RU231709U1 - High-voltage linear swing type disconnector - Google Patents

Abstract

The utility model relates to the field of equipment for electric power engineering and can be used in the designs of disconnectors installed on high-voltage power transmission lines. The disconnector comprises a frame to which the first and second fixed insulators are connected in one phase by their first ends, and between them a movable insulator is located, pivotally connected by its first end to the frame, a corresponding main fixed contact is secured to the second end of each fixed insulator, and the second end of the movable insulator is connected to the main movable contact. In this case, the main movable contact has two elongated parts that are pivotally connected to each other by one of their ends using the first axis, wherein the other end of the first part of the main movable contact is pivotally connected by the second axis to the second end of the first fixed insulator, the second part of the main movable contact is pivotally connected by the third axis to the second end of the movable insulator, and the other end of the second part of the main movable contact is designed with the possibility of interaction with the main fixed contact of the second fixed insulator. In the places of the hinged connection of the first part of the main movable contact with the second end of the first fixed insulator, the second part of the main movable contact with the second end of the movable insulator, as well as both parts of the main movable contact with each other on the corresponding axis, a corresponding spring is installed. The use of the utility model allows to simplify the design of the disconnector, as well as to increase the reliability of its operation and service life in any climatic conditions. 1 c.p. fils, 6 ill.

Description

The utility model relates to electrical apparatus engineering and electric power engineering, namely to disconnectors installed on power transmission lines.

A linear disconnector of a swinging type is known from the prior art, selected as the closest solution. The known disconnector contains two fixed insulators in one phase and one movable insulator located on the axis of rotation with a dynamic part of the main contact fixed to its upper flange, electrically connected to the end of a flexible connection, the opposite end of which, together with the contact terminal, is fixed to the upper flange of the fixed insulator. On the upper flange of the other fixed insulator, the static part of the main contact is also fixed together with the contact terminal. The static part of the main contact is made in the form of a plate, and its dynamic part is made in the form of a pair of spring-loaded lamellas, forming a slit-like receiving zone for the said plate (see Patent RU 43101, published on 27.12.2004).

The disadvantage of the closest solution is the low reliability of its operation due to the presence of a flexible connection in the main contact, which can break during operation, including when accidentally exposed to external factors. In addition, when moisture gets into the gap between the lamellas at low outside temperatures (especially in climate zones with frequent transitions through zero) and when operating the disconnector in such conditions, the lamellas break, which significantly reduces the reliability and service life of the disconnector.

The technical problem solved by the proposed utility model is the creation of a swinging disconnector with a simple and reliable design.

The technical result of the utility model is to increase the reliability of the disconnector operation and its service life in any climatic conditions by eliminating the use of flexible and easily damaged elements during operation as the main moving contact.

The technical result of the utility model is achieved due to the fact that the high-voltage disconnector contains a frame, with which the first and second fixed insulators are connected in one phase by their first ends, and between them there is a movable insulator, pivotally connected by its first end to the frame, on the second end of each fixed insulator a corresponding main fixed contact is fixed, and the second end of the movable insulator is connected to the main movable contact, the main movable contact has two elongated parts, which are pivotally connected to each other by one of their ends, wherein the other end of the first part of the main movable contact is pivotally connected to the second end of the first fixed insulator, the second part of the main movable contact is pivotally connected to the second end of the movable insulator, and the other end of the second part of the main movable contact is designed with the possibility of interaction with the main fixed contact of the second fixed insulator.

In addition, the second part of the movable contact can be pivotally connected to the second end of the movable insulator using a U-shaped connecting element.

In addition, springs can be installed in the places of the hinged connection of the first part of the main movable contact with the second end of the first fixed insulator, the second part of the main movable contact with the second end of the movable insulator, as well as both parts of the main movable contact with each other.

The utility model is explained by drawings, where Fig. 1 shows the proposed disconnector in the on position; Fig. 2 - the same, in the off position; Fig. 3 - the same, in the off and grounded position; Fig. 4 shows the disconnector drive; Fig. 5 shows view A in Fig. 4; Fig. 6 shows the draft catcher.

The proposed high-voltage linear disconnector of a swinging type contains a frame 1, which is a welded structure made of profile elements (a side member and crossbars connected to it, not shown). The welded structure of the frame 1 increases the reliability of the disconnector operation as a whole by providing rigid connections with each other, eliminating any possible relative movement of the elements of the frame 1 relative to each other during installation, operation and dismantling of the disconnector.

Insulators 2 and 3 (the first fixed insulator 2 and the second fixed insulator 3), which are fixed relative to the frame, are connected to the frame 1 of the disconnector in one of its phases. Moreover, fixed insulators 2 and 3 are rigidly fixed by one of their ends (the first ends, flanges) on the frame 1. Fastening of insulators 2 and 3 to the frame 1 can be carried out using a threaded connection, or using any other connection that ensures rigid and fixed installation of insulators 2 and 3 on the frame 1 of the disconnector.

At the second ends of fixed insulators 2 and 3, the main fixed contacts 4, 5 with contact terminals 6, 7 are rigidly fixed.

A movable insulator 8 is pivotally connected to the frame 1, located between the fixed insulators 2 and 3 in one of its phases. In this case, the movable insulator 8 is pivotally connected to the frame 1 by one (first) end by means of a shaft 9, which is pivotally connected to the frame 1 through a rotary lever 10. Another design implementation of the pivot connection of the first end of the movable insulator 8 with the frame 1 is also possible, ensuring rotation (movement, swinging) of the movable insulator 8 relative to the frame 1.

The number of phases of the disconnector with fixed insulators 2, 3 and movable insulator 8 can be any from one or more.

The other (second) end of the movable insulator 8 is pivotally connected (linked) to the main movable contact 11 (movable blade 11). The movable insulator 8 can be pivotally connected by its second end to the main contact 11 through an intermediate connecting element 12 made in the form of a bent plate having a U-shaped profile (forming a connecting fork). In this case, the connecting element 12 is connected to the contact 11 by means of a rotation axis 13. Such a connection allows for reliable gripping of the contact 11, excluding a break in the connection of the movable insulator 8 with the main contact 11, increasing the reliability of the disconnector operation and its service life in any climatic conditions.

The main movable contact 11 has two elongated parts 14 and 15, which are hinged to each other by one of their ends, for example, by means of a rotation axis 16. Thus, the movable contact 11 is made of a "scissor" type, which has increased reliability of operation and has a long service life due to the elimination of involuntary rupture of connections.

The other end of the first part 14 of the main movable contact 11 is pivotally connected (joined) to the second end of the first fixed insulator 2 by means of the axis of rotation 17 with the possibility of rotation relative to the axis 17 and with the possibility of contact (interaction) with the fixed contact 4. The pivotal connection of the first part 14 of the main movable contact 11 with the second end of the insulator 2 can be implemented through an intermediate connecting element 18, the profile of which has, for example, a U-shaped form, reliably embracing the end of the first part 14 of the contact 11. The pivotal connection of the movable insulator 8 with the main movable contact 11 is implemented through the second part 15 of the main movable contact 11 (through the connecting element 12 and the axis 13), wherein the other end of the second part 15 of the main movable contact 11 is designed with the possibility of interaction with the main fixed contact 5 of the second fixed insulator 3 during movement (rolling) of the movable insulator 8.

The hinged connection of parts 14 and 15 of the main movable contact 11 with each other, as well as the hinged connection of part 14 with the fixed insulator 2, and the hinged connection of the second end of the insulator 8 with the second part 15 of the main movable contact 11 ensure free movement of the main movable contact 11 (its folding and unfolding) with the possibility of closing and opening with the fixed contact 5. Due to the implementation of the main contact 11 of the "scissor" type, consisting of two parts 14 and 15, which, in turn, are hingedly connected to each other and, accordingly, to the insulators 2 and 8, reliable operation of the main movable contact 11 is ensured, breaks in the connections at the connection points are excluded during the entire service life of the disconnector, jamming is excluded, including when exposed to external factors (weather conditions, icing, ingress of foreign objects, etc.). As a result, the reliability of the disconnector and its service life in any climatic conditions are significantly increased.

Such a connection allows to significantly simplify the design of the disconnector and the kinematic connection of the movable insulator 8 with the main movable contact 11, eliminating the need to use flexible connections that can easily be damaged during operation, and significantly increasing the reliability of the disconnector in any weather conditions, including when the disconnector surfaces are icy.

Both parts 14 and 15 of the main movable contact 11 are made, predominantly, in the form of copper plates. In order to create the necessary contact pressure (to ensure the necessary reliable value of pressing of the contact 11 to the contacts 4, 5 and the contact plates 14 and 15 between themselves), springs are installed at the places of the hinged connection of the first part 14 of the main movable contact 11 with the second end of the first fixed insulator 2, the second part 15 of the main movable contact 11 with the second end of the movable insulator 8, as well as at the places of the hinged connection of both parts 14 and 15 of the main movable contact 11 with each other (for example, cylindrical compression springs, flat springs or Belleville springs are not shown). The springs are installed, predominantly, on the axes 13, 16, 17, or on one of the said axes, or on a part of the said axes, depending on the need to create the corresponding clamping force at the corresponding place of the connection of the disconnector elements.

To set the movable insulator 8 in motion and control the movable contact 11, the control lever 19 is connected to the rotary lever 10 by the movable contact 11. The connection of the lever 10 to the lever 19 is carried out using the control rod 20, which can have any length, ensuring the installation of the disconnector at any required height.

A movable grounding contact 21 mounted on a shaft 22 for rotating the contact 21 is pivotally connected to the frame 1. A rotary lever 23 is rigidly connected to the shaft 22 at one end, and the other end of the lever 23 is pivotally connected to a rod 24 for controlling the grounding contacts 21. In this case, the rod 24 is connected to a lever 25 for controlling the grounding contact 21 and can have any necessary length, ensuring that the disconnector is installed at any necessary height.

The lever 19 for controlling the main contact 11 and the lever 25 for controlling the grounding contacts 21 form a drive 26 for controlling the disconnector. The drive 26 is provided with two blocking locks 27 and 28, which are installed, predominantly, on one side of the drive 26. The rods 20 and 24 for controlling the main contact 11 and the grounding contacts 21, respectively, pass through the shaped openings of the rod catcher 29, eliminating the possibility of breaking and falling of the rods 20 and 24, increasing the reliability of the operation and control of the disconnector.

Mechanical blocking locks 27 and 28 are position locks that are designed with the ability to fix the “open”, “closed” and “grounded” positions of the disconnector, i.e. they ensure fixation of the selected position of the disconnector.

The disconnector operates as follows.

To disconnect the disconnector, the block lock 27 is unlocked and the lever 19 for controlling the main movable contact 11 is moved from its upper position to its lower position, the lever 19, using the rod 20, acts on the rotary lever 10, which rotates the movable insulator 8 on the shaft 9, and the movable insulator 8 folds parts 14 and 15 of the contact 11, thereby providing a visible gap between parts 14 and 15 (paired blades) and the main contact 5, the disconnector is disconnected (Fig. 2). Next, the block lock 28 is unlocked and the lever 25 for controlling the grounding contacts 21 is moved from its lower position to its upper position, the lever 25, using the rod 24, acts on the rotary lever 23, which rotates the grounding contact 21 on the shaft 22, thereby moving the disconnector to the grounded position (Fig. 3). Reverse switching, that is, bringing it to the on position, is performed in the reverse order.

Due to the above-described implementation of the proposed high-voltage linear disconnector of a swinging type, due to the exclusion in the main moving contact 11 of flexible connections that can easily be damaged during operation, due to the implementation of the moving contact 11 from two rigid parts, the design of the proposed disconnector is significantly simplified, while the reliability of the disconnector operation and its service life in any weather conditions, including the formation of ice, are significantly increased.

Claims (2)

1. A high-voltage linear disconnector of a swinging type, comprising a frame to which first and second fixed insulators are connected by their first ends in one phase, and a movable insulator is located between them, pivotally connected by its first end to the frame, a corresponding main fixed contact is fixed to the second end of each fixed insulator, and the second end of the movable insulator is connected to the main movable contact, characterized in that the main movable contact has two elongated parts that are pivotally connected to each other by one of their ends using a first axis, wherein the other end of the first part of the main movable contact is pivotally connected by a second axis to the second end of the first fixed insulator, the second part of the main movable contact is pivotally connected by a third axis to the second end of the movable insulator, and the other end of the second part of the main movable contact is configured to interact with the main fixed contact of the second fixed insulator, wherein at the points of the pivotal connection of the first part of the main movable contact with the second end of the first fixed insulator, the second part of the main movable contact with the second end a corresponding spring is installed between the movable insulator and both parts of the main movable contact on the corresponding axis. 2. A disconnector according to item 1, characterized in that the second part of the movable contact is pivotally connected to the second end of the movable insulator using a U-shaped connecting element.