RU2302050C1 - Surge limiter - Google Patents

Abstract

FIELD: electrical engineering; protection of high-voltage equipment insulation against atmospheric and switching voltage surges.

SUBSTANCE: proposed surge limiter has composite-material ground insulation tube lined with tracking-shielding ribs installed on its external cylindrical surface reinforced by terminators, at least one stack of spring-compressed coaxially joined varistor disks which is disposed between these ribs within ground-insulation tube and connected through shunt to upper terminator; space between internal cylindrical surface of ground insulation tube and stack is filled with heat-conducting insulating compound; terminator is joined to ground-insulation tube with aid of at least one flexible key installed through entry hole in keyway formed by ground insulation tube slot and terminator one; flexible key axis lies in plane perpendicular to ground insulation tube axis; tangent plane to flexible key axis is parallel to ground insulation tube axis.

EFFECT: enhanced explosion safety of surge limiter due to joining terminator and ground insulation tube with aid of flexible key.

5 cl, 11 dwg

Description

The invention relates to electrical engineering, in particular to devices for protecting the insulation of high-voltage equipment of electrical networks and stations from atmospheric and short-term switching overvoltages.

Known "Surge arrester for surge protection" according to the patent of Russian Federation No. 2145743, which contains a package of several cylindrical varistor disks mounted axially next to each other between the lower and upper end electrodes and surrounded by an elongated insulating outer casing made of rubber or other polymeric material, end electrodes are connected to each other by means of tightening elements in the form of at least three clamps from a continuously wound strand of insulating material to achieve the required contact pressure in the varistor disk. The device has an axial rod protruding from the lower end electrode and making contact with the clamping conductor washer, and also contains a screw for creating a preliminary tension in the package of varistor disks. An elastic electrical insulating plate is installed between the pressure plate and the end electrode.

The disadvantage of this device is that the connection of the end electrodes to each other is carried out using tightening elements in the form of clamps made of continuously wound strands of insulating material. Such a connection only accepts tensile loads, and under the action of compressive loads or a bending moment, the forces from the upper end electrode to the lower end electrode are transmitted through a package of varistor disks, which can cause their destruction. Such a connection has a low explosion safety.

The well-known "Surge Protector" according to the patent of the Russian Federation No. 2256972, 4MPK Н01С 7/12, adopted as the closest analogue, consisting of at least one module containing a housing insulating pipe made of composite material, lined with a tracking protective ribbed tire, fixed at its ends metal electrodes with a central threaded hole in the bottom and a column of varistor disks joined with preload placed in its cavity, shunted with electrodes through a conductive compensation washer, while the shaped metal electrodes have hubs facing the inside of the cup and forming deep annular grooves with its wall, in which the perforated ends of the housing insulating pipe are recessed, there are radial holes in the wall and hub of each electrode, coaxial with each other and with perforation holes on the recessed ends of the housing pipe, in which the radial pins fastening the electrodes to the body tube are placed and fixed; between the conductive compensation washer and the end face of the hub of at least the upper electrode there is an elastic compensation disk of conductive elastic material, the coefficient of thermal expansion of which is higher than that of the composite material of the casing pipe; in the threaded hole of the hub of the upper electrode, a mounting and clamping pin is installed, designed to create and regulate the normalized compression force of the varistor disks through a conductive compensation washer; in the electrode hub, at least one radial hole is made through and threaded, a locking screw is installed in this hole, fixing the position of the mounting-clamping pin and the normalized clamping force of the varistor disks; varistor disks, compensation washers and an elastic compensation disk are centered in a cylindrical axisymmetric column and are rigidly fixed by the radial interference of a mesh sleeve of spiral cross continuous filaments, covering with their loop edge formations the radial pins fastening the electrodes to the housing pipe, and the gap between its inner surface and axisymmetric the varistor column is filled with a thermally conductive insulating compound.

A disadvantage of the known surge protector according to the patent of the Russian Federation No. 2256972, 4MPK Н01С 7/12 is the low explosion safety due to the connection of the housing insulating pipe and the metal electrode by the radial pins, because the through hole for the radial pin is a voltage concentrator. The presence of a stress concentrator can lead to the destruction of the pin joint when an axial tensile force or bending moment is applied to the surge suppressor, and a detachment and ejection of a metal electrode may occur during emergency destruction of the apparatus.

The claimed invention has the task of increasing the explosion safety of the surge suppressor by connecting the terminal and the housing insulating pipe using a flexible key.

The problem in the claimed invention is solved due to the fact that the surge suppressor contains a housing insulating pipe made of composite material, lined with tracking protection ribs mounted on its outer cylindrical surface, reinforced with metal end fittings, a column consisting of spring-tightened columns between them in the cavity of the housing insulating pipe coaxially joined varistor disks, and connected by a shunt to the upper terminal, the cavity between the inner cylinder The surface of the casing insulating pipe and the column is filled with a heat-conducting electrical insulating compound, while the connection of the terminal and the casing insulation pipe is carried out using a flexible key installed through the entry hole in the keyway formed by a groove on the casing insulation pipe and a groove on the terminal, and the axis of the flexible key lies in a plane perpendicular to the axis of the housing insulation pipe, and a tangent plane to the axis of the flexible key parallel to the axis of the housing insulation pipe .

A flexible key can be installed through an inlet in a keyway formed by a groove on the outer cylindrical surface of the housing insulating pipe and a groove on the inner surface of the housing insulating pipe that mates with this outer cylindrical surface of the housing insulating pipe covering the housing insulating pipe.

A flexible key can be installed through an inlet in a keyway formed by a groove on the inner cylindrical surface of the housing insulating pipe and a groove on the outer surface of the terminator inserted into the housing insulating pipe that mates with this inner cylindrical surface of the housing insulating pipe.

A flexible key in cross section can be made rectangular.

The connection of the terminators and the casing insulating pipe can be carried out using several flexible keys installed through the inlet holes in the keyways formed by grooves on the cylindrical surface of the casing insulating pipe and grooves on the surface of the terminator mating with the cylindrical surface of the casing insulating pipe.

The surge protector contains a housing insulating pipe made of a composite material, for example fiberglass, which perceives all mechanical stresses. The outer cylindrical surface of the casing insulating pipe is lined with tracking protection ribs made of silicone (silaxane) rubber. Metal terminators are installed at the ends of the casing insulating pipes, which serve as contact leads of the surge suppressor and ensure the tightness of the apparatus body. The connection of the terminal and the casing insulating pipe is carried out by a flexible key made, for example, of a wire inserted through the lead-in into the keyway formed by a groove on the cylindrical surface of the casing insulating pipe and a groove on the surface of the ending connected to this cylindrical surface of the casing insulating pipe. Such a connection provides high load-bearing capacity of the surge suppressor both under the action of axial tensile and compressive loads, and under the action of a bending moment. The connection of the terminal and the casing insulating pipe can be performed using several keys, the axes of which lie on the intersection of the plane perpendicular to the axis of the casing insulating pipe and the plane parallel to this axis, this connection is more technologically advanced. Between the terminators in the cavity of the casing insulating pipe, a column consisting of coaxially aligned varistor disks is installed on the lower end. At the ends of the column, copper washers can be arranged coaxially with it, which serve to distribute the current over the entire cross section of the varistor disk. To ensure the necessary contact pressure, the varistor disk column is pressed by a spring located between the upper terminal and the copper washer. The electrical connection between the upper terminal and the varistor disk column is carried out using a shunt - a flexible copper conductor. The inner cavity between the inner cylindrical surface of the housing insulating pipe and the varistor disk column is filled with a heat-conducting electrical insulating compound, which serves to improve heat dissipation and increase the throughput of the surge suppressor. The compound is pumped into the inside of the housing insulating pipe through an opening in the lower terminal, into which the stud is then installed. The hairpin is also installed in the upper terminal, they are used to attach contact wires to the surge protector.

Thus, the connection of the terminal and the casing insulating pipe with the help of a flexible key can significantly increase the bearing capacity of the surge arrestor and its explosion safety, completely eliminating the breakdown of the terminal from the casing insulating pipe in the event of an emergency operation of the device.

The claimed invention differs from the well-known technical solution according to the patent of the Russian Federation No. 2256972 in that the connection of the terminal and the housing insulating pipe is carried out using at least one flexible key installed through the entry hole in the keyway formed by a groove on the housing insulating pipe and a groove on the terminal, and the axis of the flexible key lies in a plane perpendicular to the axis of the housing insulating pipe, and the tangent plane to the axis of the flexible key is parallel to the axis of the housing insulating pipe.

The indicated difference made it possible to obtain a technical result, namely, it increased the explosion safety of the surge suppressor due to the connection of the terminator and the casing insulating pipe using a flexible key.

Figure 1 presents the surge suppressor, an example is shown when the terminator covers the housing insulating pipe.

Figure 2 shows a section of the surge suppressor aa of figure 1.

Figure 3 presents a section of the surge suppressor BB-1 of figure 1.

Figure 4 presents the surge suppressor, an example is shown when the terminator is inserted into the housing insulating pipe.

Figure 5 shows a section of the surge suppressor BB-4.

Figure 6 presents a section of the surge suppressor according to G-D of Figure 5.

7 shows a surge suppressor, an example is shown when the longitudinal section of the flexible key is rectangular.

On Fig presents a section of the surge arrestor on DD DD 7.

Figure 9 presents the surge suppressor, an example is shown when the connection of the terminal and the housing insulating pipe is made using several keys.

Figure 10 shows a section of the surge suppressor on EE of Fig.9.

In Fig.11 shows a section of a surge arrestor according to FJ of Fig.9.

The surge protector contains a housing insulating pipe 1 (Figs. 2, 3, 5, 6, 8, 10, 11) of composite material, lined with tracking protection ribs 2 (Figs. 1-11) mounted on its outer cylindrical surface 3 (Fig. 2, 5, 8, 10), reinforced with metal terminators 4 (Figs. 1-11), placed between them in the cavity 5 (Figs. 2, 5, 8, 10) of the casing insulating pipe 1, at least one column 6 (figure 2, 5, 8, 10), consisting of spring-loaded 7 (figure 2, 3, 5, 8, 10), coaxially joined varistor disks 8 (figure 2, 5, 8, 10), and connected shunt 9 (Fig.2, 5, 8, 10 ) with an upper end 4, a cavity 5 between the inner cylindrical surface 10 (Fig. 2, 5, 8, 10) of the casing insulating pipe 1 and the column 6 is filled with heat-conducting electrical insulating compound 11 (Fig. 2, 5, 8, 10), while the connection of the terminal 4 and the housing insulating pipe 1 is carried out using at least one flexible key 12 (Fig.2, 3, 5, 6, 8, 10, 11) installed through the inlet 13 (Fig.1, 3, 6, 7, 9, 11) into the keyway 14 (FIGS. 2, 3, 5, 6, 8, 10, 11) formed by the groove 15 (FIGS. 2, 5, 8, 10) on the housing insulating pipe 1 and groove 16 (figure 2, 5, 8, 10) and the terminal 4, and the axis 17 (Fig. 3, 6, 11) of the flexible key 12 lies in a plane perpendicular to the axis 18 (Fig. 2, 5, 8, 10) of the housing insulating pipe 1, and the tangent plane to the axis 17 is flexible the dowels 12 are parallel to the axis 18 of the housing insulating pipe 1.

A flexible key 12 is installed through the inlet 13 into a keyway 14 formed by a groove 15 on the outer cylindrical surface 3 of the housing insulating pipe 1 and a groove 16 on the inner surface of the housing 19 insulating pipe 3 mating with this outer cylindrical surface 3 (Fig. 2, 8, 10) end 4, covering the housing insulating pipe 1.

A flexible key 12 is installed through the inlet 13 into a keyway 14 formed by a groove 15 on the inner cylindrical surface 10 of the housing insulating pipe 1 and a groove 16 on the outer mating pipe 10 of the housing insulating pipe 1 of the surface 20 (Fig. 5) of the terminal 4 inserted into the housing insulating pipe 1.

The flexible key 12 in the cross section is rectangular.

The connection of the terminal 4 and the casing insulating pipe 1 is carried out using four flexible keys 12 installed through the inlet holes 13 into the keyways 14 formed by the grooves 15 on the outer cylindrical surface 3 of the casing insulating pipe 1 and the grooves 16 on the casing mating with this outer cylindrical surface 3 insulating pipe 1 of the surface 19 of the terminal 4.

At the ends of column 6, copper washers 21 can be arranged coaxially with it (FIGS. 2, 5, 8, 10), which serve to distribute current over the entire cross section of the varistor disk 8. Studs 22 are installed in the terminators 4 (FIGS. 1, 2, 4 , 5, 7, 8, 9, 10), which serve to attach contact wires to the surge arrester.

The surge suppressor works as follows. Under extreme operating conditions during powerful lightning or switching overloads, when an sufficient voltage is applied to the surge suppressor, an electric current flows through it. Electric current flows from the upper terminal 4 through the shunt 9, the copper washer 21 and the column 6, consisting of varistor disks 8, to the lower terminal 4. When the electric current flows through the column 6, a large amount of heat is released, which is removed through the heat-conducting electrical insulating compound 11 and the wall case insulating pipe 1 made of a composite material, such as fiberglass, and then dissipated into the environment. In case of emergency operation of the surge suppressor, that is, during its breakdown, the vaporization of compound 11 occurs, which leads to an increase in pressure in the cavity 5 of the casing insulating pipe 1. The weakest fibers of the casing insulating pipe 1 are destroyed, which leads to the opening of the casing insulating pipe 1 of the surge protector, and through the holes formed, gas is released into the environment. This leads to a drop in pressure in the cavity 5 of the casing insulating pipe 1. The most dangerous during emergency operation of the surge suppressor is the breakdown of the terminal 4 from the casing insulating pipe 1. The connection of the terminal 4 and the casing insulating pipe 1 with a flexible key 12 can significantly increase the explosion safety of the surge protector, completely eliminating breakdown of the terminal 4 from the housing insulating pipe 1.

The invention made it possible to obtain a technical result, namely, it increased the explosion safety of the surge suppressor due to the connection of the terminal and the casing insulating pipe using a flexible key.

Claims (5)

1. Surge arrestor comprising a housing insulating pipe made of composite material, lined with tracking protection ribs mounted on its outer cylindrical surface, reinforced with metal terminators, placed between them in the cavity of the housing insulation pipe, at least one column consisting of spring-loaded, coaxially joined varistor disks, and connected by shunt to the upper terminal, the cavity between the inner cylindrical surface of the housing insulating pipe s and a column is filled with a heat-conducting electrical insulating compound, characterized in that the connection of the terminal and the housing insulating pipe is carried out using at least one flexible key installed through the inlet into the keyway formed by a groove on the housing insulating pipe and a groove on the end, and the axis of the flexible key lies in a plane perpendicular to the axis of the housing insulating pipe, and the tangent plane to the axis of the flexible key is parallel to the axis of the housing insulating pipe. 2. The surge suppressor according to claim 1, characterized in that the flexible key is installed through the inlet into the keyway formed by a groove on the outer cylindrical surface of the housing insulating pipe and a groove on the inner surface of the housing insulating pipe mating with the outer cylindrical surface of the housing pipe covering the housing insulating pipe. 3. The surge suppressor according to claim 1, characterized in that the flexible key is installed through the inlet into the keyway formed by a groove on the inner cylindrical surface of the housing insulating pipe and a groove on the outer surface of the terminator inserted into the inner cylindrical surface of the housing insulating pipe inserted into case insulating pipe. 4. The surge arrestor according to claim 1, characterized in that the flexible key in the cross section is rectangular. 5. The surge arrestor according to claim 1, characterized in that the connection of the terminal and the housing insulation pipe is carried out using four flexible keys installed through the inlets into the keyways formed by grooves on the outer cylindrical surface of the housing insulation pipe and grooves on the mating with this outer the cylindrical surface of the housing insulating pipe of the surface of the terminal.

Images