DE1063682B - High-voltage compressed air switch with multiple interruptions per pole - Google Patents

Description

GERMAN

kl. 21c 35/10

INTERNAT. KL. H 02c

PATENT OFFICE

V15185VIIIb / 21c

REGISTRATION DATE: October 10, 1958

NOTICE THE REGISTRATION AND ISSUE DEK

AUSLE GE WRITING: 2 August 0, 1959

In the case of electrical high-voltage compressed air switches with multiple interruptions per pole, means be provided, through which the recurring voltage when the switch-off process is possible evenly distributed over the individual interruption points of the switch pole. Have proven themselves for this Ohmic resistances, which, even with the appropriate training, reduce the idle lines when switched off or transformers suppressing overvoltages. The lower the resistance Resistances are designed, the higher the one through the resistors after the switch-off process at the Power switching point is the residual current flowing, the more effective the overvoltage phenomena become prevented or limited.

In the case of circuit breakers that work without a series separator, it is necessary to measure the residual resistance current switch off by means of auxiliary switching points, their contact pieces some time after the power switching points to open. In the case of compressed air switches, this time delay is generally caused by pneumatic delay elements. The auxiliary switching points are multiple designed in the manner of a spark gap, and they extinguish the residual current arc by simply pulling them apart of the contact pieces in a pressurized room. But is it a larger one Resistance residual currents, it is necessary to blow the auxiliary switching points. Such facilities are known. So was for a compressed air switch, whose switching paths are continuously under Pressure are, suggested, the resulting during the switch-off process at the power switching point Use pressure reduction for blowing the auxiliary switching points in such a way that apart from a storage volume Compressed air flows into the room of reduced pressure and the auxiliary switching point is flushed. This device has the disadvantage that the gases ionized at the auxiliary switching point are transferred to the power switching point or their surroundings flow and can give rise to re-ignition there.

Another arrangement in which the extinguishing gases of the auxiliary switching point flow out through the main gas valve, has the disadvantage that the blow valve with its relatively large cross-section after deletion of the power arc must remain open until the residual current is also at the auxiliary switching point is safely deleted. However, this means an undesirably high consumption of compressed air and conditionally the presence of very large compressed air reservoirs.

The invention avoids these disadvantages and relates to an arrangement for compressed air switches with multiple interruptions per pole and a control resistor with high-voltage compressed air switch connected in parallel to each power switching point
with multiple interruptions per pole

Applicant:

Voigt & Haeffner Aktiengesellschaft,
Frankfurt / M., Hanauer Landstr. 142-172

Richard Schulz, Friedberg (Hess.),
has been named as the inventor

Auxiliary switching point, due to the relatively high residual currents with unusually low air consumption can be switched off at the auxiliary switching point.

According to the invention, the valve controlling the auxiliary switching point is in the same way as the valve that controls the power switching point, in a manner known per se, both as a blow valve and as a shut-off valve for formed automatic shut-off of the compressed air after the auxiliary switching point has been blown. Through this the auxiliary switching point is able to handle the arcing caused by the residual currents sure to extinguish.

The switching piece provided with a piston of the auxiliary switching point is expediently within a Piston housing of the check valve arranged displaceably. By venting the the piston housing The receiving space is during the switch-off process by the compressed air in the switching chamber first moved the contact piece with the piston and then the piston housing. The latter closes in its end position the outlet opening of the compressed air, while the contact piece with the piston again assumes its original position to the piston housing. While the during the switch-off process Displacement of the piston housing, the tensioned spring is caused by the compressed air in the switching chamber is held in a tense position, is when switched on by supplying compressed air to the The back of the piston housing lifted the holding force and the piston housing by the force of the The spring is returned to its original position, the auxiliary switching point being closed. Will the Auxiliary switching point with a relatively high

909 608/320

Claims (5)

1 voltage is applied, the passage opening for the movable switching element of the auxiliary switching point in the piston housing is expediently designed as an insulating nozzle. The pictures serve to explain the invention in more detail. Figure 1 shows the assembly of the power switching point with the auxiliary switching point; Figure 2 shows the auxiliary switching point and its actuation device with the auxiliary switching point switched on; Figure 3 shows an intermediate position of the auxiliary switch point during switch-off and Figure 4 shows the final switch-off position of the auxiliary switch point. It means 1 the chamber acted upon by compressed air, which is built on a support insulator (not shown) and in which the stationary contact piece 2 and the movable contact piece 3 of the power switching point are accommodated. The control resistor 4 with the auxiliary switching point 5, 6 is parallel to the power switching point 2, 3 Compressed air supplied. As a result, the piston 9 and the differential piston 10 move to the left, whereby the valve 11 is closed and the blow valve 12 is opened. Through the latter, the compressed air can escape from the room 1 via the switching point 2, 3 at 13 into the open. The valve 11 closes the channel 14 and establishes a connection between the space 15 and the outside space. Now the contact 3 of the power switching point can move to the right, and the drawn arc is blown and extinguished. The bore 16 in the differential piston 10 causes the pressure on both sides of this piston to equalize after some time, so that the latter, supported by the force of the spring 17 and the movement of the contact piece 3, is returned to its starting position, so that the Blow valve 12 closes again. In the switched-off position, the movable contact piece 3 is held in its position against the force of the spring 7 by the compressed air present in the space 1. The piston 18 connected to the movable contact piece 3 rests against the smaller surface of the differential piston 10 and keeps the blow valve 12 closed. Figure 2 shows the auxiliary switching point 5, 6 lying parallel to the power switching point 2, 3. A piston 19 is connected to the movable contact piece 5 of the auxiliary switching point and can move within the piston housing 20 against the force of the spring 21. The piston housing 20 is under the action of the force of the spring 22 and is located in the space 23 which is connected to the pipeline 25 via the openings 24. The pipe 25 leads, as Figure 1 shows, to the valve 26 through which the pipe 25 is connected either to the pressure chamber 1 or via the opening 27 to the outside. The valve piston 28 is controlled by the pressure in the pipeline 8. When the power switching point is closed, as shown in Figure 1, line 8 is not pressurized. So there is the pressure of chamber 1 in the pipeline 25, so that the spring 22 (Fig. 2) holds the piston housing 20 and thus the switching piece 5 in the on position. 29 is the nozzle firmly connected to the piston housing 20, which can be designed as an insulating nozzle. 682 Fig. 1 shows the auxiliary switching point switched on. If compressed air is supplied to the pipeline 8 for the purpose of opening the power switching point, the power switching point 2, 3 opens, and after a short time the valve disk 28 is moved to the left. As a result, the pipeline 25 is vented via the opening 27. The result is that the compressed air in chamber 1 acts on the piston 19 via the openings 30 (Fig. 2) and moves it upwards against the force of the spring 21 until it rests against the pin 31 of the piston housing 20 (Fig. 3) . Here, the drawn arc is extinguished at the nozzle 29. As a result of the compressed air present, the piston 19 with the contact piece 5 and the piston housing 20 are moved further upwards and the spring 22 is compressed in the process. The extinguishing gases of the auxiliary switching point can get into the pipeline 25 via the bores 30, 32, 33 and 24 (Fig. 4) and flow out to the outside. In the raised position of the piston housing 20, the opening 35 and thus the bores 24 are closed by the valve disk 34, so that in this position the compressed air is shut off to the outside. The chamber pressure now reaches behind the surface of the piston 19 via the bores 32, so that the spring 21 can relax. As a result, the movable contact piece 5 of the auxiliary switching point is brought closer to the counter-contact piece 6 while maintaining a sufficient distance. During the switch-on process, the piston housing 20 with valve plate 34 is acted upon with compressed air via the pipe 25, so that the spring 22 moves the piston housing downwards and the auxiliary switching point 5, 6 is switched on as a result. In this case, a certain damping in the movement will occur due to the displacement of the air in space 23. Patent claims: 1. High-voltage compressed air switch with multiple interruptions per pole and with each power switching point control resistor connected in parallel with auxiliary switching point, characterized in that the valve controlling the auxiliary switching point in the same, per se known manner as the valve that the power switching point controls, both as a blow valve and as a shut-off valve for automatic shut-off the compressed air is formed after the auxiliary switching point has been blown. 2. Switch according to claim 1, characterized in that the provided with a piston (19) Switching piece (5) of the auxiliary switching point can be displaced within a piston housing (20) of the shut-off valve is arranged and by venting the piston housing receiving space (23) when switching off due to the compressed air in the switching chamber (1), first the Switching piece with the piston (19) and then the piston housing (20) is moved in its End position closes the outlet openings (24) of the compressed air, while the contact piece (5) with the Piston (19) resumes its original position relative to the piston housing (20). 3. Switch according to claim 1 and 2, characterized in that the through when switching off Displacement of the piston housing (20) tensioned spring (22) by the compressed air in the Switching chamber is held in a tensioned position, and when switching on by supplying Compressed air to the back of the piston housing (20), the holding force is released and the piston housing goes back to its original position by the force of the spring (22) and here the Auxiliary switching point (5, 6) closes. 4. Switch according to claim 1 to 3, characterized in that the for venting the Piston housing receiving space serving pipeline (25) at the same time to discharge the when the arc is extinguished at the auxiliary switching point is used. 5. Switch according to claim 1 to 3, characterized in that the passage opening for the movable contact piece (5) of the auxiliary switching point in the piston housing (20) designed as an insulating nozzle is. 1 sheet of drawings @ 909 608/320 8.59