The high voltage current limiting device of claim 1, wherein the support insulator slot and the platform protrusion are tapered with a rounded top. 7. High-voltage current-limiting device according to claim. 1, in which the support insulator is made of fiberglass and has a partially corrugated outer surface. 8. The high voltage current limiting device of claim 1, wherein the platform is disk-shaped. 9. The high-voltage current-limiting device according to claim 1, wherein the protective shield is removable. 10. The high-voltage current-limiting device according to claim 1, in which a cylindrical sleeve with a bottom is fixed in the grooves of each support insulator, shielding said platform protrusion.

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