RU184108U1 - INSULATOR WITH MULTI-CAMERA DISCHARGE AND FIXED AIR GAP - Google Patents

Abstract

A multicameral arrester is disclosed, attached to one end of the insulator to form a fixed air gap with an electrode fixed to the other end of the insulator. A multi-chamber arrestor can be attached to the insulator using a holder made using metal. The discharge arc that appears in the device due to overvoltage (including lightning) is extinguished, without the need to turn off the voltage on the power line, while minimizing the transverse dimensions of the device. In addition, it provides a reduction in leakage currents on the surface of the multi-chamber spark gap due to the presence of a fixed air gap.

Description

The technical field to which the utility model relates.

The utility model relates to electrical engineering, in particular, to devices for protecting electrical equipment, including power lines, from overvoltage, for example, lightning.

State of the art

From the patent CN 200710042031.3 a lightning protection insulator is known, which has a clamping device consisting of two clamping elements. The lower clamping element is provided with a conductive rod, in which the lower end forms a fixed air gap with the protrusion of the lower end of the insulator.

The disadvantage of this insulator is that in order to extinguish the discharge arc caused by lightning overvoltage in a fixed air spark gap, it is necessary to disconnect the voltage on the transmission line, since such a discharge arc has a large current strength and is in a self-sustaining mode without disconnecting the voltage.

In addition, the insulator of the prior art has large transverse dimensions in the plane in which the conductive rod having an arcuate shape is located.

Utility Model Disclosure

The objective of the utility model is to suppress the discharge arc that appears in the device due to overvoltage (including lightning), without the need to turn off the voltage on the power line, while minimizing the transverse dimensions of the device.

The problem is solved with the help of an insulator equipped with a multi-chamber arrestor attached to one end of the insulator with the formation of a fixed air gap with an electrode fixed to the other end of the insulator. A multi-chamber arrestor can be attached to the insulator using a holder made using metal. This holder can be made in the form of a plate. In a particular embodiment, the holder can be made with the possibility of fastening to the protected object, for example, to the support of the power line.

The insulator can be equipped with a mounting unit that is capable of attaching to the protected object the end of the insulator with which a fixed air gap is formed or that end of the insulator to which the multi-chamber arrestor is attached. Here, under the protected object here and in other places, unless otherwise stated, is meant a power line, electrical equipment or other objects.

A multi-chamber arrester may have a curved shape, for example, the shape of a part of a circle or ellipse. In another embodiment, the multi-chamber arrester may have a direct shape.

The insulator may preferably consist of a rod and an insulating body made using a polymer. The polymer in particular embodiments may be silicone rubber, and the core may be made using fiberglass. In addition, the insulator may consist of a rod and an insulating body made using porcelain, and the rod can be made using fiberglass.

The insulator may be equipped with a clamping device for the power line wire. The clamping device can be placed on the end of the insulator with which a fixed air gap is formed, or on the end of the insulator to which the multi-chamber arrestor is attached. The clamping device may be cast or stamped. In a preferred embodiment, the clamping device consists of two clamping elements.

The multi-chamber arrester preferably consists of an elongated insulating element, inside of which discharge electrodes are placed, which exit into the discharge chambers having exits to the outer surface of the insulating element. The discharge electrodes are predominantly installed in the insulating element with the formation of discharge gaps in the discharge chambers, the dimensions of which are less than the thickness of the dielectric layer from which the insulation element is made, which separates the discharge gaps from the outer surface of the insulating element. In a preferred embodiment, the outputs of the discharge chambers are directed away from the insulator. For example, the outputs of the discharge chambers can be directed perpendicular to the plane passing through the insulator and multi-chamber spark gap.

The elongated insulating body of the multi-chamber spark gap can be equipped with a rigid rod located along the discharge electrodes at a distance from them. In addition, the multi-chamber spark gap at the end that is involved in the formation of a fixed air gap may have a terminal electrode directly or through the discharge gap connected to one or more discharge electrodes of the spark gap.

In some embodiments, the clamping device may have a sleeve configured to laterally insert relative to the insulator an elongated insulating element of a multi-chamber spark gap or a connecting electrode connecting the insulator to the spark gap, and mechanically securing the insulating element or connecting electrode therein. In particular embodiments, an aperture may be provided at the end of the insulator, configured to insert into it an elongated insulating element of a multi-chamber spark gap or a connecting electrode connecting the insulator to the spark gap.

The technical result of the utility model is to suppress the discharge arc that appears in the device due to overvoltage (including lightning), without the need to turn off the voltage on the power line, while minimizing the transverse dimensions of the device. In addition, it provides a reduction in leakage currents on the surface of the multi-chamber spark gap due to the presence of a fixed air gap (gap). The fixed width of the air gap (gap) ensures the stability of the conditions for the onset of discharge due to overvoltage, so that the discharge will occur at overvoltages above a predetermined value.

Brief Description of the Drawings

In FIG. 1 shows a device in accordance with a utility model.

In FIG. 2 shows one way of installing a device in accordance with a utility model on a power line.

Utility Model Implementation

Next, a utility model will be described with reference to explanatory drawings. The drawings show possible embodiments of the insulator in accordance with the utility model, which are not limiting the scope of protection. The embodiments disclosed in the description of the utility model are also not limiting and are intended to explain the essence of the utility model. The scope of protection is limited only by the utility model formula.

As shown in FIG. 1 and 2, the device in accordance with the present utility model includes a holder 1 connected to the terminator 3 of the insulator 2 and the mounting electrode 6 of the multi-chamber spark gap 5. The spark gap 5 having in FIG. 1 and 2, a straight shape, is installed, in fact, parallel to the insulator 2 so that between the terminal electrode 7 of the arrester 5 and the other terminal 4 of the insulator 2 a fixed air gap (gap) is formed. In FIG. 1 and 2, a discharge electrode 8 is connected to the terminal 4, which ensures the formation of a fixed air gap of the required size and protects the terminal 4 from burnout during the passage of the discharge.

As shown in FIG. 1 and 2, the insulator 2 has terminators 3 and 4, which can be installed, for example, on the insulating rod of the insulator, and this rod can be fiberglass. In such an embodiment of the insulator, an insulating body of the insulator is installed over the rod, which can be made using polymeric material, for example, silicone rubber, porcelain, glass, or another. An insulating body is formed from the polymeric material, for example, in the form of a cylinder, equipped with several ribs surrounding the insulating body, to increase the electric length of the insulator over the surface.

At the same time, some insulators can be made with terminators having a shape different from that shown in FIG. 1 and 2. In addition, in accordance with this utility model, an insulator having a different structure and / or shape, including without metal or conductive terminators, can be used. In such embodiments, a fixed air gap is formed between the multi-electrode spark gap and the electrode, which are attached to the insulator (its ends) directly or through intermediate elements, including, for example, holder 1.

The holder is preferably made using metal to ensure the transmission of electric potential, for example, in the form of a plate. The plate may be bent, as shown in FIG. 1 and 2, or have a direct form. In FIG. 1 and 2, the holder 1 provides fastening to the protected object (to the support of the power line) by attaching to the support of the holder itself, to which the insulator and arrester are attached, using additional fasteners 11 and 12. At the same time, options are possible when the holder is not used for fastening to the support, and the structure is attached to the other end of the insulator or in another way.

For example, an insulator embodiment is possible when the end of the insulator to which the multi-chamber arrester is attached is not attached to the protected object, but the end of the insulator with which a fixed air gap is formed. To implement these options, the insulator can be equipped with a mounting unit, providing the possibility of appropriate mounting.

In FIG. Figures 1 and 2 show that the multi-chamber arrester has a direct shape. In other embodiments, the multi-chamber arrester may have a curved shape, for example, the shape of a part of a circle or ellipse. In the case of a straight shape, the transverse size of the entire structure of the insulator equipped with a multi-chamber spark gap and a fixed air gap decreases in the plane of the insulator-spark gap with an increase in its length, and in the case of a curved shape, the length of such a structure decreases with an increase in the transverse size (in the plane of the insulator gap).

The multi-chamber spark gap 5 mainly consists of an elongated insulating element, inside of which discharge electrodes are placed, which exit into the discharge chambers having exits to the outer surface of the insulating element. On the outer surface of the insulating element near the exits of the discharge chambers, protrusions 9 can be provided that serve as guides for plasma exhausts from the discharge chambers resulting from spark discharges, as well as reducing the likelihood of combining the exhausts of the discharge chambers.

The discharge electrodes are installed in the insulating element with the formation of discharge gaps in the discharge chambers, the dimensions of which are less than the thickness of the dielectric layer from which the insulation element is made, which separates the discharge gaps from the outer surface of the insulating element (i.e., in fact, the depth of the discharge chamber).

The outputs of the discharge chambers can be directed away from the insulator. For example, they can be directed perpendicular to a plane passing through an insulator and a multi-chamber spark gap, as shown in FIG. 1 and 2. This prevents exhaust from the discharge chambers, which are discharge arcs, to the insulator. This prevents the possibility of circuit discharge in addition to the provided path through the discharge gaps and electrodes.

To impart the required rigidity, the elongated insulating body can be provided with a rigid rod located along the discharge electrodes at a distance from them (and preferably inside the insulating body). In the case where the arrester is straight, the rod is also straight, which also simplifies the manufacture of the arrester. The insulator body of the arrester is mainly made using polymeric materials, such as, for example, silicone rubber.

A multi-chamber spark gap 5 at the end that is involved in the formation of a fixed air gap may have a terminal electrode 7 connected to one or more discharge electrodes of the spark gap. Hereinafter, the electrical connection or connection can be either direct (directly, galvanically) or through the discharge gap

At the other end of the multi-chamber arrester, the one that is connected to the insulator, one or more discharge electrodes can be connected to the clamping device directly or through the discharge gap or using a connecting electrode, which, in turn, can be connected to the clamping device and / or one or more discharge electrodes directly or through discharge gaps.

The connection of a multi-chamber arrestor with an insulator is possible in several ways. In one embodiment, the lower clamping element of the clamping device or the terminator of the insulator may have a protrusion included in the multi-chamber spark gap and having a mechanical connection with an elongated insulating element, as well as connected to one or more discharge electrodes directly or through discharge gaps. Such a protrusion may be called a connecting electrode mechanically and electrically connected to the lower clamping element of the insulator clamping device.

In another embodiment, the clamping device may have a sleeve connected to the terminal, into which laterally relative to the insulator can be inserted and mechanically fixed, for example, by crimping, an elongated insulating element of a multi-chamber spark gap or a connecting electrode. The sleeve can be electrically connected to the clamping device directly or through the discharge gap, and can also be part of the device. As for the multi-electrode spark gap, with it the sleeve can be connected directly or through the discharge gaps with one or more discharge electrodes or with the help of a connecting electrode, which can be connected with both the sleeve and one or more intermediate electrodes directly and / or through discharge gaps.

In yet another embodiment, a multielectrode arrester, for example, its elongated insulating element or connecting electrode, which is part of the arrester in this case, can be inserted into the hole in the upper end of the insulator. In a particular embodiment, when a multi-electrode arrestor is attached to the insulator by fixing the insulator element of the arrester in the insulator, the clamping device can be connected to one or more discharge electrodes of the arrester through the discharge gap or by means of a connecting electrode, which, in turn, can be connected as a clamp device, and one or more intermediate electrodes directly and / or through the discharge gaps.

In another particular embodiment, when the multi-electrode spark gap is attached to the insulator by means of a connecting electrode passing through an opening in the insulator, the connecting electrode can be connected directly to the clamping device or through the discharge gap. In one possible implementation, the connecting electrode can simultaneously pass through a hole in the insulator and a clamping device or a metal element, such as a terminal or tube or plate, electrically connected to the clamping device (directly or through the discharge gap) and worn on the insulator.

A multi-chamber arrestor can also be inserted into the sleeve, but not secured by crimping the sleeve, but in a different way. Both the insulating element and the connecting electrode of the arrester, passed through the hole in the insulator, can be fixed with a threaded fastener (nut, wing or the like) or other types of fasteners known from the prior art.

A multi-chamber arrester can be attached to the insulator both to the end to which the power line wire is attached, and to the end by which the insulator is attached to the power line support. Accordingly, all the described mounting options can be implemented in both cases with the corresponding replacement of one terminal or clamping device with another terminal.

In FIG. 2 shows one of the possible options for implementing the utility model. In accordance with this embodiment, the insulator 2 with a multi-chamber spark gap 5 and a fixed air gap between the electrodes 7 and 8 is attached to the crossarm 20 of the power line support, on which the support insulator 21 is mounted, to which the power line wire 22 is attached. The insulator 2 is attached to the yoke 20 using the holder 1, which is attached to the yoke 20 using the fasteners 11 and 12.

To ensure the electrical connection of the electrode 8 involved in the formation of a fixed air gap and attached to the terminator 4 of the insulator 2 with the wire 22, a conductor in the form of a cable 23 is used, which is attached to the wire 22 of the power line by means of a fastener 24. In case the power line wire 22 is insulated, the fastener 24 may be provided with an element that bites through the insulation and is in contact with the metal part of the wire.

The insulator with a multi-chamber spark gap and a fixed air gap operates as follows. In the normal mode of operation, when there is no overvoltage, the voltage from the clamping device having the potential of the power line wire is applied to one of the discharge gaps that are provided between the clamping device and the electrode fixed at one end of the insulator. In particular, voltage can be applied to one of the discharge gaps between the discharge electrodes of the multi-chamber spark gap, if the clamping device has direct electrical contact with one of these discharge electrodes. Alternatively, voltage may be applied to the discharge gap between the jig and the discharge electrode (or connecting electrode) if such a discharge gap is provided.

In the absence of overvoltage, the discharge gaps cannot be punctured by the nominal voltage of the power line and, as a result, no electric current flows through the multi-chamber arrestor and the fixed air gap (except, possibly, the leakage current, to reduce which the fixed air gap is intended).

When an overvoltage appears on the clamping device, for example, as a result of a lightning strike to or near a power line, the discharge gaps are successively punched due to the insufficient electric strength of the discharge gaps so as not to break through during overvoltage. When the extreme discharge electrode of a multicamera arrester or its terminal electrode, if provided, acquires an overvoltage potential, a breakdown of a fixed air gap occurs along a multicameral arrester and an electric current passes to a transmission line support through a fixed air gap, thereby reducing overvoltage on the transmission line wire.

At the end of the overvoltage pulse and when the voltage of the power line with an industrial frequency (50 or 60 Hz) passes through zero, the discharge arcs between the discharge electrodes of the multi-chamber spark gap are extinguished, since the multi-chamber spark gap contains many discharge gaps, which limits the possible discharge current. This ensures automatic extinction of the discharge arc after the end of the overvoltage pulse without disconnecting the voltage on the power line.

A fixed air gap, made in series with a multi-chamber arrestor, reduces leakage currents through a multi-chamber arrestor.

In FIG. 1 and 2 it is seen that the multi-chamber spark gap 5 is equipped with a protective electrode 10 mounted on the mounting electrode 6 of the multi-chamber spark gap 5. It may be necessary for the following reasons. In some cases, for example, with a large pulsed current caused, in particular, by a direct lightning strike into the wire and / or when the arrester is installed in such positions that the electrical distance from the protected or grounded object to the fastening electrode used to fix the arrester differs slightly or even less than the distance to the terminal electrode at the free end of the arrester, the discharge can pass between the protected or grounded object with which there is no connection of the arrester and the fixing electrode ohm, which is used to fix the arrester, bypassing the intermediate electrodes with the formation of a single discharge arc.

Such a single discharge between the fastening electrode used to fasten the arrester and the protected or grounded object can begin after the formation of discharges between the intermediate electrodes with their subsequent merging and transition into one arc. In addition, such a direct discharge can begin immediately between the mounting electrode used to mount the arrester and the protected or grounded object due to the breakdown of this discharge gap by overvoltage.

In addition to the fact that such a direct discharge is more difficult to extinguish and, as a result, it interferes with the normal operation of electrical equipment and, in some cases, destroys it, this discharge between the mounting electrode used to mount the arrester and the protected or grounded object also destroys the multi-chamber system arrester, consisting of intermediate electrodes that exit into the open discharge chambers, as it passes along the outputs of the discharge chambers (at least located near the said mounting electrode) and you they burn dielectric material at the exits and inside the chambers, distorting their geometric shape so that in the future many consecutive discharges cannot form. In some cases, this may even lead to oxidation and / or precipitation of the intermediate electrodes. In addition, the mounting electrode also burns out, as a result of which the electrical properties of the arrester change, and the mechanical strength decreases and other mechanical characteristics of the arrester deteriorate.

To prevent the destructive effect of a single arc between the mounting electrode used to mount the arrester and a grounded object, the arrester in accordance with this utility model is equipped with a protective electrode. In the case when lightning gets into or near a protected object (for example, a device or an element of electrical equipment, which can be, inter alia, a power line and, in particular, a wire) and an increased overvoltage is generated between the protected and grounded objects, which can punch the distance between them, bypassing the spark gap with a multi-chamber system, this discharge is carried out with the participation of a protective electrode away from the multi-chamber system, thereby preventing its damage by such a discharge increased powerfully STI

The protective electrode is connected to one of the end electrodes of the multi-chamber arrester, for example, the one used to mount the arrester. As shown in FIG. 1 and 2 of the embodiment, the protective electrode 10 is made integrally with the holder 1. In other embodiments, the protective electrode can be made integrally with the mounting or terminal electrode or as a separate part made with the possibility of connection with the fixing or terminal electrode. The protective electrode in the form of a separate part may have a part made with the possibility of attaching to electrical equipment, for example, to the electrically conductive part of the insulator (for example, the terminator of the suspension insulator or the pin of the pin insulator) or to the support of the transmission line. This embodiment of the protective electrode allows to reduce the load on the mounting part of the mounting electrode of the arrester, since the protective electrode is directly attached to the electrical equipment, and the arrester is attached to the protective electrode.

In order for a single discharge arc to exit onto the protective electrode, bypassing the multi-chamber discharge system, the protective electrode (in particular, its end) should be away from the oblong insulating element of the arrester. Thus, the protective electrode must be made protruding away from the insulating element. In particular, the protective electrode and its end should protrude in a direction perpendicular to the longitudinal direction of the insulating element. Even when the protective electrode moves away from the insulating element at an angle less than 90 °, it still protrudes in a direction perpendicular to the longitudinal direction of the insulating element, because the protective electrode has a nonzero component in this direction.

In a preferred embodiment, the protruding portion of the protective electrode 10, as shown in FIG. 1 and 2, is also located along the insulating element of the arrester 5. This is done so that the discharge arc passing through the multi-chamber system terminates on the protective electrode that is part of the fastening electrode or connected to it, and not on the fastening electrode, holder or intermediate electrode connected to the mounting electrode or separated from it by one or more discharge gaps.

In a preferred embodiment, the end of the protective electrode in the longitudinal direction of the insulating body (coinciding with the longitudinal direction of the arrester) should be closer to the terminal electrode at the free end of the arrester than the mounting electrode used to attach the arrester and connected to the protective electrode. In this case, the likelihood that a powerful direct discharge bypassing the multicamera system will be directed to the protective electrode, rather than the mounting electrode, will be significantly higher.

In addition, in a preferred embodiment, the protective electrode in the longitudinal direction of the insulating element extends to the first exit from the discharge chamber, counting from the fastening electrode used to fasten the arrester and connected to the protective electrode to the terminal electrode mounted on the free end of the arrester. This is desirable for two reasons.

Firstly, with this configuration, the likelihood that a powerful direct discharge bypassing the multicamera system will be directed to the protective electrode, and not an intermediate electrode connected to the mounting electrode or separated from it by one or more discharge gaps, will be significantly higher. Secondly, this configuration provides a free exit of the discharge arc from the first exit from the discharge chamber, passing by the protective electrode. This prevents such a discharge arc from entering the protective electrode, as a result of which the number of working discharge chambers would be reduced by one.

The protective electrode can be made voluminous, with thickness varying along one or several directions. However, in a preferred embodiment, the protective electrode is made flat of metal, for example, steel, sheet. This design of the electrode simplifies its manufacture.

In some cases, a discharge can pass between the end electrodes (fixing and terminal) of the arrester, bypassing the intermediate electrodes. In this case, the end electrodes will burn out, and the discharge chambers of the multicamera system will also be destroyed. To prevent such damage, both end electrodes of the arrester can be provided with protective electrodes in any of the above configurations. In this case, when one or more protective electrodes are installed on each end electrode, both the end electrodes and the multi-chamber system are protected from the destructive effects of an electric discharge arc of increased power.

In some embodiments, the protective electrode may also be provided with that end electrode, which is mounted on the free end of the insulating body, which is not used to attach the arrester, and is called the end electrode (electrode 7 in Figs. 1 and 2). Each of the end electrodes of the arrester can be independently provided with one or more protective electrodes, depending on the configuration of the arrester and the electrical equipment for which it is intended to protect.

The described examples of the utility model implementation are presented for the purpose of its detailed explanation and are not limiting the scope of protection, which is determined by the utility model formula. The described embodiments of the utility model can be combined in various combinations, providing the simultaneous receipt of additional technical results indicated in relation to these options.

Claims (24)

1. An insulator equipped with a multi-chamber arrestor attached to one end of the insulator to form a fixed air gap with an electrode fixed to the other end of the insulator. 2. The insulator according to claim 1, characterized in that the multi-chamber arrestor is attached to the insulator using a holder made using metal. 3. The insulator according to claim 2, characterized in that the holder is made in the form of a plate. 4. The insulator according to claim 2, characterized in that the holder is made with the possibility of attachment to the protected object. 5. The insulator according to claim 1, characterized in that it is equipped with a mounting unit configured to attach to the protected object the end of the insulator with which a fixed air gap is formed. 6. The insulator according to claim 1, characterized in that it is equipped with a mounting unit made with the possibility of attaching to the protected object the end of the insulator to which the multi-chamber arrestor is attached. 7. The insulator according to claim 1, characterized in that the multi-chamber arrestor has a curved shape. 8. The insulator according to claim 7, characterized in that the elongated insulating element has the form of a part of a circle or ellipse. 9. The insulator according to claim 1, characterized in that the multi-chamber arrestor has a direct shape. 10. The insulator according to claim 9, characterized in that it consists of a rod and an insulating body made using polymer. 11. The insulator according to p. 10, characterized in that the polymer is a silicone rubber, and the rod is made using fiberglass. 12. The insulator according to claim 1, characterized in that it consists of a rod and an insulating body made using porcelain. 13. The insulator according to p. 12, characterized in that the rod is made using fiberglass. 14. The insulator according to claim 1, characterized in that it is equipped with a clamping device for the wire of the power line or for a conductor made with the possibility of connection with the wire of the power line. 15. The insulator according to claim 14, characterized in that the clamping device is placed on the end of the insulator with which a fixed air gap is formed. 16. The insulator according to p. 14, characterized in that the clamping device is placed on the end of the insulator to which the multicameral arrester is attached. 17. The insulator according to claim 1, characterized in that the multi-chamber arrester consists of an elongated insulating element, inside of which there are discharge electrodes that exit into the discharge chambers having exits to the outer surface of the insulating element. 18. The insulator according to claim 17, characterized in that the discharge electrodes are installed in the insulating element with the formation of discharge gaps in the discharge chambers, the dimensions of which are less than the thickness of the dielectric layer from which the insulation element is made, separating the discharge gaps from the outer surface of the insulating element. 19. The insulator according to claim 17, characterized in that the outputs of the discharge chambers are directed away from the insulator. 20. The insulator according to claim 17, characterized in that the outputs of the discharge chambers are directed perpendicular to the plane passing through the insulator and the multi-chamber spark gap. 21. The insulator according to claim 17, characterized in that the elongated insulating body is equipped with a rigid rod located along the discharge electrodes at a distance from them. 22. The insulator according to claim 17, characterized in that the multi-chamber spark gap at the end that participates in the formation of the fixed air gap has a terminal electrode directly or through the discharge gap connected to one or more discharge electrodes of the spark gap. 23. The insulator according to claim 16, characterized in that the clamping device has a sleeve configured to laterally insert an elongated insulating element of a multi-chamber spark gap or connecting electrode connecting the insulator to the spark gap and mechanically securing the insulating element or connecting electrode therein. 24. The insulator according to claim 1, characterized in that a hole is provided at the end of the insulator, configured to insert into it an elongated insulating element of a multi-chamber spark gap or a connecting electrode connecting the insulator to the spark gap.

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