RU189816U1 - DISPLAY INDICATOR AND / OR OVERRULATION OF AN INSULATOR WITH A DISCHARGE CAMERA - Google Patents

Abstract

An indicator of overlap and breakdown of an insulator is presented, which includes a fastening element, a signal element, a destructible element and an arc-receiving element, the destructible element including a discharge chamber having dielectric walls and provided with electrodes connected to the fastening element and an arc-receiving element, and mechanically connecting the signal element and fastening element. The fastening element is a bracket. Thanks to the utility model, it is possible to provide a durable, reliable and easy-to-maintain design of the insulator overlap indicator.

Description

The technical field to which the utility model

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

The level of technology

One of the problems arising from the operation of power lines is the detection of an overlapped insulator. When overlapping, the insulator most often remains operational, however, an electrical discharge can damage the insulator, as a result of which the insulator can break through. Also, the overlap can be initiated by the breakdown of the insulator. In this case, the isolator fails and the line is disconnected until the insulator is replaced with a working one.

From the patent RU2609823 known optical indicator that displays the status of a string of insulators on the power line. The principle of the indicator is that it is connected in parallel with an insulator or a string of insulators. In the case when the insulation of the insulators has the required high value, the voltage in the transmission line is applied to the optical insulator and it emits visible light.

However, when the insulators are closed, a much 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 insulator overlap.

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

Secondly, the voltage drop on the sections of the insulator may be due not to a defect in the insulator, but to leakage of current across the surface of the insulator as a result of its pollution or moistening, which is the normal operating mode for the insulator.

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

Fourth, the described optical indicator has a limited service 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 on the state of the isolation of an insulator, it is necessary to periodically replace such optical indicators or radiating elements in them.

Disclosure of utility model

The objective of this utility model is to develop an indicator for the breakdown and / or overlap of an insulator of a transmission line, which has eliminated the above disadvantages.

The task of the utility model is solved with the help of an indicator of breakdown and / or overlap of the insulator, having a fastening element, a signal element, a destructible element and an arc-receiving element. The destructible element contains a discharge chamber, having dielectric walls and provided with electrodes connected to the fastening element and the arc-receiving element, and mechanically connects the signal element and the fastening element. The fastening element is a bracket.

The fastening element in the preferred embodiment is made with the possibility of installation on an insulator and / or electrical installation element, on which or near which an insulator is installed. The signal element can have a flat shape, and can also have dimensions from 40 to 1000 mm or from 40 to 400 mm or from 60 to 300 mm or from 80 to 250 mm. The discharge chamber of the destructible element can be sealed. The internal cavity of the discharge chamber can be filled with gas (for example, air) and / or a liquid and / or solid (for example, dielectric) material. The internal cavity of the discharge chamber may contain a small cross-section conductor connecting the electrodes of the discharge chamber. The signal and discharge elements can be made as a single part. Arc receiver element in some embodiments can be combined with a signal element. Arc receiving element can be made with the possibility of taking a current punched insulator with an insulating body through the spark gap or by means of a conductor (for example, wire).

The technical result of this utility model is to provide at the same time durable, reliable in operation and user-friendly maintenance of the insulator overlap indicator design. This technical result is achieved by using a discharge chamber indicator in a destructible element, which provides mechanical strength and reliability of the destructible element, and by connecting the destructible element with a signal element, the indicator is easy to maintain, in particular, replacing the destructible element with the signal element. Ease of maintenance of the indicator is also provided by the bracket.

Brief Description of the Drawings

The figure shows the indicator overlap of the insulator in the section.

Implementation of the utility model

Further, the utility model is described with reference to the accompanying figure, which depicts one of the possible options for implementing the utility model. The following description and drawing 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 nature of the utility model and possible options for its implementation, which are not limited to those shown in the figure and in the description. The utility model is further described in relation to the suspension polymer insulator, but is not limited to this type and can be used with respect to any insulators (including supporting, non-polymer, etc.), where it can be applied.

The indicator of breakdown and / or overlap of the isolator, proposed in the figure, proposed in accordance with the present utility model, contains a fastening element 1, a signal element 2, a breakable element 3 and an arc-receiving element 4. Destructive element 3 contains a discharge chamber 5, having dielectric walls and provided with electrodes 6 and 7 connected to arcuate-receiving element 4 and fastening element 1, respectively. In the variant of the indicator shown in the figure, the arc-receiving element 4 is structurally connected to the electrode 6 of the arc-discharge chamber by performing them as a single part, but in other embodiments of the utility model, they can be performed separately and then connected electrically and mechanically to each other. In the figure, the destructible element 3 mechanically connects the signal element 2 and the fastening element 1.

The fastening element 1 in the embodiment shown in the figure is a metal bracket that is provided with a clamp 10 for fastening on the insulator 8, for example, on the terminator 9 of the insulator 8, or on an electrical installation element, for example, on the neck of the pestle of the earring to which the insulator is attached, or on electrical installation, near which an insulator is installed. In some cases, the fasteners can be made in the form of other structural products that provide fastening simultaneously on the insulator and on the electrical installation element to provide a more durable mounting and / or reliable electrical contact of the indicator. The collar, as one of the fastener assembly options, provides a fairly simple, easy to maintain and reliable attachment of the bracket and indicator as a whole.

The bracket is a structure that provides the ability to locate the indicator signal element not on the insulator, but to the side of it due to the fact that the bracket itself is attached to the insulator (and / or to the electrical installation element), and the breakable and signal elements and bracket are attached to the bracket necessary to keep these elements and the indicator as a whole away from the insulator.

The fastening element performs both the function of mechanically attaching the indicator and the electrically conductive function from the insulator and / or electrical installation to the indicator (destructible element). The advantage of using the bracket is that the indicator (its destructible and signal elements) is installed near the isolator, that is, away from it at a short distance from the isolator or even close to the end of the signal element or arc-receiving element to the insulator, if necessary to ensure the detection of breakdown of the isolator . This provides the convenience of servicing the indicator at the same time as the convenience of detecting the activated indicator, since the indicator is at some distance from the isolator.

The signal element 2 may have a flat shape. In the figure, the indicator is shown in section and the plane of the signal element is perpendicular to the plane of the drawing. To ensure the visibility of the indicator, the signal element can have dimensions from 40 to 1000 mm, for example, from 40 to 400 mm or from 60 to 300 mm or from 80 to 250 mm. The signal element may have a prominent color: red, yellow, orange or others, for example, black, gray, white, etc. Such dimensions and colors of the signal element allow the naked eye from the ground to easily determine its presence or absence on the insulator.

The signal element can be made of a dielectric, for example, silicone, or of metal - in the latter version it can also serve as an arc-receiving element, that is, at the same time being a signal element and an arc-receiving element. This provides additional indicator reliability and simplicity of its design. At the same time, the implementation of the signal element from a dielectric, especially elastic, such as silicone, ensures the safety of objects located below when the signal element falls.

Destructible element 3 contains an arc-discharge chamber 5, preferably made using a dielectric material, within which an electrical discharge occurs between the electrodes 6 and 7 when the insulator is closed by a power electric arc. Due to the expansion of gases, the arc-discharge chamber and the destroyed element as a whole are destroyed, and the signal element is separated from the fastening element and the indicator as a whole — it falls to the ground. The signal element 2 and the destructible element 3 can be made as a single part, as shown in the figure - this simplifies the design of the indicator, which further increases its strength, reliability and ease of maintenance. Also, the signal element and the element to be destroyed can be made separately and then mechanically connected to each other.

The discharge chamber of the destructible element can be airtight or have a connection with the outside air. In the case of a sealed chamber, it must be filled with gas (for example, air) and / or a liquid and / or solid (for example, dielectric) material to ensure the destructibility of the destroyed element by heating and / or releasing and / or expanding gases or other substances when exposed bit arc inside the chamber.

An unpressurized chamber communicating with outside air must also be filled with gas (for example, air) and / or liquid and / or solid (for example, dielectric) material to ensure destructibleness of the element to be destroyed. In the simplest embodiment, a leaky chamber may contain air trapped in the chamber from the surrounding space. At the same time, it is necessary to take into account that the connection of the unpressurized chamber with the outside air (ambient space) should provide such resistance to the exit of heating and / or evolved and / or expanding gases or other substances, at which the internal pressure in the discharge chamber rises to a value sufficient for destruction of the discharge chamber and the destroyed element.

To ensure reliable operation of the indicator, the electrodes 6 and 7 of the arc-discharge chamber can be electrically interconnected by a conductor with high resistance to the arc current placed inside the chamber, for example, thin wire (i.e., a small cross-section conductor) or a substance (gas, liquid or solid) having electrical conductivity sufficient to equalize the electric potential between the chamber electrodes, but not sufficient to ensure the passage of the arc current (short circuit current). When electrodes produce a high potential difference during the breakdown and / or overlapping of an insulator, a small cross section conductor melts or burns due to the flow of strong current and then the arc begins to discharge.

The arc receiver element 4 is preferably metallic and in some embodiments may be combined with the signal element 2. In some embodiments, the arc receiver element may be configured to receive a punctured insulator current from the insulating body through a spark gap or by means of a conductor (for example, wire).

The location of the arc-receiving element of the indicator in relation to the insulator must be such that the field strength on the arc-receiving element is higher than on the terminator with a screen (or without a screen) on or near which the indicator is fixed. Advantageously, the arc-receiving element of the indicator should be located closer to the opposite end of the insulator or another electrical installation element that has the same potential as the opposite end of the insulator than the end with screen (or without screen) on which the indicator is fixed on the figure above. In particular, to ensure reliable operation of the indicator, the attachment element and the arc-receiving element are preferably located on opposite sides of the indicator.

Since the electric field strength at the arc-receiving element is determined not only by its location in space, but also by the shape of the arc-receiving element itself, for example, the radii of curvature of its end, in some cases, the arc-receiving element can be installed at the same or even somewhat greater distance from the opposite terminator isolator than a terminator with a screen (or without a screen), on which or near which the indicator is fixed. The field strength at the arc-receiving element is determined at the design stage of the indicator and insulator with an indicator by the calculation method.

The indicator allows to determine the isolator blocked by the electric arc by the absence of a signal element on the indicator.

The overlap of insulators can occur for the following reasons: a thunderstorm discharge, initiating a power arc; due to heavy pollution; due to the intense wet snow that completely encircles the insulator; due to extraneous exposure, for example, because of birds or foreign objects brought in by birds or wind (also, in world practice, there are cases of overlapping on the web covered with dew); due to the breakdown of the insulator. Thus, the absence of a signal element on the indicator indicates only the fact of overlap. The reason for the overlap can be determined by visual inspection of the insulator and analysis of weather conditions.

If the overlap occurred due to breakdown of the insulator, then such an insulator should be removed and replaced with a new one. In other cases, it is not necessary to dismantle the isolator. In case of overlap due to contamination, the insulator should be cleaned in accordance with the instruction manual of the insulator. The triggered indicator must be replaced with a new one.

Thus, the indicator of breakdown and / or overlap of the insulator can work both from the overlap and from the breakdown of the insulator and show both the overlap and the breakdown. Breakdown of an insulator does not always lead to overlap of the insulator, but in some situations it can lead to this. That is, as a result of some breakdowns, an overlap of the insulator can occur, and in such cases the indicator will simultaneously show both a breakdown and an overlap of the insulator.

Indicators can be used for various types of insulators, including supporting, supporting, hanging, fixing, tension polymer, glass and other types of insulators, as well as chains of insulators or insulating suspensions.

The embodiments presented in the accompanying figure and described in detail in the description 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, defined by the subsequent utility model formula. The described options can be combined and combined in any combination ensuring the implementation of the principle of action, the ability to visually determine the overlap of the insulator, including at a considerable distance from it, and the achievement of the technical result consisting in providing a durable indicator of the insulator overlap. As a result, combinations of individual options can be achieved additional technical results.

Claims (10)

1. Indicator breakdown and / or overlap of the insulator, which includes a fastening element, a signal element, a destructible element and an arc-receiving element, moreover, the destructible element includes a discharge chamber having dielectric walls and provided with electrodes connected to the fastening element and an arc-receiving element, and mechanically connects the signal element and the fastening element, and the fastening element is a bracket. 2. Indicator according to claim 1, characterized in that the fastening element is adapted to be mounted on an insulator and / or an electrical installation element on which or near which an insulator is mounted. 3. The indicator under item 1, characterized in that the signal element has a flat shape. 4. The indicator according to claim 1, characterized in that the signal element has dimensions from 40 to 1000 mm, or from 40 to 400 mm, or from 60 to 300 mm, or from 80 to 250 mm. 5. The indicator under item 1, characterized in that the discharge chamber of the destroyed element is sealed. 6. The indicator under item 1, characterized in that the internal cavity of the discharge chamber is filled with gas and / or liquid and / or solid material. 7. The indicator under item 1, characterized in that the internal cavity of the discharge chamber contains a conductor of small cross section connecting the electrodes of the discharge chamber. 8. The indicator under item 1, characterized in that the signal element and the discharge elements are made in the form of a single part. 9. The indicator under item 1, characterized in that the arc-receiving element is combined with a signal element. 10. The indicator under item 1, characterized in that the arc-receiving element is made with the possibility of accepting a current punched insulator with an insulating body through the spark gap or by means of a conductor.

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