RU187995U1 - INSULATOR WITH INDICATOR INSULATOR BREAKTHROUGH - Google Patents

Abstract

The utility model relates to electrical engineering and can be used to indicate overlap or breakdown of the insulator. SUBSTANCE: insulator is equipped with a breakdown indicator. The indicator of breakdown of the insulator is made in the form of a screen for protection against corona discharge and equalization of the electric field strength and has a signal element and at least one element destroyed by electric current. The signal element is configured to equalize the electric field strength. Moreover, the signal element or part thereof is fixed to the insulator through the destructible element with the possibility of changing the position of the signal element as a result of the destruction of the destructible element. Destructible element is made with the possibility of passing through it a current flowing through a punched insulator. When the indicator is triggered as a result of breakdown or overlap of the insulator, the signal part falls down or changes its spatial position. By changing the position of the signal element, clearly visible from long distances, it is possible to determine the fact of breakdown or overlap of the insulator. 1 tab., 22 wp f-ly.

Description

The technical field to which the utility model relates.

This utility model relates to electrical engineering, in particular to devices used on overhead power lines (VL) or other electrical equipment to indicate overlap or breakdown of insulators.

State of the art

One of the problems encountered during the operation of power lines is the detection of a punctured or blocked insulator. During electrical breakdown of the insulator, it fails due to the destruction of the internal insulation by an electric discharge and cannot continue to fulfill its function, after which the automation disconnects the power line from the voltage supply until the punctured insulator is replaced with a new one. Overlap of insulators through the air can occur due to various reasons, such as lightning discharge, pollution of insulation, interaction with birds, etc. When shutting down, the insulator most often remains operational, however, an electric discharge can damage the insulator, as a result of which the insulator can break through in the future.

An optical indicator is known from patent RU 2609823, which displays the insulation state of a string of insulators on a power line. The principle of operation of the indicator is that it is connected in parallel with the insulator or a string of insulators. In the case when the insulation of the insulators has the required high value, the voltage in the power line is applied to the optical insulator and it emits visible light.

However, when the insulation of the insulators is broken and has a low value, a significantly lower voltage is applied to the indicator and it emits much less visible light or does not emit it at all. Thus, by the absence of visible radiation from the optical indicator or by its weak luminosity, it is possible to determine the damage to the insulator or the breakdown of the insulator.

Such an optical indicator has several disadvantages. Firstly, to ensure operability, it is necessary to connect such an indicator parallel to the insulator. Since the indicator consists of conductive and semiconducting materials forming a conductive branch of the circuit, it can itself become a place of development of the overlap of the insulator.

Secondly, the voltage drop in the insulator sections may not be due to an insulator defect, but to current leaks on the surface of the insulator as a result of contamination or wetting, which is the normal operating mode for the insulator.

Thirdly, the radiation intensity of the optical indicator, subjectively determined by the observer, will be perceived different depending on the intensity of the illumination of the surrounding space - the sky or clouds. For example, in bright sunny weather, you can not see the glow of even a very luminous indicator, and at night even a weakly luminous indicator will be clearly visible, therefore, determining the malfunction of an insulator by the intensity of the indicator glow can be subjective and ambiguous.

Fourth, the described optical indicator has a limited life due to the fact that the element emitting visible light has a finite number of hours of operation. This means that in order to have information about the state of isolation of insulators, it is necessary to periodically replace such optical indicators or emitting elements in them.

Utility Model Disclosure

The technical problem of this utility model is the development of an insulator with an indicator of breakdown and overlap of the insulator (which can be, inter alia, an insulator different from the insulator on which the indicator is mounted) of a transmission line or other element of electrical equipment that eliminates the above-mentioned disadvantages.

The technical problem of this utility model is solved using an insulator equipped with an insulator breakdown indicator (the one on which the indicator is installed or different from it). The indicator has a signal element and at least one element that is destroyed by electric current, the signal element or part thereof being fixed to the insulator through the element to be destroyed so that the position of the signal element can be changed as a result of the destruction of the element to be destroyed, and the element to be destructed can pass current through it flowing through a punched insulator. The insulator can be equipped with a fastening element that secures the indicator to the insulator, thereby providing, in a particular embodiment, the breakdown of the insulator. The fastening element in the preferred embodiment can be made with the possibility of installation on

the terminator of the insulator and / or on the insulating body of the insulator, thereby providing, in a particular embodiment, the determination of breakdown of the insulator.

The insulator may have a conductive insert in the insulating body and / or on the insulating body above the lower terminal, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. Such a conductive insert may have an arc-receiving element connected to the conductive insert and directed to the location of the signal element and / or destructible element, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The indicator can be configured to transfer the current of the punched insulator from the lower terminal to the signal and / or destructible element - in this case, the triggered indicator will display the breakdown of the insulator located in series with the insulator on which the indicator is mounted, thereby providing, in a particular embodiment determination of breakdown of the insulator.

In one of the embodiments, the indicator can be made in the form of a screen to protect against corona discharge and equalize the electric field, the signal element is configured to equalize the electric field, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. In this case, the destructible element may be a spoke or a part of the screen spoke, the spoke being extended both in the direction passing through the mismatched parts of the signal element and in the direction perpendicular to several mismatched directions passing through the mismatching parts of the signal element, thereby ensuring in a particular embodiment, the determination of breakdown of the insulator. This can also be said in other words: the spokes have destructible elements made with the possibility of destruction under the action of a short circuit current arising from the breakdown of the insulator or when it is blocked through the air, and with the possibility of disconnecting the signal element from the fixing point, as a result of which the signal element changes its position in space, clearly visible from afar with the naked eye, thereby providing, in a particular embodiment, the determination of breakdown of the insulator.

In a particular embodiment, the signal element may have a flat structure, the spoke being extended both in a direction parallel to the plane in which the signal element is located and in a direction perpendicular to this plane, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. For example, if the signal element is made in

in the form of a ring, toroid, ellipsoid, arc or other shape that can be located in a plane, thereby providing, in a particular embodiment, the determination of breakdown of an insulator. That is, the flat structure of the signal element means that most of its different parts are located in the same plane, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. At the same time, the signal element itself is mainly made in the form of a volumetric body (for example, in the form of a rod bent into a toroid, ellipsoid or arc), which ensures equalization of the electric field strength, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. In other words, most of the different parts of the signal element, made in the form of volumetric bodies (mainly straight or curved cylinders), are located in the same plane, thereby providing, in a particular embodiment, the determination of breakdown of the insulator.

The spokes can be located both at an angle to the indicated plane, in which most parts of the signal element are located, and have parts parallel or perpendicular to this plane, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. This means that in any of these options or their combination, the spokes are extended in two directions: in the direction from one part of the signal element to the other (that is, in the plane of the signal element), as well as in the direction perpendicular to several mismatched directions from one parts of the signal element to another (that is, perpendicular to the plane of the location of the signal element), thereby providing, in a particular embodiment, the determination of breakdown of the insulator. In the particular case, the spokes can be part of the fastening element, thereby providing, in a particular embodiment, the determination of breakdown of the insulator.

Destructible element can be performed using various physical principles, providing in private options the definition of breakdown of the insulator, such as:

- melting a conductor with a small cross-sectional area by a short circuit current - the principle of fusible insert;

- melting by a short-circuit current of a contact (contact pad) with high contact transition resistance, for example, of an electrical connection with a small contact area;

- the destruction of the sealed chamber, the internal cavity of which is filled with gas (for example, air) and / or liquid and / or solid (for example,

dielectric) material inside which an electric discharge occurs due to the high internal pressure created by the expansion of gases during heating and the transition of solids inside the chamber into a gaseous or plasma state;

- destruction of the sealed chamber, inside which there is an explosive or flammable substance, when a short circuit current passes through it - the principle of the igniter;

In a preferred embodiment, the signal element may be configured to conduct current flowing through the punched insulator and transmit it through the destructible element, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. To this end, the indicator signal element may contain a conductive arc-receiving element, one part fixed to the signal element, and the other part directed to the insulator (for example, to the axis of the insulator), thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The arc-receiving element can be used to bypass a part of the insulating element located between the arc-receiving element and the end of the insulator on which the indicator is mounted, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The arc-receiving element should preferably be at such a distance from the insulator that the breakdown voltage of the insulating gap from the possible path of breakdown inside the insulator to the arc-receiving element is less than the phase voltage of the overhead line and less than the breakdown voltage of the air gap of the shunted indicator part of the insulating element, thereby ensuring, in particular variant definition of breakdown of the insulator. In other words, the length of the arc-receiving element, in fact, should be less than the distance between the signal element of the indicator and the insulating part of the insulator when installing the indicator on the insulator, thereby providing, in a particular embodiment, the determination of breakdown of the insulator.

In addition, the signal element may include a contact element connected to the signal element and configured to connect to the insulator, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The contact element may be an arc-receiving element that can touch the insulator (for example, its insulating body), thereby providing, in a particular embodiment, the determination of breakdown of the insulator. In this case, the length of the arc-receiving element, in fact, has a value equal to

the distance between the signal element of the indicator and the insulating part of the insulator when the indicator is mounted on the insulator, that is, it ensures that the insulating element touches the insulator, thereby providing, in a particular embodiment, the determination of breakdown of the insulator.

The signal element may not have an arc-receiving element, but independently perform its function due to the shape of the signal element itself or its location, providing the above-described ratio of the insulation gaps, for example, with an eccentric arrangement of the conductive signal element relative to the axis of the insulator, thereby providing, in a particular embodiment, the definition breakdown of the insulator.

In addition, the signal element can have an indestructible short-circuit current articulated or flexible (for example, cable) connection (including dielectric) to the mount, with an insulator, or with another electrical installation element in order to prevent the signal element from falling below a predetermined level , providing, thereby, in a particular embodiment, the determination of breakdown of the insulator.

The signal element can simultaneously serve as a screen, preventing corona discharges on insulators of high voltage classes, and, in fact, replace screen armature, thereby providing, in a particular embodiment, the determination of insulator breakdown. The insulator usually contains an insulating body, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The indicator can be configured to pass through a destructible element a current flowing through an insulating body or part of a punched insulator on which it is mounted, or through an insulating body or part of a punched insulator, sequentially (or parallel to or adjacent to) an insulator installed, on which the indicator is placed, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The indicator and its elements are mainly made using metal, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. Destructible element in some embodiments, the implementation can be performed using non-metallic elements, thereby providing, in a particular embodiment, the determination of breakdown of the insulator.

In other embodiments of the utility model, the destructible element may be configured to pass current from a punched insulator through an arc-receiving element connected to the destructible element and directed to the location of the insulator, and / or a contact element connected to the destructible element and configured to connect to the insulator , providing, thereby, in a particular embodiment, the determination of breakdown of the insulator. Destructible element can be made with the possibility of passing current from a punched insulator to the terminator of the insulator and / or electrical installation element through the fastener, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The destructible element may be configured to pass current from the punched insulator to the insulator terminal and / or the electrical installation element through an arc receiving element connected to the destructible element and directed to the location of the insulator terminal and / or electrical installation element, and / or through the contact element connected to destructible element and made with the possibility of connection with the terminal of the insulator and / or element of the electrical installation, thereby providing, in a particular embodiment, the definition of breakdown insulator.

In some embodiments, the indicator may be equipped with a lightning protection horn, thereby providing, in a particular embodiment, the determination of breakdown of the insulator. The lightning protection horn is mainly part of it or is mounted on or near the indicator so as to be located farther from the insulator part of the insulator and closer to the end of the insulator, opposite to the one on which the indicator is mounted, than the conductive parts of the indicator signal element, thereby providing private variant determination of breakdown of the insulator.

The technical result of this utility model is the combination of the function of the screen and the indicator due to the fact that the signal element can simultaneously serve as a screen that prevents corona discharges at high voltage class insulators, and, in fact, replace screen armature, thereby ensuring breakdown detection insulator and cost reduction, since the screen is necessary in any case for insulators with a voltage of 110 kV and higher. When the indicator is triggered as a result of breakdown or overlap of the insulator, the signal part falls down or changes its spatial position. By changing the position of the signal element, clearly visible from long distances, it is possible to determine the fact of breakdown or overlap of the insulator.

Brief Description of the Drawings

In FIG. 1 shows a general view of a suspension insulator equipped with shields.

In FIG. 2 shows an indicator mounted on an insulator in accordance with one embodiment of the utility model.

In FIG. 3 shows an indicator in accordance with one embodiment of the utility model, mounted on an insulator.

In FIG. 4 shows an indicator in accordance with one embodiment of the utility model, mounted on an insulator with a conductive insert.

In FIG. 5 shows a shortened insulator equipped with an indicator in accordance with one embodiment of the utility model.

In FIG. 6 shows an indicator with a lightning horn mounted on an insulator in accordance with another embodiment of the utility model.

In FIG. 7 shows an indicator in accordance with yet another embodiment of the utility model, mounted on an insulator.

In FIG. 8 shows an indicator in accordance with another embodiment of the utility model, mounted on an insulator with a conductive insert.

In FIG. 9 shows an insulator equipped with an indicator in accordance with another embodiment of the utility model.

In FIG. 10 shows a general view of a suspension insulator equipped with screens, the upper of which is an indicator, made in accordance with the present utility model.

In FIG. 11 shows one embodiment of a destructible element that implements the principle of melting a small section conductor.

In FIG. 12 shows another embodiment of a destructible element in which the principle of melting a small cross-section conductor is implemented.

In FIG. 13 shows yet another embodiment of a destructible element in which the principle of melting a small cross-section conductor is implemented.

In FIG. 14 shows one embodiment of a destructible element due to melting of the contact pad by short circuit currents.

In FIG. 15 shows a variant of a destructible element in which two principles are realized simultaneously: a conductor with a small cross-sectional area and with a small contact area.

In FIG. 16 shows a variant of a destructible element, in which the principle of destruction of a sealed chamber released by gases during an arc discharge is implemented.

In FIG. 17 shows a variant of connecting the signal element of the indicator to the insulator using wire.

In FIG. 18 shows an embodiment of installing an arc-transmitting element on a shell of an insulating body of an insulator.

On Fig shows an installation option of the arc-transmitting element on the insulating core of the insulator.

In FIG. 20 shows an embodiment of mounting an indicator on the insulator body.

Utility Model Implementation

Next, the utility model is described with reference to the accompanying figures, which depict individual embodiments of the utility model. The following description and drawings are not intended to limit the scope of protection, which is determined by the formula of the utility model, but are given to simplify the understanding of the essence of the utility model and possible options for its implementation, which are not limited to those presented in the figures and description. The utility model is further described in relation to a suspended polymer insulator, but is not limited to this type and can be used in relation to any insulators (including reference, non-polymer, etc.) where it can be applied.

The same reference numerals in FIG. 1-20 relate to elements having the same functionality. In the case of a description of an element with respect to one or several figures, this description also applies to similar elements (i.e., elements with the same numbers by position) in other figures, unless otherwise stated or if partial differences while maintaining the main functional derive from the design or purpose of the element in accordance with the figure and / or description.

The indicator proposed in accordance with the present utility model in one of the main embodiments is a signal element 2 in FIG. 1-10, 17-20, which in a particular case can combine the screen function for the insulator 1 in FIG. 1, 3, 4, 7, 8, 10, 17-20, fixed through elements 11 destroyed by a short circuit current on an insulator, in particular, as shown in FIG. 2-10, 17-19, on the terminator 3 of the insulator, or on the electrical installation element, or on the insulating body 1 of the insulator, as shown in FIG. 20, having the function of indicating breakdown of the insulator. The signal element can be made of metal or other materials having a conductive coating or combined of metal and non-metallic materials.

The indicator is fully or partially made conductive, mainly using metal, and incorporates a signal element 2. In the embodiments shown in the figures, the signal element is ring-shaped (in the form of a toroid), however, its shape may be different. For example, the signal element may be elongated or oval, closed or open, flat or three-dimensional. In addition, the signal element may be made arcuate, and in some embodiments, such an arc may be a sector of the ring.

Thus, the shape of the signal element in the plan can be round, oval, oblong, more complex or simpler, determined from the calculation of the electric field, material consumption and visual perception. If the indicator combines screen functions, the total size of the indicator signal element in the plan is selected so that it is not less than the calculated one under the conditions of permissible electric field strength and, at the same time, is clearly visible from the ground (i.e., at a distance of 10-300 m ) to the naked eye. Depending on the voltage class of the power line, the size of the signal element as a whole can advantageously range from 100 mm to 1000 mm.

The cross section of the signal element can be round, tubular, rectangular or have a more complex shape, determined from the calculation of the electric field strength according to the criteria for permissible tension acting on polymeric materials, manufacturability and material consumption. To prevent corona discharge, all convex parts of the signal element must have a radius of curvature of at least a value that depends on the voltage of the power line. Required value

the smallest radius of curvature can be calculated by formulas and tables known from reference books and textbooks.

In addition to the signal element, the indicator contains one or more spokes 7 in FIG. 2-9, 17-20. The spokes are made conductive mainly using metal with the possibility of fixing on the terminal or insulating body of the insulator by means of a mounting unit, which may be part of the spokes. To this end, the spokes can be adapted to embrace and crimp the terminal or insulating body, as shown in FIG. 1-10, 17-20. In addition, the knitting needles may themselves be covered by the attachment unit or attached to the terminal or insulating body in other ways, providing both mechanical fastening and electrical contact of the knitting needles and the terminal necessary for the implementation of this utility model. In some cases, when mounting the indicator to the insulator is difficult due to the small size of the terminal, the indicator can be fixed to the fasteners, through which the terminal of the insulator is connected to the elements of the electrical installation.

The number of spokes is determined from design considerations to ensure a strong fixation of the signal element of the screen and prevent it from breaking during transportation, storage, installation and maintenance of the insulator. The minimum number of knitting needles is one. The spokes have elements that are destroyed by short-circuit current.

One of the fracture principles implemented in the utility model is the melting of a conductor with a small cross-section by large short-circuit currents. To do this, they can have a cross-sectional area that ensures the melting of the fusible section by the breakdown current for a predetermined time interval during which the arc acts until the automatic protective shutdown of the line is triggered. In a particular embodiment, the spokes can be made completely in the form of a fusible element, which has the length of the spokes and melts under the action of the breakdown current of the insulator, or the spokes can have a local narrowing of the cross section to the required value of its area, as in FIG. eleven.

The cross-sectional shape of the fusible element with an area of S (in Fig. 11-13) can be round, tubular, rectangular or any other, determined from design considerations and the strength of fixation of the signal element

screen. In FIG. 11 shows an element destroyed by melting in the form of a local narrowing of a spoke.

In FIG. 12 shows a fusion-destructible element in the form of a tube with a small cross-sectional area. This solution allows for a small cross-sectional area to provide high mechanical strength of the connection of the signal element with the spoke due to the higher bending or torsion strength of the tubular beam compared to a circular beam with the same area.

In FIG. Figure 13 shows a melting-breakable element in the form of a thin-section wire enclosed to provide mechanical strength and rigidity of the joint in a dielectric casing. Such a solution can be implemented in cases of small short-circuit currents or a short response time of the overhead protective shutdown.

The cross-sectional area S of a single-spoke fusible element is calculated by the formula known from textbooks and reference books on electrical engineering:

,

,

where S is the cross-sectional area of the fusible element of one spoke, m ² ;

n is the number of knitting needles;

I - current, A;

ρ is the specific resistance of the material of the fusible element of the spoke at normal temperature (20 ° C), Ohm m;

τ is the current flow time, s;

k is the coefficient of performance, which determines the proportion of energy spent on the fusion of fusible elements (determined experimentally);

s - specific heat of the material of fusible elements, J / (kg (K);

δ is the density of the material of the fusible elements, kg / m ³ ;

t _PL - the melting temperature of the material of the fusible elements, ° C;

t ₀ - ambient temperature (20 ° С), ° С.

The magnitude of the short circuit current (arc current) during the breakdown of the insulator depends on the parameters of the power line, and the exposure time of the short circuit depends on the protective shutdown equipment used on the overhead line. For overhead lines of 110 - 750 kV, for which the problem to be solved is the most urgent, the arc current can reach 20 kA at an exposure time of 0.2 s (these values are given in the methods for testing arc insulators 110-750 kV for arc resistance).

Table 1 shows the calculated values of the cross-sectional area of destructible elements of conductors made of aluminum and stainless steel at arc currents of 20 kA and 2 kA, with an efficiency of 0.5 and an exposure time of 0.2 s.

The obtained cross-sectional areas of destructible elements are easily realized structurally by one or more of the proposed in FIG. 11-13 ways.

Another principle of fracture, implemented in a utility model, is the melting of the contact area of the electrical connection with a high contact transition resistance, for example, due to the small contact area. In FIG. 14 shows a variant of a destructible element due to the melting of the contact area by short-circuit currents when a high-density current passes through a point contact. The effect can be enhanced by the use of materials for contacts forming an oxide film in the contact zone due to

electrochemical corrosion, thereby increasing the contact transition resistance.

Another principle of destruction implemented in the utility model is the principle of destruction of a sealed chamber made of dielectric material, inside which an electric discharge occurs due to the high internal pressure created by the expansion of gases during heating and the transition of solid or liquid substances inside the chamber under the action of an electric arc into a gaseous or plasma state. In FIG. 16 shows an embodiment of such a destructible element. With the passage of a short circuit current, an arc is formed inside the chamber, which melts and burns solid (liquid) substances in the chamber and expands gases, creating high pressure, due to which the walls of the chamber are destroyed or metal spokes are pushed out of the chamber. In the particular case, the chamber cavity can be completely filled with solid dielectric material, including the one from which the chamber walls are made, i.e., the conductive parts of the destructible element can be completely covered with solid dielectric material.

As a destructible element, a commercially available or specially manufactured squib can also be used. With the passage of current through the igniter, the explosive explodes with loss of integrity of the igniter. To protect against accidental operation against induced static charge, a squib cartridge with protection against induced electricity can be used. In another embodiment, a conductor with a very small cross section, not able to withstand the arc current, can be used electrically installed in parallel with the igniter to equalize the charge. In this case, during the breakdown of the insulator, the thin conductor is first destroyed, and then the igniter is triggered, releasing the signal element.

In a destructible element, several of the above destruction principles, for example, a small cross-sectional area and a small contact area, as in FIG. 15, which shows a signal element riveted to a spoke with a tubular rivet through a dielectric spacer.

All destructible elements shown in Figures 11-16 can be fixed on the indicator permanently or can be replaced by means of a threaded, collet or other detachable connection to allow the indicator to be reused or changed

sensitivity due to the installation of destructible elements with different response energies.

As seen in FIG. 1-10, 17-20, the spokes are extended in two directions: in the direction from one part of the signal element to the other (for example, the opposite), as well as in the direction perpendicular to several directions from one part of the signal element to the other. If the signal element is in the form of a ring, as shown in FIG. 1-10, 17-20, of a toroid, arc, or other shape that can be located in the plane, the direction from one part of the signal element to the other can pass in the plane of the signal element, and the direction perpendicular to several directions from one part of the signal element to another may be perpendicular to this plane.

The spokes must have a component in the direction from one part of the signal element to the other because the signal element, which is a screen for protection against corona discharge, must have dimensions larger than the diameter of the insulator - both for protection against corona discharge and for performing indicator functions in accordance with this utility model: firstly, the large size of the signal element makes it easy to determine its location from a large distance (for example, from the ground, when the indicator is mounted on an insulator on an electric line transmissions); and secondly, the signal element must be larger in plan size than the cross section of the insulating element of the insulator.

Such an excess of the internal size of the signal element of the cross-section of the insulator insulator element is necessary so that the signal element can be placed not near the terminator, but near the insulator element, as shown in FIG. 3 and 7. This ensures the implementation of the principle of operation of this utility model.

The breakdown of the insulator develops from the end of the insulator, which is energized with respect to the grounded end (in Fig. 1, 3, 4, 7, 8, 10, 17-20 - from the lower to the upper). This is due to the fact that the electric field near the terminal is under voltage, significantly higher than the field near the grounded terminal. Partial discharges occur in insulator defects located in areas with a high electric field strength - closer to the terminal, which is energized, carbonize the material around it, forming

tracks - conductive tracks, which themselves are sources of partial discharges and gradually develop in the direction of a grounded terminal. In the event that the arc-receiving element of the signal element or the signal element itself is located at such a distance from the front of the track, whose electric strength is less than the electric strength of the section of the insulation gap shunted by the indicator, the breakdown channel of the insulator from this point on the insulator will not go to the grounded terminal insulator, and through a signal element, which, due to electrical contact with the spokes, has the potential of a grounded terminal. When a short-circuit current passes through destructible elements of the spokes, they will collapse and the signal element will be separated from the grounded terminal, as a result of which it will fall down under the influence of gravity or, if there is a dielectric cable or hinge limiting the fall, will change its position in space. The absence of such a large element as a signal element, or a change in its spatial position is easy to notice from a long distance, which was the purpose of this useful model.

In order that the signal element of the indicator could be located near the insulating element of the insulator, and the spokes were fixed on the upper terminal 3 (Fig. 3, 4, 5, 7, 8, 9, 17-19), the spokes should pass from the place of attachment to signal element. That is, the spokes should be extended not only in the direction from one part of the signal element to another (i.e. parallel to the plane of the signal element, since the projection of the indicator attaching to the upper terminal on this plane is between the projections of the parts or inside the projection of the entire signal element), but should also be extended in the direction perpendicular to the plane of the signal element (or lines connecting its parts, if one is not in the same plane), and due to the length of the spokes in the second (perp dikulyarnom) direction of the signal element is distant from and close to the solderless insulation element isolator.

For reliable operation of the indicator, it is necessary that the breakdown voltage of the insulation gap between the front of the breakdown track and the signal element is significantly less than the breakdown voltage of the insulation gap between the front of the breakdown track and the upper terminal. There are several ways to reduce it. Firstly, the signal element can be equipped with an arc-out (arc-receiving) pin 4 (Fig. 2 - 9). Thanks to this pin 4, the distance between the signal element, of which the arc-receiving pin is a part, and the insulating part of the insulator is reduced, which increases the likelihood of the indicator tripping in case of breakdown of the insulator.

The arc-receiving (arcing) element (pin) is mainly connected to the signal element and directed to the location of the insulator. The length of the arc-receiving element in one embodiment is less than the distance between the signal element of the indicator and the insulating part of the insulator when the indicator is installed on the insulator, due to which there is a gap between the arc-receiving element and the insulating part of the insulator, through which the leakage current of the punched insulator passes in the form of a discharge arc. In FIG. 4 and 8 show a particular implementation of this option when the arc-receiving element 4 is directed to the insert 8. In this case, the discharge arc passes between the insert and the arc-receiving element, and the length of the arc-receiving element is still less than the distance between the signal element of the indicator and the insulating part of the insulator.

In another embodiment shown in FIG. 3 and 7, the length of the arc-receiving element 4 has a value equal to the distance between the signal element 2 of the indicator and the insulating part (in particular, the surface of its insulating shell 6) of the insulator when the indicator is mounted on the insulator. Due to this, the arc-receiving element touches the insulating part of the insulator and when the front of the track passing through the insulating body of the punched insulator approaches the pin at a certain distance, the breakdown voltage of which is lower than the voltage at the insulator, breakdown of the insulation shell will occur with the formation of an arc from the front of the track to the arc-receiving pin .. From - due to thermal deformation of the shell and the rod (compression at negative temperatures), a gap appears between the pin and the shell, and then the arc-receiving element becomes smaller than The distance between the signal element and an insulator that is between the member and the insulator dugopriemnym gap appears in which, in case of breakdown of the insulator, the discharge arc will be located.

The arc-receiving (arcing) element in some embodiments can be connected to the destructible element and directed to the location of the insulator. In this case, the current from the punched insulator, passing through the arched element, will flow through the destructible element. Possible implementations and advantages of this modification of the indicator correspond to those of the indicator, in which the arc-receiving (arc) element is connected to the signal element.

Secondly, it is possible to use a metal element 8 in the insulator (Figs. 4, 8 and 19), for example, in the form of a sleeve placed on the insulator rod 5 (mainly fiberglass) and partially coated with an insulating sheath 1, providing an open surface of the sleeve 8, uncoated. In this case, the breakdown voltage of the air gap between the embedded element and the signal element (in particular, the pin) will be significantly less than the breakdown voltage of the air gap between the embedded element and the upper terminal or the spoke of the screen. In the particular case, the pin may touch the embedded metal element. The metal embedded element reduces the breakdown voltage of the insulating gap between the front of the breakdown track and the arcing pin (or signal elements) due to the absence of a dielectric layer between them, which increases the reliability of the indicator.

The proposed solution achieves high reliability of the structure due to simplicity, and if the signal element combines the functions of the screen, it reduces the cost, since the screen is necessary in any case for insulators with a voltage of 110 kV and higher. A typical application of the indicator is linear suspended polymer insulators with voltage of 110 kV and higher, but can be used for other types of insulators, as well as for insulators for lower voltage classes.

The preferred use of the indicator in accordance with this utility model is the indication of breakdown of a polymer insulator. Polymer high-voltage insulators with a protective sheath made of organosilicon rubber (silicone) have many advantages over traditional glass and porcelain, in particular: high discharge characteristics in conditions of pollution, high reliability (the failure rate of electric strength is 2-3 orders of magnitude lower than that of glass plate insulators), energy saving due to low losses of current leakage on a contaminated surface, resistance to shock electromechanical loads.

Despite the high reliability, the massive use of polymer insulators on power lines is constrained by the complexity of determining punched insulators, since visually without the use of optical devices, a punched polymer insulator on a 110-750 kV power line suspended at heights of 15 to 40 m from the ground can only be determined from close range and impossible from the ground.

Horse inspections using lifting equipment or aircraft equipped with a video camera are quite laborious and require a lot of time and financial costs. Unlike polymer, the glass insulator during breakdown is destroyed with the loss of its glass part, which is easily determined visually from the ground without the use of devices or equipment. Thus, despite the fact that the reliability of the polymer insulator is significantly higher, and the price is usually lower than glass, the consumer prefers glass insulators.

Creating an indicator that makes it possible to determine the state of polymer insulators as simple as glass insulators can fundamentally change the ratio among the types of linear insulators in favor of polymer ones, which will make it possible to realize their other positive qualities and, in particular, energy saving.

To date, there are no simple and reliable breakdown indicators for polymer insulators. As noted above, optical indicators are unreliable, unreliable and have a limited life. Breakdown indicators using a tempered glass element based on serial insulating elements of glass plate insulators have low reliability. Glass insulators are prone to spontaneous destruction during electrodynamic loads, from aging or from internal stresses obtained during manufacture. The failure rate of a glass plate insulator (plate destruction) ranges from 10-3 to 10-4 failures per year, and that of a polymer insulator is 10-6 failures per year. That is, the reliability of the polymer insulator is 100-1000 times higher than glass. This means that for 1000 cases of operation of an indicator based on a glass insulator there will be only 1 to 10 breakdowns of the polymer insulator, and the reliability of the indication by such a device is from 0.1% to 1%.

The problem of detecting breakdown of a polymer insulator can be solved using a real utility model. A breakdown in the polymer insulator develops from the place of damage to the insulator protective shell in the area with increased electric field strength near the energized terminal (for linear suspended insulators - near the lower terminal) to the grounded terminal (upper). In the zone of damage to the protective shell under the influence of electric field in a humid environment, partial discharges begin to form, which, acting on the material of the fiberglass rod 5 (Fig. 3, 4, 5, 7, 8, 9), form

Carbonized conductive track - a track in the rod or along the interface of the rod with the protective sheath, which develops towards the grounded terminal.

In a conventional insulator, not equipped with a breakdown indicator, the track reaches a grounded terminator and an electrical breakdown of the insulator is formed, accompanied by an arc discharge - a power electric arc that lasts until automatic protection trips at the substation and disconnects the voltage on the power line.

In a polymer insulator equipped with a breakdown indicator in accordance with this utility model, the sequence of events is different. When the voltage of the breakdown of insulation between the front of the track and the signal element of the screen (i.e., for example, the voltage of the breakdown of the layer of the protective sheath 6 for Fig. 3 and 7 or the air gap between the pin 4 and the embedded element 8 for Fig. 4 and 8) becomes less phase voltage due to the development of the track towards the screen and reduction of the insulation gap, an electrical breakdown of the insulation gap occurs between the signal element and the front of the track. The current passes from the lower terminal through the track, through the arc in the gap between the front of the track and the indicator (directly to the indicator signal element or through the arc pin), through the signal element and then through the indicator spoke to the grounded terminal. With the passage of current through the spokes of the indicator, it destroys the destructible elements of the spokes. The signal element is disconnected from the spokes and falls under its weight down onto the lower screen. In the design of the indicator, it may be possible to prevent the signal element from falling onto the lower screen by means of a flexible connection (for example, a cable, which can be dielectric) or a swivel, which can also be dielectric, of a signal element with an indicator element, an insulator, or an electrical installation element. In this case, the signal element hangs on a cable or rotates on a hinge, changing its position in space. The absence of a signal element (in the particular case of the upper screen) or a change in its position in space signals that the insulator was blocked by a power electric arc.

The indicator can be used as a stand-alone product, suitable for mounting on operating polymer insulators in place of an existing screen. In addition, the breakdown indicator can be used as part of an insulator, the insulating element of which, consisting of a rod 5 and an insulating sheath 6, has a small length between the terminators, which is completely shunted

indicator (see Fig. 5 and 9). In this case, such an insulator can be used as a breakdown indicator for insulators of any type suspended from the bottom on the lower terminal 9 in series with the insulator - indicator.

Shown in FIG. 1-5, the breakdown indicator will respond not only to an electric arc arising from the breakdown of insulators, but also to an arc arising from a thunderstorm or severe contamination of the surface of the insulator with a working insulator. To prevent the indicator from tripping during a thunderstorm or pollution, the indicator can be equipped with a lightning protection horn 10, shown in FIG. 6-10.

To prevent the indicator from tripping during a thunderstorm or pollution, it is necessary to ensure that the minimum distance H1 (Fig. 10) from the lower screen of the insulator to the lightning protection horn is less than the minimum distance. H2 from the lower screen to the signal element or arc-receiving pin; in the particular case, to the top screen, which is an indicator in accordance with the utility model (Fig. 10). The indicated ratio of the distances H1 and H2 from the indicator elements to the lower screen of the insulator is equivalent to the ratio of the distances from the lightning protection horn and the signal element to the lower end of the insulator, because in fact, the difference between these distances will be approximately the same for these indicator elements. Those. the minimum distance from the lower end of the insulator to the lightning protection horn should be less than the minimum distance from the lower end of the insulator to the signal element of the indicator. Under this condition, a discharge during a thunderstorm or pollution will go to a lightning protection horn, and not to the indicator screen, bypassing destructible elements, and the indicator will not work. At the same time, during breakdown of the insulator, the discharge will not go to the lightning protection horn, but to the indicator, which, as a result of this, will work and thereby indicate the punched insulator.

A lightning protection horn may be part of an indicator, as in FIG. 6, 8, 9, or may have its own attachment to the insulator terminal, as in FIG. 7, 10.

On the power line can be used as a variant of the indicator that works on any short circuit (Fig. 1-5, 17-20), and a variant of the indicator that works only on a breakdown (Fig. 6-10).

In some embodiments, the implementation of the indicator may be connected to the insulating body of the insulator using additional elements. For example, as shown in Fig. 17, the signal element 2 of the indicator is connected to the insulating body 1 of the insulator using a wire 4, which is wound, with

on the one hand to the signal element 2, and on the other hand to the shell of the insulating body 1. This ensures the transfer of the breakdown current of the insulator from the insulating body to the signal element and further to the destructible elements 11 without using an electric arc. Thanks to this solution, there is no need to install arc-receiving and / or arc-transmitting (arc-guiding) elements, as well as the need to position the signal element near the insulating body of the insulator, which simplifies the design of the indicator. And when the indicator is triggered, the signal element changes its spatial position, hanging on the wire. A similar mode of action of the indicator will also be in the case when a destructible element is connected to the insulator using a contact element, such as a wire.

In other embodiments of the utility model, an insulator may be provided with an arc-transmitting (arc-receiving) element 4, as shown in FIG. 18 and 19. For example, in accordance with FIG. 18, the arc-transmitting element 4 can be attached to the patch element 18, which can be made in the form of a metal sleeve mounted on top of the insulating shell 1 of the insulator on the insulating body between the terminators. The arc-transmitting element 4 is directed to the indicator, in particular, to its signal element 2, providing between them a discharge gap in which an arc can form. In a particular embodiment, not shown in the figures, such an arc-transmitting element can touch the indicator (its signal element or other elements) and serve as a current-transmitting element, which in the future can become an arc-transmitting element if the contact between the elements breaks.

In FIG. 19 shows an installation option of the arc-transmitting element 4 on the embedded element 8 mounted on the rod 5. The principle of operation and possible implementations are similar to those described with respect to FIG. eighteen.

The above describes the options when the indicator can be installed on the insulator by fixing it with a fastening element that is mounted on the insulator (terminal and / or insulating body) and / or electrical installation element. In the described embodiments, the current of the punched insulator flowing through the destructible element also flows into the terminal and / or the electrical installation element through the fastening element. However, it is possible that the current flowing through the destructible element flows into the terminal and / or the electrical installation element not through the fastening element, but in other ways, for example, through the discharge gap between the destructible element and the terminal and / or

electrical installation element, either through an arc-receiving (arc-transmitting) element between them, or through a contact element.

It should be noted that the indicator, in addition to the terminal and / or electrical installation element, can be installed on other parts of the insulator, for example, on its insulating part (insulating body). In this case, the destructible element may pass current from the punched insulator to the insulator terminal and / or the electrical installation element through an arc-receiving element connected to the destructible element and directed to the location of the insulator terminal and / or electrical installation element, and / or through the contact element connected to the destructible element and made with the possibility of connection with the terminal of the insulator and / or element of the electrical installation.

The indicator can be configured to pass through a destructible element of current flowing through the entire insulating body of the punched insulator on which it is installed, or part of it. In the formula and description, the sign “current flowing through the insulating body” should be interpreted as “current flowing through the entire insulating body or through a part of the insulating body”.

The indicator can be mounted on a small insulator, which is designed for serial or parallel installation (or just next to it) with the insulator, the breakdown of which the indicator should show. Such an insulator with indicator is shown in FIG. 5 and 9. In the case of a series connection of the indicator insulator (i.e., the insulator with the indicator) shown in FIG. 5 or 9, with an insulator whose breakdown must be displayed by changing the position of the indicator signal element, the breakdown current flows through the entire insulating body of the punched insulator to the terminal, which is connected to the terminal 3 or 9 of the indicator insulator, and then through the terminal 3 or 9 to the indicator through fastening element or arc-receiving element 4. The operation of the indicator occurs as previously described in relation to other indicators. Various embodiments of the indicator insulator are also possible in accordance with the previously described variants of the indicator and its functioning.

In cases where the indicator insulator is installed parallel to or next to the insulator, the breakdown of which it should indicate, the current flowing through the insulating body of the punched insulator or part of the insulating body of the punched insulator may be incident on the indicator (on the destructible and / or signal element and / or arc-receiving element)

case, when the indicator or its elements are located close to the insulating body so that the current from the insulating body of the punched insulator passes to the indicator through the discharge arc.

In some embodiments, the indicator placed on the indicator insulator, or its elements, can be connected to a punched insulator (in particular, its insulating body) using a contact element (for example, such as a wire) similarly to the embodiment shown in FIG. 17. In addition, similarly to the options shown in FIG. 18 and 19, the punched insulator may be provided with an indicator element (pin) directed to the indicator placed on the indicator insulator and forming a discharge gap with it or touching it.

In FIG. 20 shows that the indicator can be mounted on the insulating body 1 of the insulator. The spokes 7 extend from the fastening element in the direction of the signal element 2, which is made in the form of a toroid forming a screen for protection against corona discharges. In the needles 7 are placed destructible elements 11, the principle of which is described above in relation to various options for implementation. As shown in FIG. 20 variant, the signal element 2 contains an arc-transmitting element 4, which departs from the signal element 2 in the direction of the terminal 3 and can touch it or is at some distance. The principle of operation of the indicator in this installation option is similar to the above modifications.

Presented on the accompanying figures and described in detail in the description of the embodiments are intended to simplify the understanding of the essence of the utility model and should not be construed as limiting the scope of protection of the utility model, determined by the subsequent formula of the utility model. The described options can be combined and combined in any combination that ensures the implementation of the principle of operation and the achievement of a technical result, which consists in providing the ability to visually determine the breakdown of the insulator and its overlap at a considerable distance from it. As a result of the combination of individual options, additional technical results can be achieved.

Claims (23)

1. An insulator equipped with an indicator of breakdown of the insulator, and the indicator of breakdown of the insulator is made in the form of a screen for protection against corona discharge and equalization of electric field strength and has a signal element configured to equalize electric field strength, and at least one element destroyed by electric current moreover, the signal element or part thereof is fixed to the insulator through the destructible element with the possibility of changing the position of the signal element as a result those destruction of the destructible element, and the destructible element is configured to pass through it a current flowing through the punched insulator. 2. The insulator according to claim 1, characterized in that it has a conductive insert in the insulating body and / or on the insulating body above the lower terminal. 3. The insulator according to claim 2, characterized in that the conductive insert has an arc-receiving element connected to the conductive insert and directed to the location of the signal element and / or destructible element. 4. The insulator according to claim 1, characterized in that the indicator is configured to transmit the current of the punched insulator from the lower terminal to the signal and / or destructible element. 5. The insulator according to claim 1, characterized in that it is equipped with a fastening element that secures the indicator to the insulator. 6. The insulator according to claim 1, characterized in that the fastening element is configured to be installed on the terminal of the insulator and / or on the insulating body of the insulator. 7. The insulator according to claim 1, characterized in that the destructible element is a spoke or a part of the screen spoke, the spoke being extended both in the direction passing through the mismatched portions of the signal element and in the direction perpendicular to several mismatched directions passing through the mismatched parts of the signal element. 8. The insulator according to claim 7, characterized in that the signal element has a flat structure, the spoke being extended both in a direction parallel to the plane in which the signal element is located and in a direction perpendicular to this plane. 9. The insulator according to claim 1, characterized in that the signal element is configured to conduct current flowing through the punched insulator and transmit it through the destructible element. 10. The insulator according to claim 9, characterized in that the signal element comprises an arc-receiving element connected to the signal element and directed to the location of the insulator, and / or a contact element connected to the signal element and configured to connect to the insulator. 11. The insulator according to claim 10, characterized in that the length of the arc-receiving element is less than the distance between the signal element of the indicator and the insulating part of the insulator when the indicator is installed on the insulator. 12. The insulator according to claim 10, characterized in that the length of the arc-receiving element has a value equal to the distance between the signal element of the indicator and the insulating part of the insulator when the indicator is installed on the insulator. 13. The insulator according to claim 1, characterized in that the destructible element is configured to pass current from the punched insulator through an arc-receiving element connected to the destructible element and directed to the location of the insulator, and / or a contact element connected to the destructible element and made with the ability to connect to the insulator. 14. The insulator according to claim 1, characterized in that the insulator contains an insulating body, and the indicator is configured to pass through a destructible element of current flowing through the insulating body or part of a punched insulator. 15. The insulator according to claim 1, characterized in that the destructible element is configured to pass current from the punched insulator to the insulator terminator through the fastener. 16. The insulator according to claim 1, characterized in that the destructible element is configured to pass current from the punched insulator to the insulator terminal and / or the electrical installation element through an arc receiving element connected to the destructible element and directed to the location of the insulator terminal and / or contact element connected to destructible element and made with the possibility of connection with the terminal of the insulator. 17. The insulator according to claim 1, characterized in that it is equipped with a lightning protection horn. 18. The insulator according to claim 17, characterized in that the lightning protection horn is placed so that when the indicator is mounted on the insulator, the horn is located farther from the insulator part of the insulator and closer to the end of the insulator, opposite to the one on which the indicator is mounted, than the indicator signal element. 19. The insulator according to claim 1, characterized in that the destructible element is a conductor with a small cross section, destroyed by a short circuit current. 20. The insulator according to claim 1, characterized in that the destructible element is a contact pad with a high contact transition resistance, which is destroyed by a short circuit current. 21. The insulator according to claim 1, characterized in that the destructible element is a sealed chamber, the inner cavity of which is filled with gas, for example, air, and / or liquid and / or solid material, which is destroyed by the increase in internal pressure as a result of the action of an arc discharge inside the chamber at short circuit current. 22. The insulator according to p. 1, characterized in that the destructible element is a squib that is triggered by a short circuit current. 23. The insulator according to claim 1, characterized in that the signal element is provided with a flexible connection or swivel with a fastening element and / or an insulator, and / or an electrical installation element, limiting the level of its fall.

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