RU157350U1 - DISCONNECTOR HIGH VOLTAGE - Google Patents

Abstract

1. High-voltage disconnector containing a frame on which two fixed insulators and one movable insulator with main contacts located on the shaft, as well as one movable ground contact, in which the frame is made of a spar rigidly connected to each other, are placed in one phase , the shaft of the movable insulator and the shaft of the grounding contact are mechanically connected by a control lever placed on the frame with the possibility of rotation on its axis, equipped with sliding levers mounted on it with the possibility of Indicative opening of the main contacts and, through the position of all switched off contacts, turning on the ground contact located on the upper flange of the fixed insulator, while the position lock is placed on the control handle connected with the control lever. 2. The high-voltage disconnector according to claim 1, characterized in that the spars are interconnected by cross members using clamps.

Description

MPK N01N 31/00

High voltage disconnector

The utility model relates to high-voltage equipment, in particular, to switching devices of a combined type with the possibility of grounding and can be used in high voltage electrical networks to create a visible break in the electrical circuit.

The prior art various types of disconnectors used in high voltage electrical networks.

All known swing and chopping type disconnectors have a two-shaft drive located in the lower part of the support, having a mechanical interlock between the two shafts (excluding the possibility of turning on the grounding contacts when the main contacts are on or turning on the main contacts when the grounding contacts are turned on) and connected to the disconnector by means of two rods above, on a support. With the help of one rod, the main contacts are disconnected / turned on, with the help of a second rod, the grounding contacts of the disconnector are turned on / off.

All well-known analogues of manufacturers of ZETO CJSC ), ZAO GK Elektroshchit-TM Samara (http: //www.electros - http://www.electroshield.ru/razediniteli_rlk), LLC TEMZ (Operation manual - http://www.ooo -temz.ru/electrooborudovanie/razediniteli/razediniteli-rlk.html) have a significant drawback - the possibility of spontaneous inclusion of the main contacts in case of draft breakage under its own weight. They also have an integral welded supporting frame, which does not allow repair of the disconnector in the event of corrosion or burning of one or several phases (in this case, the disconnector changes completely).

The closest technical solution for the design and the achieved result (prototype) is a linear rocker disconnector described in the patent for utility model of the Russian Federation No. 130450 IPC H01H31 / 00, published on July 20, 2013. In the known device there are two fixed insulators and one movable, located on the axis of rotation, as well as one or two movable ground blades. The rotation axes of the movable insulator and at least one grounding knife are mechanically connected in such a way that when the main contacts open, the grounding knife is simultaneously turned on to the fixed grounding contact at the upper end of the fixed insulator, while the terminal pin is fixed to the upper flange of one of the stationary insulators , the main knife and a fixed ground contact, and on the upper flange of the movable insulator the main contact is fixed with a flexible connection, which is electrically connected to another contact a solid terminal and a fixed ground contact mounted on the upper flange of the second fixed insulator.

This disconnector was developed for JSC Russian Railways and cannot be used in all circuit designs of JSC Russian Grids.

A disadvantage of the known device is the parallel operation (simultaneous operation): opening of the main contacts and the inclusion of the grounding contact, which contradicts the "Intersectoral rules for labor protection (Safety Rules) when operating electrical equipment POT R M-016-2001" (Disconnect - Check - Ground) and "Instructions for the operation of operational safety interlocks in high voltage switchgears" RD 34.35.512.

The objective of the utility model is to simplify the design, increase the safety, reliability and maintainability of the device.

The solution to this problem is achieved by placing on the frame a curly control lever mechanically connected through sliding levers with a shaft of main contacts and a shaft of grounding contacts, with the possibility of fixing the curly lever in the desired position. The frame, at the same time, is made of a team of spars and cross members rigidly connected to each other.

The essence of the technical solution is that in the high-voltage disconnector, the horizontal frame is made of a team consisting of spars rigidly interconnected, on which two fixed insulators and one movable insulator located on the shaft, as well as one movable ground contact, are placed in one phase. The shaft of the movable insulator with the main contact and the shaft of the ground contact are mechanically connected by a curved control lever and sliding levers in such a way that when the main contacts are opened, in series, through the fixed position “Disconnected” of the main contacts (providing a visible gap), the ground contacts located on the upper flange of the fixed insulator, which provides rigid mechanical blocking of the main contacts and grounding contacts, and the complete disconnection of the main contacts with the next inclusion of grounding contacts (sequential switching, in contrast to the design of the prototype, with parallel switching). This ensures complete safety during any operational switching in electric networks.

The utility model is illustrated with graphic materials.

Figure 1 schematically shows a high voltage disconnector in the on position (main contacts are closed, grounding contacts are disconnected).

Figure 2 - high-voltage disconnector in the position when the main contacts are disconnected, grounding contacts are also disconnected.

Figure 3 - high-voltage disconnector in position with the included ground contacts and disconnected main contacts.

Figure 4 shows the assembly frame of the disconnector, top view.

Figure 5 is a prefabricated frame, side view.

The high-voltage disconnector contains a frame 1, consisting of spars 2 and cross-members from a square tube 3 connected by clamps 4. Fixed insulators 5 are placed on the frame, with fixed main contacts 6 and one fixed ground contact 7 and mounted on shaft 8, movable the insulator 9, bearing the movable main contact 10. On the surface of the frame 1 on the axis 11, is mounted, with the possibility of rotation in a plane perpendicular to the surface of the frame 1, a shaped control lever 12. The control lever 12 is mechanically connected with the shaft 8 of the movable insulator 9, through the sliding lever 13 and with the shaft 14 of the movable ground terminal 15, through the sliding lever 16. On the handle 17 of the control lever mechanically connected with the control lever 12, a latch 18 is made to fix the control lever 12 in the desired position.

The disconnector operates as follows.

Initially, the control lever 12 is in the "Disabled" position, at an angle of about 45 ° with respect to the horizontal surface of the frame 1 (figure 2). When the control lever 12 is turned to the extreme horizontal position parallel to the surface of the frame 1, the main contacts 6 and 10 are closed using the sliding lever 13, and the control lever 12 is fixed in the extreme horizontal position by means of the latch 18. The grounding contacts 7 and 15 are disconnected (Fig. 1). When the control lever 12 is in the "Disabled" position, the sliding lever 13 returns and opens the main contacts 6 and 10, while the ground contacts 7 and 15 are also in the off state (figure 2). In this position, you can check the absence of voltage. After that, the control lever 12 is moved to its lowest position (at an angle of about 80 °, which is determined experimentally) and the sliding lever 16 closes the ground contacts 7 and 15, and the control lever 12 is fixed using the latch 18 in the lowermost position (Fig. 3). There is a sequential (sequential) switching on and off of the main contacts and grounding contacts, which completely eliminates the physical inclusion of the main contacts and grounding contacts at the same time. The frame is made by a team of spars and cross members to ensure greater reliability and maintainability of the structure.

Thus, a complete disconnection of the main contacts with the subsequent inclusion of grounding contacts and vice versa - disconnection of the grounding contacts with the subsequent inclusion of the main contacts is ensured. Guaranteed work safety. In addition, due to the design features of the levers 12, 13 and 16, the possibility of spontaneous inclusion of the main contacts when the draft is cut off is excluded.

The maintainability of the disconnector is provided by a fully prefabricated rigid support frame (one or more phases of the disconnector can be replaced).

The technical effect is to simplify the design, increase the safety, reliability and maintainability of the device.

Thus, the problem facing the utility model is solved.

Claims (2)

1. High voltage disconnector containing a frame on which two fixed insulators and one movable insulator with main contacts located on the shaft, as well as one movable ground contact, in which the frame is made of a spar assembly, are rigidly interconnected , the shaft of the movable insulator and the shaft of the grounding contact are mechanically connected by a control lever placed on the frame with the possibility of rotation on its axis, equipped with sliding levers mounted on it with the possibility of The essential opening of the main contacts and, through the position of all switched off contacts, the inclusion of the grounding contact located on the upper flange of the fixed insulator, while the position lock is placed on the control handle connected with the control lever. 2. The high-voltage disconnector according to claim 1, characterized in that the spars are interconnected by crossbars using clamps.

Images