RU149891U1 - DISPLAY SCREEN - Google Patents

Abstract

1. The screen for leveling the electric field near the element of electrical equipment or power lines, made with the possibility of mechanical fastening on the specified or adjacent element of electrical equipment or power lines and containing an elongated conductor, made with the possibility of electrical contact with the specified or neighboring element of electrical equipment or power lines and at least partially round the specified element of electrical equipment or transmission lines, characterized in that the screen comprises an insulation layer at least partially covering said elongated conductor, and at least a first main electrode mounted on top of the insulation layer and / or at least partially in the insulation layer. . The screen according to claim 1, characterized in that it is capable of bending around an element of electrical equipment or a power line with an insulating body within an angle of up to 30, 60, 90, 120, 150, 180, 210, 240, 270, 300, 330 or 360 degrees inclusive .3. A screen according to claim 1, characterized in that the discharge voltage of the sliding discharge over the surface of the insulation layer between the first main electrode and the elongated conductor is less than the discharge voltage of the discharge through the air gap between the first main electrode and the elongated conductor. The screen according to claim 1, characterized in that it comprises a second main electrode installed to provide electrical contact with the elongated conductor, the discharge voltage of a sliding discharge along the surface of the insulation layer between the first main electrode and the elongated wire

Description

The technical field to which the utility model relates.

The proposed utility model relates to protective fittings installed on electrical equipment, in particular, on insulators or strings of insulators, designed to protect against arcing and / or corona discharge and / or to equalize the voltage distribution across the insulator or strings of insulators. In addition, the proposed utility model also relates to arresters for protecting electrical equipment from lightning surges. Such devices can protect, for example, high-voltage installations, insulators and other elements of high-voltage power lines, as well as electrical equipment.

State of the art

Known, in particular, from patent US 6455782, a screen designed to equalize the distribution of voltage across a string of insulators or the distribution of electric field along polymeric insulators. Such screens also provide the ability to limit the electric field in the insulating rod of the insulator on which they are installed. In addition, the screen allows you to protect electrical components from corona discharges.

At the same time, it should be noted that this screen does not solve the problem of protecting the electrical equipment on which it is installed from overvoltages caused, for example, by lightning discharges.

Utility Model Disclosure

The objective that this utility model solves is the creation of a reliable and low-cost device in production that provides an improvement in the distribution of electric field strength near the elements of electrical installations or power lines on which it is installed, as well as protecting these elements of electrical equipment or power lines from lightning surges . In other words, the objective of the utility model is to provide a device that combines the properties of a spark gap and a screen.

The objective of this utility model is solved with the help of a screen for leveling the electric field in the vicinity of an element of an electric equipment or power line, made with the possibility of mechanical fastening on a specified or adjacent element of an electric equipment or power line and containing an elongated conductor, made with the possibility of electrical contact with the specified or an adjacent element of electrical equipment or a power line, and at least partially th diffraction element or said electric power line. The screen is characterized in that it comprises an insulation layer at least partially covering said elongated conductor, and at least a first main electrode mounted on top of the insulation layer and / or at least partially in the insulation layer. The rounding of an element of an electric equipment or power line by an elongated conductor is advantageously provided with a gap between the conductor with an insulation layer applied thereon, electrodes and other elements, and an element of an electric equipment or power line on the envelope.

The screen is predominantly configured to bend an element of electrical equipment or a power line with an insulating body within an angle of up to 30, 60, 90, 120, 150, 180, 210, 240, 270, 300, 330 or 360 degrees inclusive.

In a preferred embodiment of the shield, the discharge voltage of the sliding discharge over the surface of the insulation layer between the first main electrode and the elongated conductor is less than the discharge voltage of the discharge through the air gap between the first main electrode and the elongated conductor.

The shield in some embodiments may comprise a second main electrode mounted to provide electrical contact with an elongated conductor, in which case a discharge discharge voltage across the surface of the insulation layer between the first main electrode and the elongated conductor or second main electrode is preferably less than the discharge voltage of the air discharge between the first main electrode and elongated conductor.

In preferred embodiments, the shield comprises at least one intermediate electrode mounted on top of the insulation layer, wherein the length of the discharge gap along the surface of the insulation layer between the intermediate electrode and the first main electrode is less than the length of the discharge gap along the surface of the insulation layer between the first main electrode and the elongated conductor . In this case, the discharge voltage of the sliding discharge along the surface of the insulation layer between the first main electrode and the intermediate electrode is predominantly less than the discharge voltage of the air discharge between the first main electrode and the elongated conductor. A discharge chamber may be provided between the intermediate electrode and the first main electrode. If two or more intermediate electrodes are provided on the screen, discharge chambers can also be made between them. In the case where the screen contains a second main electrode installed to provide electrical contact with the elongated conductor, the discharge chamber can also be made between the intermediate electrode and the second main electrode.

In other embodiments, the implementation of at least one intermediate electrode may be installed at least partially in the insulation layer, and if the first main electrode is also installed at least partially in the insulation layer, then between the intermediate electrode and the first main electrode a discharge chamber may be formed that extends to the surface of the insulation layer. If the screen contains a second main electrode installed at least partially in the insulation layer to provide electrical contact with the elongated conductor, a discharge chamber can also be formed between the intermediate electrode and the second main electrode, which extends to the surface of the insulation layer. When at least two intermediate electrodes are installed at least partially in the insulation layer on the screen, discharge chambers can also be formed between adjacent intermediate electrodes that extend to the surface of the insulation layer.

In some embodiments, the shield may comprise means for attaching an elongated conductor to an electrical component or power line. Said fastening means are advantageously designed to provide an electrical connection to the elongated conductor with an element of electrical equipment or a power line.

In a preferred embodiment, the bending stiffness coefficient of the screen is at least 1 N / m, 10 N / m, 25 N / m, 50 N / m, 75 N / m, 100 N / m, 200 N / m, 300 N / m , 400 N / m, 500 N / m or 1000 N / m.

The objective of this utility model is also solved by means of a power line containing supports with insulators, at least one electrically energized wire connected to the insulators by means of fixing devices, and at least one screen for leveling the electric field in the vicinity of the element electrical equipment or power lines. The task of the utility model is solved due to the fact that the screen is made according to any of the above options.

In a preferred embodiment, the shield is mounted on the insulator using fastening means, wherein the discharge discharge voltage across the surface of the insulation layer between the first main electrode and the elongated conductor and / or the attachment means is less than the discharge voltage across the air gap between the first main electrode and the elongated conductor and / or fastening means and / or insulator.

The technical result achieved is to reduce the cost of lightning protection and increase its efficiency due to the fact that the screen used to improve the structure of the electric field around the elements of electrical installations or power lines also provides protection of these elements from lightning surges. This allows you to abandon the use of additional lightning protection devices, as well as conveniently provide lightning protection for elements of electrical installations, power lines, electrical insulators or strings of insulators, since the arrester screen can be installed on almost any device. An additional technical result is the provision of a device for lightning protection, having the convenience of installation on power lines or in electrical installations.

In addition, the technical result of the utility model is to increase the voltage of the appearance of a corona discharge on the screen surface due to a decrease in the electric field strength due to the presence of an insulation layer over the metal base of the screen. At the same time, the level of radio interference from the power line is significantly reduced. Also, thanks to the insulation layer, it is possible to install additional intermediate electrodes, the presence of which also reduces the onset voltage of the corona discharge due to the distribution of electric field intensity more extensive in space (this effect is enhanced when electrodes are installed on the outer surface of the screen, remote from the protected elements). In addition, thanks to the combination of the screen and the arrester, it is possible to reduce the space occupied by these elements, since now one device, and not two, performs the functions of the screen and the arrester.

Brief Description of the Drawings

The inventive utility model is illustrated by drawings, where:

In FIG. 1 shows a first embodiment of a screen in accordance with the present utility model.

In FIG. 2 shows a second embodiment of a screen in accordance with the present utility model.

In FIG. 3 shows an embodiment of a screen with intermediate electrodes.

In FIG. 4 shows an embodiment of a screen with intermediate electrodes and discharge chambers.

In FIG. 5 shows an embodiment of a power line with screens mounted on a polymer insulator in accordance with the present utility model.

In FIG. 6 shows an installation option for determining the bending stiffness coefficient of the dielectric element of the arrester in the initial state.

In FIG. 7 shows an installation option for determining a bending stiffness coefficient of a dielectric element of a spark gap in a state of applied bending force.

Identical positions in the drawings are denoted by the same pointers, and when describing a position with a pointer in relation to one drawing, such a description in relation to other figures may be omitted.

Utility Model Implementation

In FIG. 1 shows a first embodiment of a screen in accordance with the present utility model. The screen for leveling the electric field near (in the vicinity) of the element of electrical equipment or power lines is an elongated conductor 1 with a layer of insulation 2 applied to it. The specified conductor can be made in various forms, for example, in the form of a monolithic metal bar (for example, steel, aluminum, copper or from another metal or alloy), preferably of circular cross section, however, in some embodiments, it may have different from circular cross section or consist of several lived. Tape or shaped products may also be used depending on the conditions of use. The sign "oblong" means that the length of the specified conductor is significantly greater (4 or more times) of the width and / or thickness. Due to its elongation, it is usually possible to indicate the longitudinal direction along the conductor (in a particular embodiment, through its ends), that is, in the longest dimension.

The screen is made with the possibility of mechanical fastening on the specified or adjacent element of electrical equipment or power lines. This fastening can be achieved in various ways, for example, by fixing the insulation layer, if this layer by its mechanical properties provides such fastening (that is, for example, it is solid and has protrusions / recesses / holes for fixing with mate fasteners or mate elements electrical equipment or power lines), or, for example, securing the screen as a whole by clamping over insulation. In addition, the ability to fasten the screen to an element of electrical equipment or power lines can be provided by the shape of the screen at the place of attachment, for example, straight, curved, ring-shaped, spiral, etc.

The elongated conductor included in the shield is designed so that electrical contact with the specified element of the electrical equipment or power line is ensured and at least partial bending of the specified element of the electrical equipment or power line when installed on it. The electrical contact may be provided, for example, by an additional conductor connecting the elongated conductor and the element of electrical equipment or power lines, or the contact of the elongated conductor and said element. To enable elongated electrical contact, the conductor may have an open surface (without an insulation layer at this point) for direct or through an intermediate element of electrical contact with the element of electrical equipment or power lines. In addition, to allow electrical contact, the elongated conductor may have a shape conducive to establishing electrical contact with the specified element of electrical equipment or power lines or an intermediate element, for example, straight, curved, annular, spiral, etc., have protrusions / recesses / holes etc. In the event that an insulation layer is located at the point of electrical contact, the conductor may be shaped to allow the insulation layer to be removed (preferably in a simple and convenient way) or to penetrate a metal object through the insulation layer (i.e., pierce / cut through the insulation layer with a needle / knife, etc.) for making electrical contact with an elongated conductor in / under the insulation layer - for example, have a straight, curved, annular, spiral, etc. shape or have protrusions / recesses / holes, etc.

The elongated conductor included in the screen is designed so as to provide at least partial bending of the specified element of electrical equipment or power lines when installed on it. Accordingly, at least a portion of the elongated conductor (and hence the screen as a whole) may be in the form of a circle / circle / ellipse / toroid or may be a sector of a circle / circle / ellipse / toroid, with such a configuration being considered as enveloping / enclosing when the element to be protected or a line running, for example, along the element to be protected, is located inside a circle / circle / ellipse / toroid or sector of a circle / circle / ellipse / toroid (preferably in the geometric center). In addition, depending on the configuration of the electrical equipment (i.e., the distribution of the electric field), at least a portion of the elongated conductor (and hence the screen as a whole) may take the form of a parabola, hyperbola and any other curve of the second or more order of the required size .

In a preferred embodiment, the elongated conductor is mechanically secured to an element of the electrical equipment or power line, in particular, as shown in FIG. 1 option, it contains straight ends 3, which can be used to secure the screen on the element of electrical equipment or power lines. For example, an element of an electrical equipment or power line may include fastening means that fixes the screen at the ends 3. In other embodiments, the ends of the conductor may have parts designed to enclose an element of electrical equipment or a power line, or parts that allow the ends of the conductor to be fixed relative to each other, providing for example, the coverage of an element of electrical equipment or power lines with fixation due to elastic forces. Figure 2 shows a variant of the screen containing means 7 for mounting the screen on an element of electrical equipment or power lines. These means 7 are installed at the ends of the conductor 1 and allow using a bolt, screw, clamp or other connection to compress elements of the means 7 element of electrical equipment or power lines, thereby fixing the screen on this element.

It is desirable that the screen has sufficient mechanical strength (rigidity). Mechanical strength (rigidity) is necessary in order for the screen to retain its shape. Since the part of the screen enveloping the element of electrical equipment or the power line is suspended, with insufficient mechanical strength / stiffness, this part will fall towards the ground and, therefore, the screen will not be able to create (correct) the necessary distribution of the electric field, since the shape of the screen will differ from the set and necessary to create the required distribution of the electric field. The strength / rigidity of the screen can be provided, for example, due to the mechanical properties of the elongated conductor and / or the insulation layer applied to it.

The indicated possibility of mechanical fixing on an element of an electric equipment or power line provides for electrical contact with the indicated element of an electric equipment or power line so that the screen potential is equal to the potential of an element of electric equipment or power line in order to correct the electric field strength around the element of electric equipment or power line. The electrical contact is preferably provided in that the ends 3 or the fastening means 7 do not contain insulation and can directly contact an element of electrical equipment or a power line, which is mainly also made of metal. However, in some embodiments, the ends of the conductor or the fastening means may be coated with an insulation layer, provided that the screen is electrically contacted with the electrical component or power line on which it is attached. Electrical contact can be achieved by performing a part of the insulation layer adjacent to the elements of the electrical equipment or power line with a degree of electrical conductivity sufficient for the purposes of the utility model, for example, by introducing appropriate additives that increase the conductivity of the dielectric material into the insulation layer. In another embodiment, the fasteners may be configured to locally pierce, cut, or remove the insulation layer, with subsequent electrical contact.

The elongated conductor 1 is configured to at least partially bend (cover) an element of the electrical equipment or power line on which it will be installed, or a line running, for example, along the specified element of the electrical equipment or power line. Optionally, the screen has a round shape, but there may be other screen configurations, for example, in the form of a sector, ellipse, and other shapes. The envelope is mainly carried out in a plane perpendicular to the longitudinal direction of the longitudinal element of the electrical installation or transmission line, however, instead of the right angle between the specified direction and the plane, there may be other angles (for example, within 15, 30, 45, 60, 75, 80, 85 degrees or any angle in the range, for example, from 30 to 90 degrees) or the envelope can occur not in a plane, but be curved.

The part of the circle or solid angle in which the electrical element or power line is bent around by the screen is preferably not less than 180 degrees and can be up to 210, 240, 270, 300, 330 or 360 degrees (inclusive) or any range composed using specified values (for example, 180-360 degrees or other). The angle is mainly determined based on the location of the shield or the location of the element of electrical equipment or power lines, to adjust the distribution of the electric field around which the screen is intended. In the case when the screen forms a plane, the place of the beginning of the corner can be defined as the intersection of this plane with the protected element of the electrical equipment or power line (its center point or axis) or as the point on the plane farthest from all parts of the screen (in the case of the screen in the form of a disk or circle, this will be the center of the disk or circle). In some applications, the part of the circle or solid angle in which the electrical element or power line is bent around by the screen can be less than 180 degrees depending on the electric field (for example, its strength indicator), which must be changed, and can be up to or more 30, 60, 90, 120, 150 or 180 degrees (inclusive) or any range compiled using the specified values (for example, 30-180 degrees or another).

In accordance with a utility model, the screen comprises an insulation layer 2, at least partially covering the elongated conductor 1. The coating can be complete provided that, as already mentioned, the electric contact of the conductor with the element of the electrical equipment or power line is provided to adjust the electric field strength around which screen is intended.

On top of the insulation layer 2 and / or at least partially in the insulation layer 2, at least a first main electrode 4 (or with a coating, for example, partially installed on the layer 2 of the electrode 4 (or other electrodes) with an additional layer is installed isolation). The words "at least the first main electrode" means the possibility of placing on the screen a second main electrode, as will be described later, or other additional main electrodes. The first main electrode 4 is installed in such a way as to provide the possibility of transmitting or receiving a discharge of lightning overvoltage to or from other surrounding objects (in one embodiment, from the same screen-arrester, as will be described in relation to Fig. 5). For this, the main electrode 4 can be installed on the insulation layer 2 or in the insulation layer 2 so as to protrude from the layer 2 or be able to connect with an electrical conductor supplying or discharging a lightning overvoltage discharge.

In FIG. 1 also shows the operating principle of the arrester screen in accordance with the present utility model. When overvoltage gets through the spark discharge 5 to the first main electrode 4 due to the fact that the first main electrode 4 is separated by an insulation layer 2 from an elongated conductor 1 having a different potential that matches the potential of an electric equipment or power line, a sliding will develop on the surface of the insulation layer 2 bit 6, reaching the place where he has the opportunity to get to conductor 1 or the element connected to it. As a result, a discharge channel is formed, through which a discharge current flows, equalizing the potentials of the conductor 1 and the first main electrode 4. In FIG. 1 shows that a sliding discharge 6 can develop before it hits a conductor 1, in particular, at the end 3 of a conductor on which there is no insulation.

In the arrester screens shown in the figures, the rounding by the elongated conductor occurs within an angle of about 340 degrees; however, due to the fact that the parts of the elongated conductor extending to the center of the circle in order to be able to fasten, taking into account the insulation layer applied to them, close the circle (that is, lie adjacent to each other), we can say that in this case the envelope is carried out 360 degrees ( taking into account the insulation layer).

As shown in FIG. 2, a second main electrode 8 is applied, placed on top of the insulation layer 2 and galvanically connected to the conductor 1, for example, by means of a connecting conductor passing through the insulation layer 2. In such an embodiment of the arrester screen, a sliding discharge will develop along the surface of the insulation layer 2 until it encounters a second main electrode 8 having an electric potential that matches the potential of the conductor 1, and hence of the electrical component or power line on which the screen is mounted. In the event that the second main electrode 8 in FIG. 2 was absent, a sliding discharge could develop until the end of the insulation layer 2 or to the fastening means 7. In some cases, it may be possible to connect the first main electrode 4 to any object among others objects using an electrical conductor, and in this case, discharge 5 may be absent. One or more electrodes may have protrusions designed to reduce the distance between the electrodes and / or objects with which a spark discharge is performed, to reduce the discharge voltage and increase the probability of discharge occurring precisely through those discharge gaps that form the protrusions.

If the overvoltage from a lightning discharge is on the element of electrical equipment or power line, on which the shield-arrester is mounted, then due to the fact that the first main electrode 4, which has excellent potential, is separated from the conductor 1, which receives the potential of the element of electric equipment or power line with which it is connected , by the insulation layer 2, retains a potential different from the lightning one, and a sliding discharge 6 of reverse polarity develops on the surface of the insulation layer 2, since the potential difference fishing between the electrode 4 and the conductor 1 is sufficient for the formation of creepage.

To enable the screen to function as a spark gap in accordance with the utility model, the discharge voltage of the sliding discharge over the surface of the insulation layer between the first main electrode and the elongated conductor is less than the discharge voltage of the discharge through the air gap between the first main electrode and the elongated conductor. The discharge voltage through the air gap can be determined as follows:

U _B ≈500H,

where H is the length of the discharge gap (gap) in meters;

U _B - discharge voltage, in kV.

The discharge voltage of a sliding discharge along a dielectric (insulation) layer covering a metal conductor can be determined, for example, by the following formula:

U _CK = c · S ^0.2 · (b / (εε ₀ )) ^0.4

where c is a coefficient taking into account the shape of the insulation layer and the metal conductor, S is the length of the moving discharge, b is the thickness of the insulation layer, ε is the relative dielectric constant of the insulation layer, and ε ₀ is the absolute dielectric constant, it has a value of 8.85 · 10 ^-12 F / m

Obviously, by changing the thickness of the insulation layer and its relative dielectric constant, it is possible to choose a combination where the discharge voltage for a sliding discharge is less than the discharge voltage of the discharge through the air gap, since the discharge voltage for the air gap has an approximately linear dependence on its length, and the discharge voltage for a sliding discharge has a much smaller dependence on the length of the sliding discharge, in particular to the extent of 0.2. Based on this, it is possible to provide conditions under which the discharge will occur along the surface of the insulation layer along the screen, and not directly to an elongated conductor or an element of electrical equipment or a power line on which the screen is mounted.

According to another embodiment of the utility model shown in FIG. 3, the screen further comprises several intermediate electrodes 9 mounted on top of the insulation layer 2, and, as you can see, the length of the discharge gap along the surface of the insulation layer between the intermediate electrode closest to the first main electrode and the first main electrode is less than the length of the discharge gap along the surface of the insulation layer between the first main electrode and the elongated conductor. In this case, the discharge voltage of the sliding discharge along the surface of the insulation layer between the first main electrode and the intermediate electrode should preferably be less than the discharge voltage of the air discharge between the first main electrode and the elongated conductor so that the lightning overvoltage discharge passes over the surface of the insulation layer, and not directly through air gap.

A discharge from one of the intermediate electrodes (including the closest or farthest from the first main electrode) to an elongated conductor or any element connected to it can also occur through the air gap, however, for the purposes of this utility model, surface discharge is preferable. At the same time, it must be understood that the discharges between the intermediate electrodes, as well as between the intermediate and main electrodes, as well as between the intermediate electrode and the elongated conductor, do not have to be surface, they can pass, including, at a certain distance from the layer surface isolation, i.e. in the air. In FIG. 3 it is shown that a combination of types of discharges can be observed, that is, between the intermediate electrode and the first main electrode 4 and between the intermediate electrodes 9 themselves, discharges 10 occur at a certain distance from the surface, and between the intermediate electrode closest to the fastening means 7 and the elongated conductor 2 discharge 11 is observed, passing along the surface of the insulation layer 2.

As shown in FIG. 4, the intermediate electrodes 12 can be installed on top of the insulation layer 2 with a slight deviation from the layer 2. In this case, discharge chambers are made between the intermediate electrodes 12, for example, by inserting the ends of the electrodes 12 into cups 14 made of a dielectric and containing a bottom and side walls, forming discharge chambers, the exits from the discharge chambers being preferably opposite the bottoms. Since the dielectric cups 14 are attached to the insulation layer 2 by their bottom parts, the discharges 13 occurring in the discharge chambers inside the dielectric cups 14 between the ends of the intermediate electrodes 12 protruding into the discharge chambers exit the discharge chambers away from the elongated conductor 1 and, preferably, away from the elements with which the conductor 1 is connected. At the same time, the outputs from one or more discharge chambers can be directed to the conductor or the elements connected to it.

Between the intermediate electrodes 12 and the first main electrode 4 and the second main electrode 8, discharge chambers can also be formed, for example, also using dielectric glasses. The main electrodes can protrude into the discharge chambers of the dielectric cups on their own or have taps that can be designed to create, as one of the electrodes, the discharge gaps in the discharge chambers that are separated from the main electrodes at some distances. In FIG. 4 it is shown that the second main electrode 8 has a galvanic connection with the conductor 1, however, in some embodiments, such a connection may not be provided and overvoltage discharge from the electrode 8 to the conductor 1 or the elements connected to it can occur on the surface of the insulation layer 2 or directly, through the air gap.

In other embodiments, the implementation of at least one intermediate electrode may be installed at least partially in the insulation layer, and if the first main electrode is also installed at least partially in the insulation layer, then between the intermediate electrode and the first main electrode a discharge chamber may be formed that extends to the surface of the insulation layer. If the screen contains a second main electrode installed at least partially in the insulation layer to provide electrical contact with the elongated conductor, a discharge chamber can also be formed between the intermediate electrode and the second main electrode, which extends to the surface of the insulation layer. When at least two intermediate electrodes are installed at least partially in the insulation layer on the screen, discharge chambers can also be formed between adjacent intermediate electrodes that extend to the surface of the insulation layer. In such cases, discharge chambers are formed in the insulation layer itself, and electrodes protrude into them, forming discharge gaps between them. The outputs of such discharge chambers are usually openings connecting the discharge chambers and the surface of the insulation layer.

In FIG. 5 shows a power line comprising supports 18 with insulators 15, at least one electrically conductive wire 19 connected to the insulators 15 by means of fasteners, and two shields 20 for leveling the electric field in the vicinity of the insulator 15, which is an element power lines (can also be used for other electrical equipment). The screens 20 are made according to one of the above options and due to this also provide protection for the power line from lightning surges. In some embodiments, one shield or more than two screens may be installed for one insulator or other element of a power line or electrical equipment.

When a lightning discharge occurs on the wire 19 through the fastening devices, the overvoltage falls on the lower terminal 17 of the insulator 15. On the terminal 17 using the fastening unit 7, a screen 20 is installed, made using an elongated conductor with an insulation layer applied over it, on top of which the first main electrode 4 is installed. Since the elongated shield conductor and the first main electrode are separated by an insulation layer, and the elongated conductor has the potential of the terminal of the insulator on which it is installed, between the conductor and the first main electrode is observed overvoltage of a lightning discharge, which, in case of exceeding the breakdown voltage, causes a sliding discharge 6 on the surface of the insulation layer. Due to the sliding discharge, the potential of the main electrode 4 of the lower screen becomes close to the potential of the terminal 17 and, accordingly, the wire 19.

Due to the fact that the potential difference between the first main electrodes 4 of the upper and lower shields 20 installed on the terminals 16 and 17 of the insulator 15, respectively, is now close to a lightning overvoltage, an electric air discharge 5 occurs between the electrodes 4. In some embodiments, the electrodes 4 can be interconnected by a conductor or by using additional electrodes.

Further, since there is now also a potential difference close to overvoltage between the first main electrode 4 and the conductor of the upper screen, a sliding discharge 6 also occurs on the surface of the insulation layer of the upper screen 20, falling on the mounting unit 7 and the upper terminal 16 of the insulator 15 having a connection with a grounded power pole. Due to the fact that the development of discharges and the transfer of the overvoltage potential of a lightning discharge occurs rather quickly, all of these discharges can exist simultaneously, so that the charge received from lightning goes into the ground. When the voltage of the industrial frequency passes through zero, the arc goes out, and the power line restores its functionality, and the screens are ready to discharge the next lightning overvoltage discharge to the ground.

The screen is mounted on the insulator using the fastening means, which can be part of the screen or be an element placed on the terminal. To ensure the operability of this design, it is desirable to ensure that the discharge voltage of the sliding discharge along the surface of the insulation layer between the first main electrode and the elongated conductor and / or fastening means is less than the discharge voltage of the discharge through the air gap between the first main electrode and the elongated conductor and / or fastening means and / or an insulator.

One of the characteristics through which it is possible to determine the necessary mechanical properties of the screen (in particular, an elongated conductor and / or insulation layer) is the bending stiffness. It can be determined, for example, in accordance with the method for which FIGS. 6 and 7 are shown. According to this method, a part of the screen 20 in an unbent rectilinear form (for example, an elongated conductor with insulation) or a blank for manufacturing a screen in a straight form on two bases 21, spaced from each other at a distance L having, for example, from 10 to 20 thicknesses d of the screen (for example, the thicknesses of an elongated conductor together with insulation), i.e. shown in FIG. 6 and 7, the preferred embodiment, for example, L = 20d (due to the fact that the screen most often has a circular cross section, the thickness d may correspond to the diameter of the screen, measured, for example, on the outer surface of the insulation layer).

Further, in a plane located approximately in the middle (preferably strictly in the middle) between the two bases 21 on which the screen 20 is laid, a deformer 25 is applied to the screen 20 from above, with the help of which a force F is transmitted to the screen 20, aimed at deflection h of the screen 20 down (in this case, the direction is determined in accordance with the measurement scheme in Fig. 6 and 7, and not as in operation). As a result of measuring the magnitude of the force F and deflection (bending) h, it is possible to determine the coefficient of bending stiffness k = F / h, where F is the force applied to the dielectric element, and h is the magnitude of the deflection of the dielectric element.

In an advantageous embodiment, it is desirable to measure the deflection value h of the dielectric element in the lower part 24 of the screen 20 below the point of application of force F, because in the upper part 23 of the screen 20, in the place where the force F is directly applied by the deformer 25, deformation of the screen 20 (for example, the insulation layer) may occur, not related to its deflection, in the case when the screen (in particular, the layer insulation) is made using deformable (for example, elastic or soft) materials, while in the lower part 24 of the screen 20 under the place of application of force F, such deformation is not observed, because no force is applied to it and the movement of the surface of the lower part 24 of the screen under the site of application of force P occurs only due to the deflection of the screen 20.

Due to the possibility of deformation of the screen 20, not related to bending, in the case when the screen is made using deformable (for example, elastic or soft) materials, not only by the deformer 25, but also by the bases 21, to prevent deformation of the lower surface of the screen 20 by the bases 21, which may lead to a distortion of the deflection value h, between the screen 20 and the bases 21, rigid gaskets 22 may be located. The gaskets 22 may be flat or in the form of grooves. The gaskets 22 make it possible to distribute the deforming force from the bases 21 to the large length of the screen 20 and, thereby, reduce the distortion of the measured value of the deflection of the screen 20. The gaskets 22 can preferably freely change their angular position relative to the bases 21, in some cases, the gaskets 22 and the bases 21 can have a swivel joint. It is believed that the gaskets 22, as well as the base 21, are made of weakly deformable material (for example, with respect to the dielectric element).

In the event that irreversible deformation occurs when the screen is exposed (for example, the screen breaks or cracks), then we can assume that the screen is fragile, not flexible and / or its bending stiffness coefficient without breaking the material is obviously large and the screen will not be arbitrary change its shape (without destruction).

In a preferred embodiment, to prevent changing the shape of the screen, its minimum bending stiffness (bending stiffness coefficient) can have a value of at least 1 N / m, 10 N / m, 25 N / m, 50 N / m, 75 N / m, 100 N / m, 200 N / m, 300 N / m, 400 N / m, 500 N / m or 1000 N / m (depending on the materials used in the manufacture of the screen, the shape and size of the screen).

In the present description, the words “has,” “comprises,” “includes,” and the like. used to indicate the presence of indicated characteristics, elements, components of actions, values, or the like. and do not prevent the possibility of the presence or addition of one or more other features, elements, components, actions, values, etc.

The options and modifications of the arrester according to the utility model and insulators-dischargers constructed using such arrester considered in this description are given only to explain their design and operating principles. Specialists in the art should understand that deviations from the above examples of execution are possible, which are also covered by the formula of the utility model.

Claims (15)

1. The screen for leveling the electric field near the element of electrical equipment or power lines, made with the possibility of mechanical fastening on the specified or adjacent element of electrical equipment or power lines and containing an elongated conductor, made with the possibility of electrical contact with the specified or neighboring element of electrical equipment or power lines and at least partially round the specified element of electrical equipment or the power transmission line, characterized in that the shield comprises an insulation layer at least partially covering said elongated conductor and at least a first main electrode, mounted on top of the insulation layer and / or at least partly in the layer of insulation. 2. The screen according to claim 1, characterized in that it is capable of bending around an element of electrical equipment or a power line with an insulating body within an angle of up to 30, 60, 90, 120, 150, 180, 210, 240, 270, 300, 330 or 360 degrees inclusive. 3. The screen according to claim 1, characterized in that the discharge voltage of the sliding discharge over the surface of the insulation layer between the first main electrode and the elongated conductor is less than the discharge voltage of the discharge through the air gap between the first main electrode and the elongated conductor. 4. The screen according to claim 1, characterized in that it contains a second main electrode installed to provide electrical contact with the elongated conductor, and the discharge voltage of the sliding discharge along the surface of the insulation layer between the first main electrode and the elongated conductor or the second main electrode is less than the discharge voltage of the air discharge between the first main electrode and the elongated conductor. 5. The screen according to claim 1, characterized in that it contains at least one intermediate electrode mounted on top of the insulation layer, the length of the discharge gap along the surface of the insulation layer between the intermediate electrode and the first main electrode being less than the length of the discharge gap along the surface of the insulation layer between the first main electrode and the elongated conductor. 6. The screen according to claim 5, characterized in that the discharge voltage of the sliding discharge along the surface of the insulator layer between the first main electrode and the intermediate electrode is less than the discharge voltage of the air discharge between the first main electrode and the elongated conductor. 7. The screen according to claim 5, characterized in that it comprises a discharge chamber between the intermediate electrode and the first main electrode. 8. The screen according to claim 5, characterized in that it contains at least two intermediate electrodes, as well as discharge chambers between the intermediate electrodes. 9. The screen according to claim 5, characterized in that it comprises a second main electrode installed to provide electrical contact with the elongated conductor, as well as a discharge chamber between the intermediate electrode and the second main electrode. 10. The screen according to claim 1, characterized in that it comprises at least one intermediate electrode mounted at least partially in the insulation layer, the first main electrode being installed at least partially in the insulation layer, between an intermediate electrode and a first main electrode are equipped with a discharge chamber that extends to the surface of the insulation layer. 11. The screen according to p. 1, characterized in that it contains at least two intermediate electrodes installed at least partially in the insulation layer, and between adjacent intermediate electrodes are made discharge chambers that extend to the surface of the insulation layer. 12. The screen according to p. 1, characterized in that it contains at least one intermediate electrode installed at least partially in the insulation layer, and a second main electrode installed at least partially in the insulation layer with the provision electrical contact with an elongated conductor, and between the intermediate electrode and the second main electrode, a discharge chamber is formed that extends to the surface of the insulation layer. 13. The screen according to claim 1, characterized in that it comprises means for attaching an elongated conductor to an element of electrical equipment or a power line. 14. The screen according to claim 13, characterized in that the fastening means are made to provide an electrical connection to the elongated conductor with an element of electrical equipment or a power line. 15. The screen according to claim 1, characterized in that the bending stiffness coefficient of the screen is at least 1 N / m, 10 N / m, 25 N / m, 50 N / m, 75 N / m, 100 N / m, 200 N / m, 300 N / m, 400 N / m, 500 N / m or 1000 N / m.

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