DE1008384B - Gas pressure switch - Google Patents

Description

GERMAN

The invention relates to control devices for the gas push valves provided in compressed gas switches and movable contact organs.

In the case of a pressure gas switch working according to the permanent pressure principle, there is a fast running interruption electrical circuits achieved in that one of the mutually movable interrupter contacts arranged in an interrupter chamber filled with high pressure gas. One serves to extinguish the arc of a gas surge that occurs when the contact is opened, which one in the generally generated by controlling a gas surge valve so that a high pressure and large gas jet during the interruption process Speed between the opening contacts escapes into the open air. To achieve, that the gas burst is triggered exactly when the contacts open, and that furthermore after the interruption process If further high pressure gas is provided, one must observe the movements of the gas push valve and the breaker contacts coordinate precisely with each other. It is known to this end to control the arc-extinguishing gas jet through the movable contact. It is desirable that the gas surge valve opens immediately before the contact is released and 'immediately after the occurrence of the The circuit interruption caused by a certain contact distance closes.

It is also already known, the gas outlet valve and the drive member for the movable contacts via a Coupling to connect with each other. The clutch is mechanical in the known case and is through Lever done. However, this complicates the structure of the gas pressure switch, in addition to Operation of the mechanical devices requires greater drive powers.

The purpose of the invention is therefore to provide a simple and reliably working control device for the To create gas push valve of a pressure gas switch. This purpose is achieved by using the movable Contact members and the gas push valve according to the invention by means of a pneumatic coupling connects with each other, the coupling consists of a cylinder, which is connected to the drive member connected drive piston and a follower piston connected to the ■ gas push valve is provided and that this cylinder one or more with the pressure Iptmmer having communicating openings. The pneumatic coupling causes an opening of the gas surge valve before the contact detachment and on the other hand ensures that the gas surge valve is after Establishing a certain contact distance independent of the movement of the contact organs closes.

Gas pressure switch

Applicant:

General Electric Company,
Schenectady, NY (V. St. A.)

Representative: Dr.-Ing, E. Sommerfeld, patent attorney,
Munich 23, Dunantstr. 6th

Claimed priority:
is V. St. v. America from, 10. Decemberil953

John Wood Beatty, Lansdowne, Pa.,
and Reed Macomber Anderson, Glenolden, Pa.

(V. St. A.),
have been named as inventors

Another embodiment of the invention is such a pneumatic coupling with a structural

Equip 3d simple contact control shock absorber. The invention is also intended to provide a novel arrangement of contacts that can move relative to one another be created, which enables a very quick contact opening and especially for compressed gas switches, which work according to the permanent pressure principle is suitable.

The invention therefore consists in that the movable contact members have a pneumatic coupling are operatively connected to the gas push valve.

The coupling consists of a cylinder and two opposing cylinders that can be moved back and forth Pistons. One of these pistons serves as a driving piston and is connected to the movable contact elements coupled, while the other piston is connected to the gas surge valve and as a follower piston is working. Due to the contact-opening movement of the drive piston, between the front and Rear side of the follower piston created a pressure gradient, consequently the follower piston from the drive piston is subsequently taken along and thereby opens the normally closed gas surge valve. In addition, suitable devices are provided which ensure that the pressure gradient mentioned is maintained very quickly after a certain opening stroke

709 509/304

reduces, whereby the follower piston is released and the gas surge valve is closed again. Furthermore, the cylinder has a constriction at its end through which the gas, which moves in front of the drive piston moving into the open position, is compressed and a shock absorber effect is thereby achieved at the end of the opening stroke.

The invention will now be described in its further details with reference to the drawings. In the drawings means

Fig. 1 is an elevation, partly in section, of one according to the invention Gas pressure switch,

Fig. 2 is an enlarged section along the line 2-2 from Fig. 1,

The two pipe attachments 43 are used to hold the bridging contacts 34 and 35 in a pivotable manner and 44 each provided with a fork head 45. A suitable pivot pin 46 is seated on the fork heads 45, which sits freely in an opening at the inner end of the associated bridging contact. Like on best seen in Fig. 2, a properly functioning friction contact is achieved in that the outermost ends of the contact rod 31 and ίο the contact nozzle 33 have a rectangular outer cross-section there and the contact bridge 35 is provided with spaced arms 47, which with their substantially smooth inner surfaces making contact on the smooth side surfaces of the corresponding stationary

Fig. 3 is a detailed view of a 15 contacts 31 and 33 according to the invention slide along.

pneumatic coupling,

Fig. 4 shows another embodiment of the pneumatic coupling according to the invention and

Fig. 5 still another embodiment of the pneumatic coupling according to the invention.

Fig. 1 shows a gas pressure switch with an interrupter unit 10. This interrupter unit consists from an all-round interrupter chamber 11 ,, which is through a metal housing 12 and two

In order to open and close the contact bridges 34 and 35 according to Fig. 1, an open and from movable drive rod 50 provided, which at their lower end is connected to a suitable, not shown 20 drive mechanism. At her upper The end is the drive rod 50 made of insulating material via a crosshead 51 attached to it with the Contact bridges 34 and 35 connected. This cross head has a connection made of insulating material pipe sockets 13 and 14 at both ends, the 25 pieces 52, which at the points 53 and 54 by means of gean the two opposite ends of the housing suitable pivot pin pivotable with the corresponding -12 are attached, is formed. The interrupter, the contact bridge and cross head end are intermingled 11 stands over an insulating tube 15 with a bond.

High pressure gas source (not shown) in connection. By means of a compression spring 55, the contacts 34

so that the chamber 11 is pressed into the contact-closing position with a gas equal to 30 and 35. Pressure, as it prevails in the gas source, is filled. If the drive rod 50 is now against the tension of the The outer ends of the Kammerll are moved very quickly downwards by the clamping spring 55, so are plates 20 and 21, which on the pipe sockets 13 and 14 so that the contact bridges 34 and 35 very quickly are attached, sealed. The pipe sockets 13 and their previous position in Fig. 1 with dashed lines 14, which are made of a material, the 35 lines of which are indicated position 56, i.e. the contacts mechanical strength is sufficient to open the circuit and the circuit is broken. Chamberll to record the prevailing continuous gas pressure, in order to delete the contacts when opening expediently in weather-resistant bridges in the columns 25 and 26 resulting light-porcelain tube insulators 22 and 23 stored. One or two throttle strokes are used for the holding bows, In addition, the interrupter unit 10 is provided with an insulating 40 for the generation of which an outflow channel 60 is provided tubular column 24, which encloses the tube 15 and is intended to be taken from the interrupter chamber 11 through the moderately made of porcelain, contact tubes 32 and 33 and through the cylindrical

The stationary contact organs for the lower casting leads to the outside air. The contact tubes Crushers according to Fig. 1 consist of two elongated 32 and 33 with nozzle mouthpieces or openings Contact rods 30 and 31, which are provided by the clamping plates 45 57, which form the inlets of the outflow channel 60 20 or 21 are worn and form inside the. To control the arc extinguishing gas flow through Extending chamber 11, as well as from two centrally located nozzles 57 and channel 60 serves a back and forth arranged, electrically interconnected nozzle-movable gas push valve 61 of cylindrical contact pipes 32 and 33. These two contact pairs are formed at the outer end of the outflow channel 60 form at their outer ends two gaps 25 and 26, 50 is arranged in a tubular valve housing which slides through two pivotably arranged, movable 62 and in the closed position on one Contact bracket 34 and 35 are bridged. The stationary valve seat ring 63 rests. Thus the Clamping plates 20 and 21 are each connected to the power line and outflow channel 60 all in all through the nozzles 57, gene 36 and 37 connected so that the electrical the inner walls of the contact tubes 32 and 33, the Current conduction through the interrupter as follows- 55 inner walls of the cylindrical casting 40, the represents: Outer wall of the valve housing tube concentric to this from the power line 36 and the clamping plate 62 and the valve seat ring 63 fastened in a suitable manner to the casting 40. The gas push valve 61 works, as shown in figure 60, according to the piston balancing principle and is normally urged to the closed position by a spring 64. After the chamber 11 is normally filled with high pressure gas, flows as soon as the valve 61 (by means of is guided downwards by means of a suitable flange support 42 on the device 65) and thus housing 12 is attached. At its lower end opens, gas at great speed from the

Kammerll through the nozzles 57 and the channel 60 over
the valve 61 to the outside. This very fast gas flow through the nozzles 57 calls into the columns 25 and
26 an axial blowing tube enveloping the arcs

20 through the contact rod 30, the contact bridge 34, the contact tubes 32 and 33, then through the contact bridge 35, the contact rod 31 and finally through the clamping plate 21 into the power line 37.

In order to keep the centrally arranged contact tubes 32 and 33 in axial alignment, one is essentially cylindrical casting 40 is provided. The casting 40 has at its upper end a flange 41 which

the casting 40 sits two tubular lugs 43 and 44, which fit tightly into the contact tubes 32 and 33, respectively and fused to the inner ends thereof.

effect that serves to extinguish the arcs.

In detail, the creation and extinction of the arc occurs during the opening of the interrupter contacts in front of you as follows: At the moment when the brackets 34 and 35 move rapidly downwards move is between the contact rod 30 and the bracket 34 and the contact rod 31 and the bracket 35 an arc is formed each time. Since immediately before the contact separation, the gas surge valve 61 has been opened is, as a result of the high pressure gas flow through the nozzles 57 at the gaps 25 and 26, the blowing effect set. This blowing effect creates a tubular gas flow that has a certain Has speed and envelops the arc, so that the arc very quickly from the bracket 35 and 35 are sucked into the contact tubes 32 and 33 and go out there immediately.

Since each interruption surge in the chamber 11 causes only a small pressure drop, high pressure gas is available at the gaps 25 and 26 at all times. Furthermore, since the dielectric strength of a gas is generally directly proportional to the pressure of the gas in question, a relatively very small contact opening is sufficient to create a fully adequate interruption insulation at the gaps 25 and 26. It is thereby achieved that the pivotable brackets 34 and 35 can already perform their interrupting and insulating function a very short time after the initiation of the contact separation. This means that a large part of the opening stroke of the brackets 34 and 35 is available elsewhere and is therefore used in order to produce a braking effect which in no way affects an interrupter and isolation characteristic of the arrangement. Assume that the full opening angle of the swivel bracket is z. B. 28 ° and a full insulation effect occur at an opening angle of 14 °, which corresponds to a position in which the distance between the contact rod 30 and the bracket 34 corresponds to the distance between the contact stroke 30 and the contact tube 32, there is a remaining Angle of rotation of a further 14 ° is available for braking the moving parts of the interrupter. The braking effect is further promoted by the pivoting arrangement of the brackets 34 and 35, since only the outer ends of the bracket move at a relatively high speed, while the heavier drive mechanism in the immediate vicinity of the pivot pin 46 is connected to the bracket and therefore with much less Speed moves. In this way, the movements of the parts are slowed down more easily at the end of the opening stroke. It should be noted that the movements of the contacts 32 and 33 and of the gas push valve 61 must be precisely coordinated with one another. In particular, in order to achieve very rapid arc extinction, it is desirable for the extinguishing bubble effect to set in somewhat before the arcs are formed between the breaker contacts. Furthermore, in order to maintain the gas pressure in the chamber, it must be ensured that the gas surge valve closes as soon as the circuit is interrupted. In order to bring about the necessary coordination of the valve and contact movements, the pneumatic coupling 65 is provided according to the invention, which establishes an operative connection between the contacts 34, 35 and the gas surge valve 61. An embodiment of this pneumatic coupling is shown in detail in FIG. Thereafter, the coupling 65 consists of a stationary cylinder 66 and two reciprocally movable, coaxially arranged, cooperating pistons 67 and 68. The lower or drive piston 67 is driven by the cross head 51 by means of a piston rod 69 which is located between the piston 67 and the cross head 51 and is slidably guided through a sealed opening located in the lower end wall of the cylinder 66. The upper or trailing piston 68 is means of

ίο a piston rod 70, which is between the piston 68 and the gas push valve 61 is arranged, coupled to the gas push valve 61. The pistons 67 and 68 are sealed along their outer periphery against the inner wall of the cylinder 66, so that practical no gas can escape along the piston walls. Appropriately for sealing conventional piston rings (not shown) are used.

The coordination of the contact and valve movements

ao conditions by means of the pneumatic coupling 65 proceeds as follows: As long as the contacts are closed pistons 67 and 68 are in the position shown in FIG. Since the cylinder 66 is on its upper end has a passage 71 communicating with the chamber 11 and there furthermore, the upper piston 68 is provided with a narrow passage slot 72, prevails on both Sides of the piston 68 the same pressure as in the gas pressure source, as long as the two pistons are in the are in the position shown in Fig. 3. The same pressure prevails below the drive piston 67, as a result one located near the lower end of the cylinder 66 and communicating with the chamber 11 standing narrow outlet opening 80. At the moment when by means of mechanical drive devices, not shown the piston drive rod 50 is moved very rapidly downwards for the purpose of opening the interrupter the lower piston 67, which is rigidly coupled to the rod 50, also moves very quickly below. This downward movement provides an instantaneous reduction in the space in the narrow space gas pressure prevailing between the two pistons. As a result of this arises on the axially opposite one Sides of the upper piston 68 a pressure drop very quickly. With continuous downward movement of the lower piston, this pressure gradient very quickly reaches a value that is sufficient to counteract the restoring force of the valve spring 64 is a downward movement following the movement of the lower piston 67 of the upper piston 68 to force. This dislodges the gas push valve 61 from its seat peeled off and opened in the desired manner. The smaller the original space between the two pistons, the further or more rigidly the follower piston follows the movement of the drive piston. The movable contacts 34 and 35 have sufficient contact adhesion to the stationary contacts, so that the gas push valve 61 opens exactly at the moment when the contacts are about to to break away from each other. This ensures that the desired bubble effect at the columns 25 and 26 begins at the moment when the arcs are about to develop.

The upper piston follows the lower piston until the valve 61 hits a stop ring 75 which sits at the head of the cylinder 66 on a somewhat yielding buffer ring 76. As soon as the valve stop occurs, the downward movement of the upper piston 68 is stopped in a Position where the valve is fully open. Of the

7 8

Lower piston 67 sets against it, driven by it is achieved that the desired blowing effect is almost

the interrupter drive mechanism, its release simultaneously with the triggering of the opening movement moving forward. As a result, that of the cross head 51 is used again.

The pressure between the two pistons is reduced and the closing of the interrupter is used at the same time, as a result of the compression of the gas in 5 spring 55, which, as soon as it is disengaged, the Kreuzdem constricting cylinder space below the head 51 and the contacts 34, 35 upwards into the piston 67, the pressure on the bottom of the piston pushes closed position. One in the lower piston 67 67 increased. The check valve 77 arranged in this way on both sides ensures that the The pressure gradient formed by the piston 67 calls for a relatively free gas through the piston 67 moderate delay effect, which can flow down and thus the closing process during the last section of the opening stroke without excessive braking on the part of the pneurna. As a result, at the end of the table clutch 65 expires.

Opening stroke the movement of the interrupter parts In Fig. 4 is a modified embodiment

gradually slowed down. shown, which also serves to achieve the desired

As already mentioned, so that the gas pressure is maintained in dependence on the valve and contact movements at the chamber 11, it must be ensured at a certain point of the opening stroke that the valve 61 reaches a suitable time. Those parts in Fig. 4 which correspond to the detent point during the opening stroke or at least in the speaking parts in Fig. 3 are identified with the same reference numbers as in Fig. 3 at the moment when the opening stroke is ended. Since the interrupter according to 20 Fig. 3. In the arrangement according to Fig. 4, an outlet opening 80 ″ is provided that is expediently in the open position in Fig. 1 in comparison to the opening 80 according to Fig. 3 by means of suitable latching devices (not shown) is locked, the return of the valve 61 in opening 80 ^a , which creates a connection between the closed position regardless of the interrupter chamber 11 and the interior of the cylinder opening of the valve causing drive 25 ders 66, is expediently done slightly above mechanism. This independence of the lowest movement (indicated by dotted lines) is arranged according to an embodiment of the position 81 which the drive piston 67 occupies at the end of the interrupter according to the invention by means of an outlet opening stroke the upper one is set as soon as the drive piston 67 with the trailing piston 68 guided Durchlaßschli tz 72 exists. When the piston 68 moves into its lowest position 81 and the contacts move towards the fully open position opening 80 ° with the space between the two and the pistons 67 and 68 come into contact in follower pistons, an instantaneous coupling occurs are guided below, by reducing the on both sides of the follower piston 68 the slit 72 a small gas flow seeps into the pressure gradient prevailing in the space, so that the follow-up between the two pistons. The piston through the slot 72 35 separates itself from its driving piston and under the seeping gas causes a gradual reduction of the pressure that is immediately prevailing again on both sides of the follower piston under the influence of the valve spring 64 and the valve closes, falling, so that after a certain downward movement - By opening the opening 80 ^a at any movement of the follower piston, the pressure on both sides desired point in the wall of the cylinder 66 of this piston is balanced to the extent that the 40 is arranged, one can achieve that the follower valve spring 64 come into action and the Follow-up piston can lead back to the opening stroke from its follow-up clutch released position at this desired point on the piston. The slot 72 will enter. After the opening 80 ″ for the is expediently dimensioned so that the approximately solution of the follow-up coupling is made usable, the amount of gas that seeps through three current cycles is just 45, the passage slot in the follow-up piston can be sufficient to avoid the reversal of the follow-up piston and behrlich,
of the gas surge valve to trigger. In the arrangement according to Fig. 4 is in the

As can be seen from the above, the moment when the opening stroke has ended is carried out the pneumatic clutch 65 not only a very emphatic away breaker parts flawless coordination of the valve and contact braking force is granted by the fact that, to the extent that movements in the desired manner, but rather the drive piston 67 beyond the opening 80 ″ that acts at the same time as an excellent thrust - moved further downwards, he is forced, that in Damper for braking the movement of the lower part of the cylinder 66 breaker parts at the end of the opening stroke. compress trapped gas.

It can also be seen that the pneumatic 55 In Fig. 5 is an otherwise modified Ausmatic Coupling is particularly suitable, the gas shock guide form of the invention shown, with the control valve 61 in such a way that the corresponding parts in Fig. 1 coincide Gas bubble effect on columns 25 and 26 with except- parts with the same reference numbers as in Fig. 1 proper promptness sets in as soon as the undersigned are designated. The arrangement according to Fig. 5 interrupter reacts to a line fault. Especially 60 differs from the previously described anordist, since the space above the valve-coupled openings is mainly due to the fact that according to Fig. 5 the upper Piston 68 in open connection (directly on the drive mechanism for the interrupter Point 71) is combined with the permanent pressure interrupter chamber with the pneumatic coupling, 11 stands, at any time the full gas pressure above that while it was previously arranged separately from it. Piston 68 available. As a result, at only 65 As can be seen from Fig. 5, the pneumatic slight downward movement of the lower piston 67 clutch 90 - exactly as in the arrangement according to from the closed position according to Fig. 3 immediately Fig. 1 ■ - between the gas surge valve 61 and the a strong downward force on piston 68 and having crosshead 51 arranged. However, according to Fig. 5 is exerted on the valve 61. By this very the opening movement of the contacts by one prompt opening reaction of the gas push valve 61 70 gas suction in the piston located below the lower

Union closed cylinder space caused, with the help of the two-way valve 92, which is controlled by suitable (not shown), responsive to any line disturbances devices. The continuous pressure interrupter chamber 11 is ^{in free communication with the gas reservoir 88 via a line 88 a} , so that when the contacts are closed, as shown in the figure, the gas pressure prevailing on both sides of the lower or drive piston 91 is equal to that in the reservoir 88 prevailing pressure is; This is the case because the upper side of the piston 91 is in communication with the interrupter chamber 11 via an opening 93 located in the cylinder 89 and a passage slot 94 guided through the upper or trailing piston 95, and the underside of the drive piston 91 in a similar manner Way via the line 96 and the valve 92 is connected to the reservoir 88. Accordingly, as in the arrangement according to FIG. 3, the two pistons are subjected to an even pressure as long as the contacts are in the normally closed position, so that the gas push valve and the contacts are closed, obeying the pressure of the springs 64 and 55, respectively. If the control valve 92 is now rotated clockwise to the position indicated by dashed lines at 95 ° and the line 96 is thus opened to the outside air, a pressure gradient is created on the two opposite sides of the lower piston 91. This pressure gradient is sufficient to very quickly press the piston 91 and the cross head connected to it downward against the tension of the closing spring 55, so that the breaker contacts open. This downward movement of the lower piston causes a pressure drop on the underside of the upper piston 95, as a result of which the upper piston is carried downward in a follow-up coupling until the valve 61 strikes the stop 75. The passage slot 94 allows a restricted gas flow into the coupling space between the two pistons, so that after a certain time delay the pressures on both sides of the upper piston equalize and thus, as in the arrangements according to Figs. 1 to 3, the valve 61 is driven back into the closed starting position under the influence of the spring 64.

An additional feature of the arrangement according to Fig. 5 is that the devices that serve to hold the breaker contacts in the open position, directly with the pneumatic Coupling are united; namely the lower one. Piston 91 is provided with a raised seat ring 97, which, when the piston 91 is in its lowest position, on the lower wall 98 of the Cylinder 89 sits and seals the cylinder space against the line 96. If this condition occurs, so the force exerted by the gas pressure above the lower piston 91 ensures that the piston 91 is held in its lowest position as long as the control valve 92 is opened to the outside air is. In this way the breaker is held in the open position as desired.

The closing of the interrupter according to FIG. 5 can be brought about by ^{bending the control valve 92 back from the open position 95 a} into the original normal position and thereby directing high-pressure gas against the lower surface of the piston 91. This high-pressure gas presses the piston 91 upwards together with the spring 55 and thus causes the breaker contacts to close. The check valve 99 arranged in the upper piston 95 ensures that the lower piston 91 moves upward without being significantly braked by the gas ίο enclosed in the coupling space between the two pistons.

Claims (7)

Patent claims: 1. Compressed gas switch, consisting of separable contacts arranged in a pressure chamber, a movable gas push valve to control the directly at the contacts the chamber exiting gas flow and a movable drive member for bringing about the Contact separation, whereby the gas push valve and the drive member are connected to one another via a coupling are connected, characterized in that the coupling is pneumatic and consists of one Cylinder consists of a drive piston connected to the drive member and a with the gas push valve connected follower piston is provided, and that this cylinder one or has a plurality of openings communicating with the pressure chamber. 2. Compressed gas switch according to claim 1, characterized in that the cylinder has a substantially has closed wall part, in which the piston is guided in a sliding and sealing manner are so that the entry of gas into the space between the two pistons during at least part of the piston stroke is prevented. 3. Compressed gas switch according to claim 1 or 2, characterized in that the drive member through the opening stroke of a contact is moved and that devices for releasing the follower piston are provided after a certain part of this opening stroke. 4. Compressed gas switch according to claim 3, characterized in that the release device from a passage consists of the space between the two pistons with a gas source whose Pressure is higher than the gas pressure prevailing in this space, connects. 5. Compressed gas switch according to claim 4, characterized in that the passage from a through the caster piston-guided slot consists. 6. Compressed gas switch according to one of claims 1 to 5, characterized by stop devices, by which the stroke of the follower piston is restricted so that it is shorter than the stroke of the drive piston. 7. Compressed gas switch according to one of claims 1 to 6, characterized in that a Valve (92) for emptying the space on one side of the drive piston the outside air is provided. Considered publications:
German patent specifications No. 662 401, 659 030, 504 736, 305 797, 288 168. 1 sheet of drawings 509/304 5.57