RU138350U1 - LINEAR CONTACT ASSEMBLY FOR HIGH VOLTAGE DISCONNECTOR (OPTIONS), ARC DEVICE FOR THIS DISCONNECTOR AND HIGH VOLTAGE DISCONNECTOR (OPTIONS) - Google Patents

Abstract

1. A linear contact node for a high voltage disconnector, which includes two support insulators mounted on a support base, on the first of which the contact lips of the conductive bus are fixed, and on the second of which the conductive bus is fixed with a rotary mounted contact knife for interacting with the contact lips on the first support insulator, the contact knife is rotatable in a vertical plane from the first position of placement in the contact jaws on the first support insulator in the position of placement in the contact jaws of the grounding bus, the contact knife is connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact knife is connected to the additional insulator at a point located between the axis of rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator, characterized in that it is equipped with an arc suppression device made in the form of a spring fixed to the contact knife, the end of which is one second spring side is designed as a resiliently deformable rod laid along the track of the knife with its outlet end for the length dimension of the knife and resiliently bending up from this contact blade by moving the blade from a first position to a second polozhenie.2. A linear contact node for a high voltage disconnector, which includes a first support insulator mounted on a support base, on the upper free end of which are fixed contact lips of the conductive bus, and a second support insulator, on the top�

Description

The utility model relates to electrical devices, namely to outdoor high voltage disconnectors and is designed to enable and disable energized sections of the electrical circuit of outdoor high voltage lines, not only in the absence of load current, but also in the presence of the latter, as well as grounding of disconnected sections these lines.

The purpose of the disconnectors is to disconnect sections of the circuit that are without load, thereby creating a visible gap on the line. This is necessary to ensure the safety of personnel working on the disconnected site. According to GOST R 52726-2007, the disconnector is a contact switching device that provides in the disconnected position an insulating gap that meets the standardized requirements. The disconnector is able to open and close the circuit with a small current or a small voltage change at the terminals of each of its poles. It is also capable of conducting currents under normal conditions in the circuit and conducting currents for normalized times under abnormal conditions, such as a short circuit.

Numerous devices are known for switching on and off energized sections of a high voltage electrical circuit. The multiplicity of such devices is due to the variety of specific operating conditions. So are known disconnectors according to RU 79723, H02B 1/00, RU 2035784, H01H 31/00, RU 2150763, H01H 31/00, H02B 1/04, made with a rotary support insulator with a contact knife at the top. These disconnectors are widely used in high voltage transmission systems. But all of them have drawbacks expressed in the low reliability of operation in an outdoor environment, low operational safety and increased labor intensity in maintenance. In particular, the weak point is the design of the contact pairs (pads) of the conductive circuit. The implementation of hooks and / or rings at the ends of the contact knives to improve contact is not an optimal design solution providing sufficiently reliable electrical contact, which can lead to the formation of microarcs when the circuit is closed and, therefore, to increase the resistance of the contact pair. The latter, in turn, increases the likelihood of arcing.

Some of these disadvantages are solved in the known high-voltage disconnector for a three-phase power system, including a frame, which is a horizontally positioned steel rectangular welded structure with three supporting transverse beams, three vertically located supporting insulators, fixedly fixed at the ends of the supporting beams on one side of the frame, on the upper the flange of each of which is fixedly mounted a conductive bus with contact jaws at the end, three vertically located supporting insulators fixed on the ends of the support beams on the other side of the frame, on the upper flange of each of which a conductive busbar is movably fixed at one end in the form of a movable contact knife having a contact pad at the other end, three insulators mounted on rods connected to the vertical movement mechanism, on the upper flanges of each of which a conductive busbar in the form of a movable contact knife is movably fixed by the second point in a position that provides the necessary movement of the contact knife in a vert the ground plane, the ground loop, which is a grounding bus with contact jaws, while the distance between the conductive busbar, fixed on the upper flange of the insulator and the upper edge of the jaws of the grounding bus located below the corresponding insulator, is 440-500 mm, the movable contact knife in neutral position is located between the contact lips of the busbars of the grounding circuit and the contact lips of the tires fixedly mounted on the upper flange of the insulators, conductive busbars located along the top of the insulators and all contact jaws are made of copper-based materials, the outer surfaces of the contact jaws are spring loaded using flat plates of elastic steel, and an additional insulating plate is made below the fastening point on the upper flange of the insulator with a movably fixed conductive bus in the form of a movable contact knife RU 118791, H01H 31/00, publ. 12/27/2012). This decision was made as a prototype for the declared objects.

A particular advantage of the known disconnector in terms of operating safety is the ability to find the contact knife in the neutral position, which is necessary in some cases of installation work. In addition, to close the conductive circuit, the contact knife moves from the bottom up, which reduces the likelihood of an uncontrolled or accidental closure of the conductive circuit. Similarly, it increases the safety of operation and the location of the contact jaws of the grounding circuit, which are located below the neutral position of the contact knife. Accordingly, to close the ground loop, the contact knife moves from top to bottom, which also reduces the possibility of uncontrolled or accidental opening of the loop. These design features can improve operational safety and reduce the complexity of maintenance.

However, in the known solution there are a number of serious drawbacks that lead to operational unreliability of the disconnector, which manifests itself with an increase in the time of its operation. This is due to the fact that any mechanical system of lever type during operation acquires a wear and fatigue error, which generates upward. In the known solution, it is assumed that there is a grounding circuit made in the form of contact jaws of grounding buses. Moreover, these contact jaws are located in the direction of movement of the movable contact knives on the side of three vertically arranged support insulators, motionlessly fixed at the ends of the support beams on the opposite side of the frame. When moving down, the free end of the contact knife along the arc moves down and must fall between the contact jaws, the direction of which in the angle of position is chosen so that the free end of the knife should be recessed in these jaws. But in practice, there may be cases when this free end of the knife may not reach the jaws, or enter them with a blow, or the jaws will be clogged, etc. Some of these options may be the result of incomplete operation of the knife displacement drive due to wear of the ties, and some of these options may be the result of the fact that the dimensions of the contact socket of the contact jaws increase due to wear and do not give full contact. Getting the free end of the knife into the jaw slot during angular movement requires precise adjustment of the positioning system of the movable knife on the insulator: any deviation of the axis of rotation of the knife during operation increases this deviation angle, as a result of which the knife does not fall down in the vertical plane passing through the jaws, but in the plane having an angular deviation from the desired trajectory of movement. This leads to the erosion of the entire system and to its premature wear.

In addition, the base on which the entire disconnector system is mounted is the frame, but on this frame all the insulators are mounted vertically upward and cantilevered. It should be noted that insulators operate under mechanical stress and dynamic load from moving knives and drive. In this case, the extreme insulators on each side of the frame are mounted on cantilever sections of the frame cross members. When the disconnector operates in the mode of dynamic contacts with the knife, these insulators are exposed to their swinging (deviation from the vertical) relative to the cantilever fixing point. These loads are also transferred to the console of the cross members, which are not supported at their free ends. As a result, extremely located insulators, which are the supporting elements for knives, themselves do not have stable support on the frame (in the range of elastic deformations of the material of the cross members). This affects the geometry of the interconnected positioning of all elements in each linear node of the disconnector.

In the known design of the disconnector, the achievement of a predetermined distance between the contact pad of the knife and the jaws on the first support insulator in the mode of separation of the circuit is provided with the vertical position of the second support insulator. In this regard, in order to ensure the specified distance, it is necessary to raise the height of the second support insulator relative to the frame, which is achieved by introducing an insulating plate under the insulator. To obtain a large distance, the thickness of this plate should be large enough. This increases the mass and dimensions of the disconnector.

Also, the known disconnector cannot be used to disconnect energized sections of the electrical circuit of high voltage lines in the presence of a load current, since in this case an arched ignition occurs.

This utility model is aimed at achieving a technical result, which consists in increasing the reliability and safety of disconnecting a circuit under load by introducing an arcing device.

The specified technical result is achieved by the fact that the linear contact node for the high voltage disconnector, which includes two supporting insulators mounted on the support base, on the first of which are mounted contact lips of the conductive bus, and on the second of which is mounted a conductive bus with a rotary mounted contact knife for interacting with contact jaws on the first support insulator, the contact knife is rotatable in a vertical plane from the first position in the contact jaws on the first support insulator to the second position of the ground bus in the contact jaws, the contact knife is connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact knife is connected to the additional insulator at a point located between the axis rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator, is equipped with an arcing device made in the form of a spring fixed to the contact knife the end of the coil of which on one side of the spring is made in the form of an elastically deformable bar laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding upward from this knife when moving the contact knife from the first position to the second position.

The specified technical result is also achieved by the fact that the linear contact node for the high voltage disconnector, which includes mounted on the support base, the first support insulator, on the upper free end of which are fixed the contact lips of the conductive bus, and the second support insulator, on the upper free end of which is fixed conductive bus with a rotary mounted contact knife with a contact pad for interaction with contact jaws on the first support insulator, contact knife vyp it is rotatable in the vertical plane from the position of the contact pad in the contact jaws on the first support insulator to the position of the contact pad in the contact jaws of the ground bus, while the contact knife is equipped with an additional insulator, one end connected to the drive for its rotation in the vertical plane and the other the end with the contact knife at a point located between the axis of rotation of the knife and the location of the contact pad on this knife is equipped with an arcing device, made in the form of a spring fixed to the contact knife, the end of the coil of which on one side of the spring is made in the form of an elastically deformable bar laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding upward from this knife, the contact lips of the grounding bus are fixed on the support base on the side of the placement of the second support insulator and below the level of attachment of this support insulator on this base, the second support insulator and the additional insulator are inclined to the side first supporting insulator. These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The specified technical result is achieved in that in a high voltage disconnector including a frame on which at least two linear contact assemblies are mounted, each of which includes two support insulators mounted on opposite sides of the frame, on the first of which are mounted contact lips of the conductive bus and on the second of which a conductive busbar with a rotary mounted contact knife is fixed for interaction with contact jaws on the first support insulator, the contact knife is flax with the possibility of rotation in the vertical plane from the first position in the contact jaws on the first support insulator to the second position in the contact jaws of the grounding bus, the contact knife is connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact the knife is connected with an additional insulator at a point located between the axis of rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator, each linear contact node is equipped with an arc suppression device made in the form of a spring fixed to the contact knife, the end of the coil of which on one side of the spring is made in the form of an elastically deformable rod laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding up of this knife when moving the contact knife from the first position to the second position.

The specified technical result is achieved in that in a high voltage disconnector including a frame on which at least two linear contact assemblies are mounted, each of which includes two support insulators mounted on opposite sides of the frame, on the first of which are mounted contact lips of the conductive bus and on the second of which a conductive busbar with a rotary mounted contact knife is fixed for interaction with contact jaws on the first support insulator, the contact knife is flax with the possibility of rotation in the vertical plane from the first position in the contact jaws on the first support insulator to the second position in the contact jaws of the grounding bus, the contact knife is connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact the knife is connected with an additional insulator at a point located between the axis of rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator, each linear contact node is equipped with an arc suppression device made in the form of a spring fixed to the contact knife, the end of the coil of which on one side of the spring is made in the form of an elastically deformable rod laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding up of this knife when moving the contact knife from the first position to the second position, while in each linear contact node, the contact lips of the ground bus are attached to the frame on the side placed I second support insulators and below the attachment of the insulator and the second insulator support and additional insulator disposed obliquely towards the first support insulator.

The specified technical result is achieved in that the arc suppression device for the high voltage disconnector is made in the form of a spring fixed to the contact knife, the end of the coil of which on one side of the spring is made in the form of an elastically deformable bar laid along the contact knife with the end of the knife extending beyond the length and sec the possibility of elastic bending upwards from this knife when moving the contact knife from the position of placement in the movable jaws on the support insulator to the position of placement in the contact jaws behind grounding tires.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

In FIG. 1 shows a kinematic diagram of a linear contact node of one phase of a disconnector;

FIG. 2 - shows the position of the elements of the linear contact node of one phase of the disconnector when the circuit is broken;

FIG. 3 - shows the position of the elements of the linear contact node of one phase of the disconnector when shorted to the ground loop;

FIG. 4 - shows the mechanism of the accelerator switch;

FIG. 5 - shows a bar catcher of a spring of an extinguishing device;

FIG. 6 - shows the position of the contact knife in the jaws of the grounding loop;

FIG. 7 is a general view of a three-phase disconnector assembled on a frame.

According to this utility model, the design of an outdoor high voltage disconnector is considered, which is designed to turn on and off energized sections of the electrical circuit of high voltage lines in the absence or presence of a load current, as well as grounding of disconnected sections of these lines. A two-phase or three-phase disconnector (depending on the type of network) includes several linear contact nodes for one phase, made identically and assembled on a common frame (on a common support base made with pads for fixing support insulators) into a switching structure.

Each linear contact node for one phase (Fig. 1 and 2) is placed on the frame 1 and includes a vertically oriented one support insulator 2, on the upper free end of which are fixed contact jaws 3 of the conductive bus 4, and one support insulator 5, on the upper the free end of which is conductive bus 6 with a contact knife 7 with a contact pad 8 for interaction with the contact jaws 3 on the first support insulator 2. Support insulators 2 and 5 are mounted at a distance from each other. In this case, the second support insulator 5, which carries the conductive bus 6, to which the contact knife 7 is rotated (on a horizontal hinge or axis 9), is inclined towards the first support insulator 2. The contact knife 7, which is rotatable relative to the conductive bus 6, is connected with this fixed conductive bus 6 through a copper cable 10.

The contact knife 7 is made to rotate in a vertical plane from the position of its contact pad 8 in the movable jaws 3 to the position of the contact pad 8 in the contact jaws 11 of the ground bus 12. A contact jaws 11 of the ground bus 12 are attached to the frame on the side of the second ( inclined) support insulator 5 and below the level of fastening of the support insulators on the frame. Moreover, the contact knife 7 is equipped with an additional insulator 13, connected with the drive 14 of the rotation (the drive, for example, can be made in the form of a system of levers 15, providing two extreme working position and one neutral) contact knife in a vertical plane and with a contact knife at point A, located between the axis of rotation 9 of this knife on the second support insulator and the location of the contact pad 8 on the knife. The movable contact knife of the linear disconnector assembly has three positions - the position of the ground loop circuit, the neutral position and the circuit position of the conductive circuit. The additional insulator 13 is also inclined towards the first support insulator 2 and, in fact, parallel to the slope of the second support insulator 5. The additional insulator does not pass in the hole of the spar or cross member (beam, channel), which reduces the likelihood of icing of the insulator inside the frame.

In this design, the distance between the conductive busbar 4, fixedly mounted on the upper flange of the first support insulator 2 and the upper edge of the jaws 11 of the grounding bus 12, located below the corresponding second support insulator 5, is not less than 440-500 mm. In this case, to increase the stroke of the contact knife and ensure it in a practically vertical position downward (in the contact mode with the grounding bus), the additional insulator is pivotally connected (hinge 16) to one arm of the lever 17, the other arm of which is fixedly mounted (pos. 18) on the contact a knife. This increases the angle of inclination of the knife, which allows to significantly increase this distance to guaranteed impenetrable under the most adverse climatic conditions.

In general, a linear contact assembly for a high voltage disconnector includes two support insulators mounted on a support base, on the first of which contact conductive bus jaws are fixed, and on the second of which a conductive bus is mounted with a rotary mounted contact knife for interacting with contact jaws on first supporting insulator. The contact knife is rotatable in a vertical plane from the first position in the movable jaws on the first support insulator to the second position in the contact jaws of the grounding bus. In addition, the contact knife is also connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact knife is connected to the additional insulator at a point located between the axis of rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator.

This algorithmic presentation of a typical disconnector circuitry includes both the design of the disconnector with all supporting insulators 2 and 5, which are located vertically (their longitudinal axis is vertical), and the design of the disconnector with one of the supporting insulators 5, inclined towards the other supporting insulator 2 For any of these execution schemes, it is intended to include an arcing device in the circuit (Figs. 2, 3 and 5). This arcing device can be made in the form of a fixed 7 p rifles 20, the end of the coil of which on one side of the spring is made in the form of an elastically deformable rod 21, laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding upward from this knife when moving the contact knife from the first position to the second position. The use of an arc suppression device of this design allows you to disconnect under voltage sections of the electrical circuit of high voltage lines in the presence of a load current (high voltage circuit with an active load). When the contacts between them open, a spark does not run, which contributes to a longer service life of expensive copper contacts. The consumable element is an inexpensive spring of an extinguishing device. The axis of attachment of this spring inside the contact (main) knives is not aligned with the axis of rotation of these knives, which provides the convenience of replacing the spring without the need for technological repair or disassembly of the knives turning assembly. The spring of the extinguishing device and the rod of this spring are made, for example, of spring steel, for example 65G.

The contact jaws on the first support insulator can be spring loaded from flat elastic steel plates. The grounding circuit is made integral with the frame and consists of steel plates, one end of which is welded to the frame, and contact jaws are fixed on the other, similar to the busbar lips of the current-supply circuit with spring-loaded flat elastic steel plates. All contact jaws can be made of copper-based materials (copper parts are made of electrotechnical copper M1 and can be tin-plated - this is preferable, but not necessary), the outer surfaces of the contact jaws are spring-loaded using flat plates made of elastic steel. The exact design of the jaws and their spring-loaded mechanism is not considered in this application.

As an example of execution, the claimed solution proposes that the contact jaws on the support insulator and on the grounding bus are spring-loaded towards each other due to the twisted spring 22 (Fig. 6), the compression force of which is regulated by the stroke of the screw 23 passing inside this spring. In this example, the preloading of the contact jaws 3 or 11 in the on and in the grounded position, respectively, is provided by coil, not flat springs (as in the prototype), the compression force of which can be controlled by the stroke of the screw passing inside the spring. In the prototype, such adjustment is absent.

As supporting insulators, insulators, for example, grades C4-80, can be used. Depending on the magnitude of the voltage, insulators of other brands can be used.

To accelerate turning off or on, each linear contact node is equipped with a spring 24 (Fig. 4), connected at one end with the frame 1, and with the other shoulder with the lever 15 for turning the additional insulator 13 or directly with the latter to accelerate the movement of the contact knife 7 to the off or on position when crossing a dead center. To speed up the shutdown operation (in order to reduce the time the current flows through the spring when the copper contacts are separated), a coil spring is used, which, when turned off, passes through a dead center and, unclenching, quickly leads the main knives down, while the arc-extinguishing spring “shoots”, breaking the chain. In addition to the example of direct use of the spring, you can consider using a telescopic system or a cylinder with a piston in which the movable element is spring-loaded. Such a telescopic system or cylinder with a piston is thus placed between the frame and the arm of the additional insulator or by this insulator itself, in order to ensure that the spring moves through a dead point when the additional insulator is angularly moved from one extreme position to another. For all the considered examples, the spring acts as a spring-type servo amplifier or spring pusher or accelerator.

To capture the firing rod 21 of the spring 20 of the extinguishing device in the upper part of the contact blades 7, catchers 25 are provided in the form of two plates bent in opposite directions. And from the side of the contact jaws on the first support insulator there is a gripping unit 26 of the end of the spring bar of the extinguishing device, consisting of two steel plates bent at an angle and a third steel plate with a U-shaped bend at the end, which is the bed for the end of the spring bar of the extinguishing device. This site ensures that the end of the spring of the arc extinguishing device ends up in the U-shaped bed 27 when the contact blades move upward to the ON position.

The linear node of the disconnector operates as follows (Fig. 2).

To connect the conductive circuit, the lever of the drive lever system is removed. The end of the rod 21 of the spring of the extinguishing device is located in the U-shaped bed 27 of the contact jaws 3. To open the conductive circuit, i.e. bringing the device into an inoperative position in the mode of the load in the circuit using a lever drive moves the link 15 of the mechanism, leading to the rotation of the additional insulator 13. The latter through the lever 17 puts pressure on the contact knife 7 and removes it from the contact jaws 3 on the supporting insulator 2. When the end of the rod 21 of the spring of the extinguishing device remains in the U-shaped bed 27 of the contact jaws 3. As the contact knife 7 moves down, the rod 21 of the spring of the extinguishing device, elastically bending, is separated from the body of the contact about the knife and at the same time the end of the bar slides along the bed until it slips out of the bed. Such an algorithm for switching off or disconnecting a contact knife with contact jaws allows first to remove the main mass contact from the connection, leaving the contact along the bar, and then without forming an arc, to separate the bar from the jaws of the conductive bus 4.

At the moment of exit of the contact pad of the knife from the contact jaws, the spring 24 of the accelerator moves to the dead point and deforms to the maximum and after the transition of the dead point is straightened, giving up the stored energy to either the lever 15 of the additional insulator or directly to the insulator itself. This leads to an abrupt increase in the speed of movement of the contact knife at the exit of the contact jaws 3 of the conductive bus 4. At the moment of contact, under the action of the force of the drive and the spring 24, the end of the rod 21 is forcefully removed from the receiving bed. The contact of the conductive busbars 4 and 6 is open.

The accelerating action of the spring 24 is necessary to reduce the flow time of the load current through the rod of the spring 21, that is, to accelerate the act of opening the circuit. In the future, the speed of the knife is not critical. Therefore, the dead center of the spring 24, when opened, passes almost immediately, and when closed at the very end of the movement.

The system is moved to the connection position of the contact circuit in the reverse order.

This linear contact node for one phase in an amount of two or three (depending on the number of phases in the network) is mounted on frame 1 (Fig. 3). The frame consists of spars 28 with cross members 29 attached to them. The frame is a structure in which the ends 30 of the cross members 29 on each side of the frame are rigidly connected to each other and to the side members or directly to the side members. For example, the frame may be a horizontally positioned steel welded structure (Fig. 7), consisting of side members 28 with cross members 29 attached to them over the side members, the ends 30 of which extend beyond the side members. In this frame, the ends 30 of the cross members 29 are rigidly connected on each side of the frame by longitudinal elements 31 and are supported by jibs 32 connecting the ends 30 of the cross members to the side members 28. In another embodiment, the ends of the cross members 20 of the frame can be rigidly connected on each side to the side members 28 directly with the formation of a frame rectangular in plan (that is, the cross members are not located above the side members, as in the first embodiment, but between the side members). With any design of the frame, the cantilever fastening of the ends of the cross members is excluded, which excludes the possibility of their elastic deformation and vibrations and the transmission of these vibrations to cantilevered supporting insulators. In this case, the supporting insulators, fixed at the edges of the crossbars, maintain the vertical position of their longitudinal axis and, accordingly, the position of the contact jaws with respect to the path of movement of the contact area of the knife. Despite the fact that during operation, the rotation axis of the contact knife may wear out (which will lead to some change in the path of the knife — deviation from the vertical plane), the likelihood of the contact area of the knife not falling into the jaw of the contact jaws is reduced. The frame and all metal parts are made of ordinary steel and then galvanized. It is possible to use other methods of protection, for example dyeing, in particular by powder method or dipping in paint.

In the assembled disconnector structure shown in FIG. 7 for a three-phase version of its execution, vertically oriented three (for a two-phase version of execution - two) support insulators are fixed on the first cross-member, on the upper free end of each of which are fixed contact lips of the conductive bus, and on the second cross-section three are mounted with an inclination towards the first insulators support insulators, on the upper free end of each of which a conductive bus is fixed in the form of a contact knife with a contact pad for interaction with contact jaws on the support zolyatorah the first cross member. The extreme insulators in this scheme of the three-phase disconnector are placed along the edges of the cross-members, and in the variant of the two-phase disconnector, all the insulators are placed on the edges of the cross-members.

Each contact knife is rotatable in a vertical plane from the position of the contact pad in the contact jaws to the position of the contact pad in the contact jaws of the ground bus. Each contact knife is equipped with an additional insulator associated with a rotary drive of the contact knife in the vertical plane and with the contact knife at a point located between the axis of rotation of each knife on the corresponding supporting insulator and the location of the contact pad on the knife. Each additional insulator in this circuit is connected to its contact knife through a two-arm lever rigidly fixed on this knife according to the principle that was previously considered in relation to the design of a separate linear unit.

In the three-phase disconnector design considered as an example, all nodes of each linear switching node have exact positioning relative to each other, since the design of the support frame, on which all nodes are based, structurally excludes the possibility of its elastic deformation, which could affect the position of the axes of the insulators in moment of disconnection or inclusion of switching. This significantly increases the operational reliability and durability of the disconnector. Positive is the disconnection of switching by lowering the contact knife along the path down. But in this case, it is necessary to ensure guaranteed security for personnel, regardless of the fact that the contacts are open. In the disconnector, this is ensured by the distance from the point of contact of the contact pad of the knife in the jaws of the grounding bus to the contact jaws of a vertically oriented support insulator. Theoretically and, as is accepted in practice, this pronounced visibility is achieved already at 200 mm, but it is desirable to have approximately 440-500 mm. This follows from the fact that disconnectors play an important role in wiring diagrams, the reliability of the entire electrical installation depends on the reliability of their work, therefore they have the following requirement: "creating a visible gap in the air, whose electric strength corresponds to the maximum pulse voltage". This directive setting of the requirement implies that for each non-standard use case, including for critical climatic conditions, it is necessary to provide such a visible gap, "whose electric strength corresponds to the maximum impulse voltage". For conditions of high humidity or ice (as an example), the distance should be large, but to obtain a large distance in the solution according to the prototype, it is necessary to greatly increase the dimensions of the disconnector along the length of the linear unit and in height. This is not the best solution. And in the claimed design, the knife in the open circuit position is almost vertically lowered down. With this design, the disconnector becomes compact, and the value of this control distance, guaranteeing "electric strength exceeding the maximum pulse voltage" becomes significantly greater than the practical distance. The specific value of this distance in the claimed design becomes dependent on the length of the contact knife, and not on the dimensions of the disconnector as a whole. To ensure the almost vertical position of the contact knife in the closed position with the ground loop, the support insulator 5 is installed obliquely towards the support insulator 2. This displays the axis of rotation of the contact knife in a position in which the body of the support insulator does not prevent the knife from being vertically lowered. The inclined position of the additional insulator is not determined by the need for the longitudinal axes of this insulator and the supporting insulator 5 to be parallel, but by the fact that it is in this position that the lever coupling of the additional insulator with the contact knife allows you to form the trajectory of this knife without deviations in the vertical plane. This allows you to accurately position the contact area of the knife in the receiving contact jaws of the support insulator 2. Placing one of the support insulators at an angle and placing the grounding jaws on its side made it possible to reduce the dimensions of the disconnector and increased the electrical safety distance with smaller dimensions of the product.

The design of the disconnector, when the contact blades do not move above the top of the supporting insulators during movement, allows you to cover the entire disconnector with a roof of insulating material, mounted on the frame using posts made of insulating material. This can protect birds from electric shock. It is impossible to completely place the disconnector in the box, since one of the requirements for the disconnector is the presence of a "visible air gap when the contacts are disconnected." A variant is possible, according to which it is possible to cover each linear node of the disconnector with separate covers or in each such linear node the contact area of contact knives with contact jaws, and also to close the hinge of contact knives with current-carrying copper buses (plates) from the opposite side from weather. Illustratively, these examples of protective roofs or covers are not shown.

The claimed design provides, as an embodiment, the ability to cover the frame, as well as contact knives, except for contact points, with an insulating organo-silicate composition (such as paint) in order to protect birds from electric shock. This is relevant both as an independent solution, and in conjunction with the supply of a disconnector mounted on a frame with a roof made of insulating material that covers the linear contact nodes located on the frame from above, or with covers that cover the area of contact jaws on the first support insulator and / or zone in each linear contact node swivel the contact knife with a conductive bus, or individually closing each linear contact node.

This utility model is industrially applicable and can be manufactured using the technologies that are used today in the production of high voltage disconnectors.

Claims (21)

1. A linear contact node for a high voltage disconnector, which includes two support insulators mounted on a support base, on the first of which the contact lips of the conductive bus are fixed, and on the second of which the conductive bus is fixed with a rotary mounted contact knife for interacting with the contact lips on the first support insulator, the contact knife is rotatable in a vertical plane from the first position of placement in the contact jaws on the first support insulator in the position of placement in the contact jaws of the grounding bus, the contact knife is connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact knife is connected to the additional insulator at a point located between the axis of rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator, characterized in that it is equipped with an arc suppression device made in the form of a spring fixed to the contact knife, the end of which is one second spring side is designed as a resiliently deformable rod laid along the track of the knife with its outlet end for the length dimension of the knife and resiliently bending up from this contact blade by moving the blade from the first position to the second position. 2. A linear contact node for a high voltage disconnector, including a first support insulator mounted on a support base, on the upper free end of which the contact lips of the conductive bus are fixed, and a second support insulator, on the upper free end of which a conductive bus is mounted with a rotary mounted contact knife with a contact pad for interaction with contact jaws on the first support insulator, the contact knife is rotatable in a vertical plane from the position of the contact pad in the contact jaws on the first support insulator to the position of the contact pad in the contact jaws of the ground bus, while the contact knife is equipped with an additional insulator, one end connected to the drive of its rotation in the vertical plane and the other end with the contact knife at the point located between the axis of rotation of the knife and the location of the contact area on this knife, characterized in that it is equipped with an arcing device made in the form of fixed to the contact the knife of the spring, the end of the coil of which on one side of the spring is made in the form of an elastic deformable bar laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding upward from this knife, the contact lips of the grounding bus are fixed on the support base on the side placing the second reference insulator and below the level of attachment of this reference insulator on this base, the second reference insulator and the additional insulator are inclined toward the first reference insulator. 3. The linear contact node according to claim 2, characterized in that a frame made with pads for fixing the supporting insulators is used as a support base. 4. The linear contact node according to claim 2, characterized in that the additional insulator is connected to the contact knife through a lever rigidly fixed on this knife. 5. The linear contact assembly according to claim 2, characterized in that the contact jaws on the support insulator and at the grounding bus are spring-loaded towards each other due to the twisted spring, the compression force of which is regulated by the stroke of the screw passing inside this spring. 6. The linear contact node according to claim 2, characterized in that to accelerate the turn-off or on, it is equipped with a spring connected at one end to the frame and the other with a turn lever of the additional insulator or directly with the latter to accelerate the movement of the contact knife to the off or on position when crossing a dead center. 7. The linear contact node according to claim 2, characterized in that for catching the bar spring of the extinguishing device, a catcher is mounted in the form of two plates bent in opposite directions in the upper part of the contact knife. 8. The linear contact node according to claim 2, characterized in that on the side of the contact jaws on the first support insulator there is a node for gripping the end of the bar spring of the extinguishing device, consisting of two steel plates bent at an angle and a third steel plate with a U-shaped bend at the end being a bed for the end of the bar spring of the extinguishing device. 9. A high voltage disconnector comprising a frame on which at least two linear contact assemblies are mounted, each of which includes two support insulators mounted on opposite sides of the frame, on the first of which the contact lips of the conductive bus are fixed, and on the second of which a conductive bus with a rotary mounted contact knife is fixed for interaction with contact jaws on the first support insulator, the contact knife is rotatable in a vertical plane from the first position in the contact jaws on the first support insulator to the second position in the contact jaws of the grounding bus, the contact knife is connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact knife is connected to the additional insulator at located between the axis of rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator, characterized in that each linear contact node It is equipped with an extinguishing device made in the form of a spring fixed on a contact knife, the end of the coil of which on one side of the spring is made in the form of an elastically deformable bar laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding upward from this knife when moving contact knife from the first position to the second position. 10. The high voltage disconnector according to claim 9, characterized in that the frame consists of spars with cross members attached to them and is a structure in which the ends of the cross members on each side of the frame are rigidly connected to each other and to the side members or directly to the side members, 11. The high voltage disconnector according to claim 9, characterized in that in each linear contact node, the contact lips of the grounding bus are attached to the frame on the side of the second support insulators and below the level of fastening of this insulator, and the second support insulator and additional insulator are inclined to the side first supporting insulator. 12. The high voltage disconnector according to claim 9, characterized in that the additional insulator is connected to the contact knife through a lever rigidly fixed to this knife. 13. The high voltage disconnector according to claim 9, characterized in that the contact jaws on the support insulator and at the grounding bus are spring-loaded towards each other due to the twisted spring, the compression force of which is regulated by the stroke of the screw passing inside this spring. 14. The high voltage disconnector according to claim 9, characterized in that for accelerating the switching off or on, it is equipped with a spring connected at one end to the frame and the other with a turn lever of the additional insulator or directly with the latter to accelerate the movement of the contact knife to the off or on position when crossing a dead center. 15. The high voltage disconnector according to claim 9, characterized in that for catching the bar spring of the extinguishing device, a catcher is mounted in the form of two plates bent in opposite directions in the upper part of the contact knife. 16. The high voltage disconnector according to claim 9, characterized in that on the side of the contact jaws on the first support insulator there is a node for gripping the end of the bar spring of the extinguishing device, consisting of two steel plates bent at an angle and a third steel plate with a U-shaped bend at the end being a bed for the end of the bar spring of the extinguishing device. 17. The high voltage disconnector according to claim 9, characterized in that it is provided with a roof of insulating material fixed to the frame using columns of insulating material, covering linear contact nodes located on the frame on top, or with covers covering the placement area in each linear contact assembly contact jaws on the first support insulator and / or the hinge area of the contact knife with the conductive bus or individually closing each linear contact node. 18. A high voltage disconnector comprising a frame on which at least two linear contact assemblies are mounted, each of which includes two support insulators mounted on opposite sides of the frame, on the first of which the contact lips of the conductive bus are fixed, and on the second of which a conductive bus with a rotary mounted contact knife is fixed for interaction with contact jaws on the first support insulator, the contact knife is rotatable in a vertical plane and from the first position of placement in the contact jaws on the first support insulator to the second position of placement in the contact jaws of the ground bus, the contact knife is connected to an additional insulator, the other end of which is connected to the drive of its rotation in the vertical plane, while the contact knife is connected to the additional insulator in a point located between the axis of rotation of this knife and the location of the contact of this knife with movable jaws on the first support insulator, characterized in that each linear contact node Abge is suppressed by an arc suppression device made in the form of a spring fixed to the contact knife, the end of the coil of which on one side of the spring is made in the form of an elastically deformable rod laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding upward from this knife when moving contact knife from the first position to the second position, while in each linear contact node contact jaws of the grounding bus are attached to the frame on the side of the second support insulator and bottom e level of fastening of this insulator, and the second supporting insulator and additional insulator are located obliquely in the direction of the first supporting insulator. 19. The high voltage disconnector according to claim 18, characterized in that to accelerate the turn-off or on, it is equipped with a spring connected at one end to the frame and the other with a turn lever of the additional insulator or directly with the latter to accelerate the movement of the contact knife to the off or on position when crossing a dead center. 20. The high voltage disconnector according to claim 18, characterized in that it is provided with a roof of insulating material fixed to the frame with the help of columns of insulating material, covering the linear contact nodes located on the frame on top, or with covers covering the placement area in each linear contact assembly contact jaws on the first support insulator and / or the hinge area of the contact knife with the conductive bus or individually closing each linear contact node. 21. An arc suppression device for a high voltage disconnector, made in the form of a spring fixed to the contact knife, the end of which on one side of the spring is made in the form of an elastically deformable rod laid along the contact knife with the end of the knife extending beyond the length of the knife and with the possibility of elastic folding up from this knife when moving the contact knife from the position of placement in the movable jaws on the support insulator to the position of placement in the contact jaws of the grounding bus.

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