DE1172756B - Gas pressure switch - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Boarding school Class: H 02 c

GERMAN

PATENT OFFICE

EDITORIAL

German AI .: 21c-35/10

Number: 1 172 756

File number: G 33825 VIII d / 21 c

Filing date: December 15, 1961

Opening day: June 25, 1964

The invention relates to a pressurized gas switch with a pressurized gas Housing, in which separable main contacts, with the help of a delay device later separating auxiliary contacts and a control device for the contacts are arranged and in which the movable contacts are telescopically displaceable with respect to the stationary contacts and the contact actuation takes place by the pressurized gas. It is already a pressurized gas switch known, its contacts in a with on and off switch under pressure standing chamber are arranged and in which the arc extinguishing by the flowing out of the chamber Pressurized gas is effected. The switching operations can be done pneumatically by devices can be controlled on the downstream side of the extinguishing chamber. In order to use special storage containers for such switches It is important to avoid the actuation pressure gas and thus insulating gas supply pipes also known, the actuating gas to carry out the switching operations one of the switching chamber to be taken from the separated room part. The well-known switch contains only a single interruption point, so no delayed disconnecting auxiliary contacts.

Another known pressure gas switch, which also has no auxiliary contacts, is designed so that the connection between the arcing chamber and the outside air only during the arc extinguishing is maintained so that the compressed gas consumption remains relatively small.

Compressed gas switch, the main contacts bridged by a resistor and delayed disconnecting Containing auxiliary contacts are also known. In a known switch of this type, however, the Auxiliary contacts housed in a different chamber than the main contacts. The main and auxiliary contacts are also operated by separate devices, so that this switch is structurally quite is complicated and takes up a lot of space.

The invention is intended to provide a pressurized gas switch with a pressurized gas Housing, in which separable main contacts, with the help of a delay device later separating auxiliary contacts and a control device for the contacts are arranged and in which the movable contacts are telescopically displaceable with respect to the stationary contacts and the contact actuation carried out by the compressed gas, which is simple in construction, compact and reliable. According to the invention, this is achieved in that the compressed gas switches which can be telescopically displaced relative to one another

Applicant:

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

Representative:

Dr.-Ing. E. Sommerfeld and Dr. D. v. Bezold,
Patent Attorneys, Munich 23, Dunantstr. 6th

Named as inventor:
Thellwell Russell Coggeshall,
BaIa Cynwyd, Pa. (V. St. A.)

Claimed priority:

V. St. v. America December 20, 1960

(77 145)

movable contacts are arranged between the stationary contacts on a stationary support, which two interconnected and closed by the telescopically movable contacts Contains control chambers, which by selectively connecting with the interior of the pressurized gas containing Housing or the outside air a closing or opening of the contacts under the action of the Allow surfaces of the movable contacts acting pressure of the compressed gas. In the drawings shows

Fi g. 1 is a partially sectioned side view an embodiment of the gas pressure switch according to the invention,

F i g. 2 is an enlarged view of part of FIG. 1, with the parts of the switch in the closed Position are shown,

F i g. 3 is a view similar to FIG. 2, but with the parts of the switch in the open position are shown.

The in F i g. The switch 10 shown in FIG. 1 consists of a preferably grounded metal tank 11 which is normally filled with an arc-extinguishing and insulating compressed gas, for example compressed air. Two spaced-apart bushings 14 and 15 protrude into the tank in order to establish an electrical line connection from the outside to the inside of the tank.

409 627/339

3 4

These bushings can be from any one of the holder 40 on one of the bottom of the tank 11 appropriate conventional training; they are upstanding stationary insulator rod 42, which is used to therefore described here only insofar as it serves for the holder 40 electrically from the ground and Understanding the invention is required. How to isolate from tank 11, arranged from Fig. 1, each of the feedthroughs consists of 5. As can be seen from FIG. 2 and 3, the holder 40 is of a conductor pin 16 arranged in the middle, is hollow and consists of after the two which extends through the passage and opposite ends extending cylindrical two insulator sheaths 17 and 19 of conventional training hub pieces 44 and 46. The hub piece 44 is seated dung, which the pin 16 on the roof wall of the slidable in a cylinder part of the movable main tank 11 holders. In both feedthroughs, isolate contacts 22 so that they are adjacent to the inner surface Ren the insulator sheaths the high voltage leading 50 of the moving main contact a contact conductor pin 16 is formed by the preferably grounded tank 11. Control chamber 48. The movable one The pin 16 of the right feedthrough is tubular, the main contact 22 is, more precisely, a cylindrical shape, while the pin 16 of the left penetrator piston, which can be pulled out on the cylinder guide is of massive training. 15 throat hub piece 44 is seated. Around the outer perimeter At the inner end of the conductor pin 16 on the right of the hub piece 44 is a suitable ring bushing 15, the stationary contact arrangement seal 52 is provided, thus along the outer surface nungl8 attached in a suitable manner. The arrangement of the hub piece 44 does not enter any pressurized gas into the chamber 48 opening 18 has an annular contactor part 20 which can seep into or out of the chamber 48, made of suitable arc-proof metal, which is 20 The auxiliary contact 34 has the shape of a piston a movable contact 22 can come into contact with a molded contact 22 and laterally thereof. The movable contact 22 preferably has a standing cylindrical sleeve 54. The sleeve 54 is seated a conical part 23 made of arc-proof material which can be pulled out in the hub piece 46. Inside the sleeve material, which when the contacts are closed with the contact 54 there is an auxiliary contact control chamber 56, clocking part 20 of the stationary Kontaktanord- 35 and on the outer circumference of the sleeve 54 is a suitable one is in contact. Both the stationary contact ring seal 58 are provided to prevent assembly 18 as well as the pin 16, on which they hold compressed gas along the outer surface of the sleeve 54 into the tert is tubular, so that in their chamber 56 in or out of the chamber 56 inside an outflow channel 24 is formed which seeps from the.

inner end of the stationary contact arrangement 18 30 To one the two movable contacts 22 and runs to the outer end of the pin 16. Normally ready to hold the force in its closed position if the flow of pressurized gas from the interior of the tank is to be stopped, two compression springs 60 and 62 are provided see through this outflow channel 24 through the moving. The compression spring 60 engages between the upsetting Contact 22, which, if the contacts are closed, holder 40 and the movable main console are, the inlet opening of the channel 24 seal 35 clock 22 in such a way that they on the contact 22 © ine tet, locked. However, if the contact 22 is exerted by the sta- force, which normally occurs in the in tionary contact 18 withdrawn, as shown in FIG. 3 an- F i g. 2 holds the closed position shown during is interpreted, the outflow channel 24 opens, and the compression spring 62 between the stationary holder the compressed gas can attack from the interior of the tank 11 40 and the auxiliary contact 34 in such a way that on through the channel 24 into the surrounding atmosphere 40, the auxiliary contact 34 exerts a force which flow as indicated by arrows 26 in FIG. 3 these are usually listed in the in FIG. 2 interpreted is. This flow of pressurized gas helps keep the closed position.

the contact separation between the contacts 22 The contact opening is caused by the

and 18 formed arc is extinguished, as further contact control chambers 48 and 56 via a control

will become clearer below. 45 line 65 made of insulating material to the outside air

The inner end of the other pin 16 can be opened. In the line 65 is located

suitably an additional stationary contact a control valve indicated schematically at 66, the

arrangement 30 attached. The assembly 30 has a control of the flow of pressurized gas through the conduit. That

annular contactor part 32 made of a suitable control valve 66 is preferably a three-way valve

arc-proof metal that is formed with the additional loading 50 so that when it is closed it is a

movable contact arrangement 34 comes into contact. The connection between the pressurized gas in the tank 11 and

Assembly 34 has an annular contactor which makes contact control chambers 56 and 48

part 38 made of arc-proof metal which, if this is the case, when the switch is in the position shown in FIG. 1

Contact set is closed, deal with the contact and 2 shown closed position. It will

transmitter part 32 of the stationary contact arrangement in 55 valve 66 opened, as shown in Fig. 3, so

Contact is located. it connects the contact control chambers 56 and 48

As can be seen more clearly below, via the line 65 with the outside air below, the main work of power interruption will be the timely disconnection of the connection between the Konvon contacts 18, 22. These contacts clock control chambers and the interior of the tank 11 should therefore be used as main contacts in the following via line 65.

be drawn. The other set of contacts 30, 34 is used when the valve 66 is in the position shown in FIG. 1 shown (soon to be explained, known per se) is auxiliary support, then the pressurized gas has in the contacts, which is why the contacts 30, 34 in the following as control chambers 56 and 48 have the same pressure as Auxiliary contacts are to be designated. the gas surrounding the contacts in the tank 11. Da

To hold both the movable main 65 that surface area (50) of the contact 22,

contact 22 as well as the movable auxiliary contact of the pressing in the contact closing direction

34, a stationary gas pressure is applied between these two contacts, is greater than that

rer metallic holder 40 is provided. As can be seen, the surface area of the contact 22, which is included in the

5 6

Contact opening direction pressing gas pressure bet position to the right in the in F i g. 3 shown

is served, expresses the resulting or net position.

force of the compressed gas in such a direction that when the main contacts 22, 18 move away from each other

the contact 22 is kept closed. This will loosen the arc formed between them The net force is subjected to a gas shock by the force of the spring 60 as compressed gas flows through the

complements, as it has already been described. If the arc range is in the direction of arrows 26 in

Contact control chamber 48 by opening valve F i g. 3 flows. This burst of gas is used in

66 opened to the outside air, the pressure falls ter way the arc is quickly extinguished by in

very rapidly in this chamber, so that the arc gap now has a dielectric resistance

on the right side of the contact 22 attacking io is built up, which is sufficiently dielectric strength,

Pressure predominates. This predominant pressure forces to reignite the arc after one

the contact 22 against the force of the closing spring 60 to prevent premature current zero,

to the left, whereby the movable main contact 22 The interruption process can thereby something

is separated from the stationary main contact 18. be softened in its violence that one the

Shortly after the two main contacts 22, 18 15 arc gap with a resistor 70 over have opened up in this way, those who, in a known manner, ensure that the Auxiliary contacts 34, 30 open. The force that this speed with which the normal transition opening the auxiliary contacts are caused by the voltage on the path after each current zero again Venting of the auxiliary contact control chamber 56, which is built up at, is reduced. After the light opening of the valve 66 takes place. The 20 arc broken off at the main contacts flows that is, when the chamber 56 via the line 65 for a current through the series connection of the resistor the outside air is opened, the pressure in this 70 and the auxiliary contacts 30, 34 falls via a suitable chamber from, so that now the two movable contact sets on the left side nice way of the piston 34 acting pressure predominates. Flexible conductor 72 connecting with one another. This a force is generated by the contact 34 25 resistance current is interrupted by that against the force of the closing spring 62 from the stationary the auxiliary contacts 34 and 30 in the contact described above 30 pushes off to the right. be separated in a different way. This stream since he

It is important that the movable auxiliary contact 34 is so limited by the resistor 70 is essential

remains closed for a long time until the movable one is lower than the one on the main contacts.

Main contact 22 opened a considerable distance 30 broke current. It is therefore sufficient for the deletion

Has. In some cases, this order may be that of the arc formed on the auxiliary contacts

Opening processes can be achieved by using the existing pressurized gas without a noticeable

the relative masses of the two moveable Konwerter gas shock is required.

clocks and the rela- tively acting on these contacts. As regulated by the net opening forces that are vertical with the main contacts 18, 22 or a correspondingly 35-related outflow channel 24 is dimensioned relatively. According to the preferred embodiment, a large amount of compressed gas escapes, it is essential of the invention, however, a more effective control Hch that this gas flow is stopped as soon as this opening sequence is provided in such a way that resistance current is interrupted so that an inhibiting device 82 is present in the tank, 11 there is no excessive pressure and thus the auxiliary contact 34 does not move as long as an excessive amount of gas is lost in 40. For this purpose, the closed position shown in FIG. 2 is latched within a predetermined short period of time until the movable main contact 22 has moved back into the closed position within the span of the opening of the auxiliary contacts of the movable main contact 22 over its full opening stroke. The chocking device 82 is composed of a brought to, in which it seals the discharge passage 24, a stationary pivot bearing 45 causes 84 hinged clinker ^This return movement of the movable Hauptkontakkenhebel 83, which is controlled by a suitable spring, examples tes 22 characterized in that by a in the spring 85, for example, is tensioned in a clockwise direction around its center of the auxiliary contact 34 provided opening 75 pivot point. The ratchet lever 83 pressurized gas into the contact control chamber 48 of the main carries at its free end a roller 86 which is supplied to contact 22. That is, when the first cam surface 87 is seated on the auxiliary contact 34. 50 movable auxiliary contact 34 its in F i g. When the ratchet lever 83 shown in FIG. 3 is in its position in FIG. 2 fully open position is reached, there is a locked position at the indicated, the roller 86 holds the movable auxiliary contact 34 located ring seal via the cam surface 87 the movable auxiliary 80 on the left end of one of the chamber 48 of the contact 34 closed. movable main contact protruding rigid

To disengage the ratchet lever 83 when the tube 81 is removed. This not only interrupts the connection of the opening movement of the movable manure between the chamber 48 and the line 65 which is suitably opened with outside air downstream of the main contact 22, but also the control cam 89 coupled to the contact 22 in front of the opening 75 and seen at the same time . When the main contact 22 moves into the fully open position shown in tube 81, a direct connection between the FIG. 3, 60 pressurized gas in the tank U and the chamber 48 is established, the control cam 89 on the latch lever 83. As a result, builds up Immediately in the chamber the cam follower 88, causing the pawl 48 to apply pressure, and this pressure generates a pre-lever 83 counterclockwise around its prevailing force, which pushes the movable contact 22 pivot point 84 and in this way moves it to the right into the closed position presses. As a result, the movable auxiliary contact is released 65 for opening, the outflow channel 24 is sealed and the flow is closed. Since then terminated at the movable auxiliary contact 34 of compressed gas through this channel,
an opening force is applied, as explained above. The amount of time required for the contact 34 to move out of the position shown in FIG. 2 shown- the chamber 48 a for the closure of the moving

Union main contact 22 can build up sufficient pressure is through a movable auxiliary contact 34 located dosing pin 90 regulated. When contact 34 moves to the fully open position, the metering pin 90 slides into the bore of the tube 81, so that a narrowed confluence opening is formed, which the speed with which flows through the pipe 81, the pressurized gas building up the contact closure pressure. The dispensing pen 90 is designed and dimensioned in such a way that between the point in time when the movable auxiliary contact 34 reaches the fully open position, and the point in time when the movable main contact 22 closes, a sufficient time elapses to ensure that the resistive current is passed to the Auxiliary contacts 30, 34 is interrupted before the main contacts are closed again.

During the time interval when the main moving contact closes, the moving main contact remains Auxiliary contact 34 in the in F i g. 3 open position shown because most of the auxiliary contact control chamber 56 is still in communication with the outside air via the control line 65 and therefore a the pressure from the tank 11 is applied to a sufficiently large net surface area of the auxiliary contact 34 is to keep the contact 34 open against the force of the spring 62. By being in this Manner the contacts 30, 34 are kept open, the circuit remains open as it is intended. Because the gap or the distance between the opened contacts 30 and 34 in the pressurized gas of the tank 11, the line has a dielectric strength which is sufficient, also a relative one to keep high voltage circuit open.

During the period when the contacts in the FIG. 3 are held, none is possible significant amount of gas is lost through the control line 65 as the seal 80 prevents it from coming out the pressurized areas of the actuating mechanism in this case any pressurized gas can seep into the control line 65. Furthermore, during this period, the seal 80 seals the auxiliary contact control chamber 56 against the adjacent compressed gas, so that in cooperation with the line 65 which is open to the outside air, this is ensured is that the pressure in the chamber 56 is low and thus the movable auxiliary contact 34 is open remain.

To the movable auxiliary contact 34 from the in F i g. 3 into the open position shown in FIG. 2 Due to the closed position shown, the control valve 66 is in the in F i g. 1 shown closed position brought back. This allows compressed gas from the tank 11 via the control line 65 into the chamber 56 flow. As a result of the pressure now built up in the chamber, the movable contact becomes pressed to the left and then finally into the position shown in FIG shown closed position brought.

As for the initiation of the opening of the movable main contact 22 by draining or venting the chamber 48 is concerned, it can be seen that the desired rapid venting of the chamber 48 through the metering pin 90 is not impaired, since the metering pin 90 is outside during this venting of the tube 81 is located, as can be seen from FIG. Furthermore, with regard to the contact opening process, that the draining or venting of the chamber 56 through the central opening of the auxiliary contact 34 is not significantly impaired as the aperture 75 is very small compared to the very limited area over which the venting takes place, e.g. B. the area between the fixed tube 81 and the sleeve 54 on the movable Auxiliary contact 34. Compressed gas flowing in approximately through opening 75 escapes during venting therefore via the control line 65, even before there is any in the chamber 56 during its venting can build up significant pressure.

Claims (6)

Patent claims: 1. Compressed gas switch with a housing containing a pressurized gas in which separable main contacts, with the help of a delay device later separating auxiliary contacts and a control device for these contacts are arranged, in which the movable ones Contacts are telescopically displaceable with respect to the stationary contacts and the contact is actuated by the compressed gas, characterized in that the Movable contacts (22, 34) which can be moved telescopically relative to one another between the stationary Contacts (18, 30) are arranged on a stationary carrier (40), which two together connected and closed by the telescopically movable contacts control chambers (48, 56) contains, which by selectively connecting with the interior of the pressurized gas containing Housing or the outside air a closing or opening of the contacts under the Effect of the pressure of the compressed gas acting on the surfaces of the movable contacts enable. 2. Compressed gas switch according to claim 1, characterized in that the movable main and Auxiliary contact (22 or 34) each have a first surface that is different from that in the housing (11) Gas pressure is applied in the sense of a contact opening, as well as a second surface in each case, the gas pressure prevailing in the control chambers (48 and 56) in the sense of a Closure of the contacts is applied, and that an arrangement (75, 80, 81) is provided is to at least part of the opening of the movable auxiliary contact (34) second surface of the movable auxiliary contact against the one in the one control chamber (56) Seal gas pressure and the second surface of the movable main contact (22) with to pressurize the compressed gas in the housing (11) to close the main contacts (22, 18). 3. Compressed gas switch according to claim 2, characterized in that the arrangement (75, 80, 81) a connection between the compressed gas and arranged in the movable auxiliary contact (34) in the housing (11) and the opening (75) producing a control chamber (56) and one of the two Contains control chambers (48, 56) connecting tube (81), at one end of which the movable auxiliary contact (34) is in its open position in such a way that one chamber (56) against the opening (75) in the movable auxiliary contact (34) sealed (80) and the other Control chamber (48) via the pipe (81) and the opening (75) with the compressed gas in the housing (11) connected is. 4. Compressed gas switch according to claim 2 or 3, characterized in that the movable Auxiliary contact (34) a throttle pin (90) to influence the speed at which the Pressurized gas flows against the second surface of the main movable contact (22), carries. 5. Compressed gas switch according to one of the preceding claims, characterized in that that the stationary main contact (18) within the housing (11) on an outlet channel (24) is arranged for the housing forming hollow conductor leadthrough (15) and that the associated movable contact (22) seals the outlet channel (24) in its closed position. 6. Compressed gas switch according to one of the preceding claims, characterized by a Ratchet device (82) comprising a cam follower cooperating with a cam (89) (88) which disengages the movable auxiliary contact (34) with a delay when the movable Main contact (22) moved to its open position. Considered publications:
German Patent No. 647141;
British Patent Nos. 769 831, 770100. 1 sheet of drawings 409 627/339 6.6+ © Bundesdruckerei Berlin