SU566537A3 - Gas-filled switch - Google Patents

Description

(54) GAS SWITCH

one

The invention relates to high-voltage instrumentation, in particular, tank-type gas switches.

Tank type gas switches are known to contain a low pressure tank,

inside of which there is a high-pressure chamber with open contacts, - connected by means of an insulating rod with a piston-type driving device. ; The purpose of the invention is an improved switch speed.

In the proposed device, this is achieved by the fact that the driving device is made in the form of a gas-filled chamber with a piston connected through a seal to a source of pulsed driving force, and the latter is used to use electromagnetic force or the force of an explosive blast.

FIG. 1 shows schematically a pre-burned switch, general view; 2-4 shows a drive device in which electromagnetic pulse force is used (three options); in fig. 5 is a drive device in which explosive force explosive is used.

The switch (see Fig. 1) is designed symmetrically with respect to the central power supply unit and: connected to the high voltage line through the glands 1. The switch contacts are located in the high pressure chambers 2, which are located in the low pressure cavity 3 of the tank 4, which is at ground potential. High pressure tanks are filled with gas. The switch contacts are driven by driven piston y-ports 5 by means of insulating rods 6. The actuators are located outside the tank. The tank is installed on the base 7.

The drive unit 5 (see FIG. 2) has been completed as follows. The housing 8 forms a high pressure chamber 9. Inside (the high pressure chambers are located a guide cylinder 1O, having a flange 11 in the middle part, in which a drive disc coil 12 is installed. The flange of the DZ valve 14 is located opposite the coil. Relatively the coil 13 a coil. A chamber 15 is formed between the valve body and the guide cylinder, communicating through the three-way valve (not shown) to the outside atmosphere,

or with a source of compressed air. Sealing elements 16-G8 are used for sealing. The front part of the guide cylinder is designed as a cup 19, thereby forming o-. . side chamber 20 communicating with the atmosphere. The cup 19, together with the seal 21, includes the end part 22 of the drive bar 23, which is directly connected to the insulating rod 6. To maintain high pressure in the housing of the drive unit, seal 24. The end portion of the drive rod 23 is spring-loaded 25. The valve is sealed by seals 26 and 27. The middle part of the guide cylinder is made with a through hole 28, as a result of which the pressure in the body of the actuator can act on the front surface of the valve flange. A cavity 29 is formed between the cup 19 and the valve 14.

The drive device (see Fig. 2) works as follows. Upon receipt of the switch: the command to turn off the previously charged capacitor (not shown in the drawings) is discharged to the drive coil 12. At the same time, between the coil and the flange:. Valve 14 produces a repulsive repulsive force, as a result of which the valve moves quickly, trying to move more and more away from the drive coil.

The sealing effect of the seals 26 and 27 is disturbed, with the result that the cavity 29 is connected to the diversion chamber 20, which communicates with the atmosphere. Under the action of pressure in the drive unit housing / acting on the end portion 22 of the drive rod 23, the latter is moved, compressing the spring 25. As a result, the switch contacts connected to the insulation rod 6 are opened through the drive rod 23. and a shutdown occurs.

Inclusion occurs as follows. Compressed air through a three-way valve (not shown in the drawings) is supplied to chamber 15, where under the action of pressure in, the valve moves to its original position. After which the chamber 15 will be under atmospheric pressure. The drive rod with the co-piece also returns to its original position. The switch contacts are closed through the insulation

Nyu barbell. Turns on the switch.

The described device is an exhaust type device, as from chambers 15 and 20. air is sucked into other chambers or from others into these chambers.

Another embodiment of the drive device is shown in FIG. 3. The housing 8 has an internal flange 30 in which a drive coil 12 is installed. Opposite the coil is located the flange 13 of the valve 14. Sealing 31 is sealed between the housing and the valve. The valve is spring-loaded spring 32. The chamber 33 is located between the housing and the valve a damper 34 is installed. On the other side of the inner flange is a chamber 35 which, through a three-way valve 36, is connected to the inlet pipe 37 and the outlet pipe 38 in communication with the atmosphere. Channel 39 reports cameras 33 and 35.

Inside the valve 14 passes the actuator rod. 23, one end of which is connected to the switch contacts via an isolation rod. The end part 22 of the rod 2 3 has the form of a spring-loaded piston moving to the rear of the housing, made in the form of a cup 4.0, on the back wall of which a damper 41 is installed and holes 42 are formed, forming an air damper. Through these holes from the chamber 43 air is released. A sealing ring 44 is installed on the end part of the drive shaft. A seal 45 is installed between the end portion of the drive rod and the valve flange, and between the valve and the drive rod are seals 46 and 47.

The drive device (see Fig. 3) works as follows. When the switch receives a shutdown command, the previously charged capacitor is discharged to the drive of the first roller 12. Under the effect of the arising force, the flange 13 together with the valve 14 quickly moves to the right. When the flange moves, the action of the seal 45 is eliminated, as a result of which the air pressure in the chamber 35 begins to act on the end part 22 of the drive rod .23, and it moves to the left, overcoming the force of the return spring 25. As a result, the switch contacts open. There is a shutdown. The damper 41 and the orifice 42 weaken the impact force.

To turn the switch on, it is necessary for the camera 35 to communicate with the atmosphere. For this, the three-way valve 36 is moved to the discharge pipe 38. As a result, the pressure in the chambers 35 and

33 gradually decreases, and when it becomes less than a certain value, the valve body 14 is returned to its original position by the action of the spring 32. The actuating rod 23 also returns to its original position. The switch contacts are closed. Inclusion occurs.

The device shown in FIG. 3 has a higher switching speed than the device shown in FIG. 2

FIG. 4 shows a pneumatic wiring device (one of the options). This device is different from the device shown in FIG. 3, in that the drive rod 23 passes through the supporting structure 48. Such a co-operation can be any fixed element of the switch. The drive rod 23 passes through: through the inner hole of the movable magnetic

core 49. A fixed magnetic core 50 is attached to the device body and a drive coil 12 is installed between the fixed and movable cores. Sealing between the cores is carried out using 51 n seals.

52. „

The drive device (see Fig. 4) works as follows. When the switch receives a switch-off command, the previously charged capacitor is discharged to the drive coil 12. The coil is energized and the moving core 49 is quickly attracted to the fixed core 50. Moving the moving core to the right eliminates the effect of the seal 45, resulting in air pressure located in the chamber 35, begins to act on the end portion 22 of the drive rod 23 ,. and it moves to the left, and so on. Further operation of the device is similar to the operation of the device shown in FIG. 3

Switching the switch on with the help of the drive device according to FIG. 4 occurs in the same way as the switch is turned on by the driving device according to FIG. 3

Pa figs. Figure 5 shows a drive device (one (P1 of the variants), in which the explosive force of an explosive is used as the impulsive ... force. This device differs from the devices shown in Fig. 3 and 4 in that the valve 14 is located in chamber 53 and its flange 13 - into the body of the drive device 8. Pressure resulting from the explosion is transmitted through the channel 54 to the chamber 53.

The device works as follows. When a shutdown command is received, an explosive-1 substance explodes, which causes an increase in pressure in chamber 53. As a result, valve 14 with flange 13 is moved to the right. Moving the flange 13 to the right eliminates the effect of the seal 45, as a result of which the air pressure in the chamber 35 begins to act on the end portion 22 of the actuating rod 23, and it moves to the left, and so on. The operation of the device is similar to that of the devices shown in FIGS. 3 and 4. Switching the switch on with the drive device shown in FIG. 5 is similar to turning on the switch with the driving devices shown in FIG. 3 and 4.

Claims (3)

1. Gas tank type switch containing a low pressure tank, inside of which a high chamber is located. pressure with break contacts connected by means of an isolation rod to a piston type actuator device By the fact that, in order to increase speed, this drive device is made in the form of a gas-filled chamber with a piston connected through a seal with a source of pulsed driving force. 2. A switch according to claim 1, characterized in that electromagnetic force is used as the pulsed driving force. 3. The switch according to claim 1, about tl and h. Yusch and the fact that the force of an explosive is used as a pulsed driving force. I U -, „„ .., „„ ...- ..-. Л .i 7 Cfif iLfjf ff f fj 7 7 ///////  // / v. figure 1 4 & i / 3. J J5 38J7 FIG. , rm .-. sp. 35