EP0731482A2 - Circuit breaker - Google Patents

Abstract

This circuit breaker has a power current path and an arcing chamber (1) filled with an insulating medium. One movable (2) and one fixed contact piece (3) is arranged in the power circuit. Furthermore, in the arcing chamber (1) at least one blow coil (22), which is acted upon by current at least temporarily, is provided and a blow volume (9) which stores the increased pressure of the insulating medium that occurs during a switch-off process.

A circuit breaker is to be created in which an excessive pressure rise in the blowing volume is avoided with simple means. This is achieved in that the at least one blow coil (22) is designed to be fully or partially short-circuited and that means are provided which enable this short-circuiting.

Description

The invention is based on a circuit breaker according to the preamble of claim 1.

STATE OF THE ART

A circuit breaker is known from US Pat. No. 2,333,598, which uses compressed air as an insulating medium and as a switching gas. This circuit breaker has an arcing chamber which is provided with a blow coil which is activated when it is switched off and which then applies an axial magnetic field to the cylindrical arc zone in a known manner. This magnetic field causes the arc to rotate. The rotating arc heats the gas in the arc zone so that an increase in pressure occurs in this area, the pressure-applied gas thus obtained is stored in a blowing volume. The blowing volume is designed so large that it can absorb the highest possible pressures with this circuit breaker and store it until the arc blowing begins. If comparatively large currents with long arcing times are switched off, it is possible that a significantly higher pressure is generated than is ultimately required to extinguish the arc. However, the blowing volume must be designed for these highest possible pressures, whereby the circuit breaker is unnecessarily enlarged and thus also more expensive.

PRESENTATION OF THE INVENTION

The invention, as characterized in the independent claims, solves the problem of creating a circuit breaker in which an excessive increase in pressure in the blowing volume is avoided with simple means.

The advantages achieved by the invention can essentially be seen in the fact that the wall of the blowing volume is mechanically overloaded with a high degree of certainty. The volume of the blowing volume can thus be selected to be optimally small, and with it the dimensions of the arcing chamber can also be advantageously kept small, so that an advantageously space-saving and inexpensive circuit breaker can be created. The limitation of the pressure rise means that the gas temperature is also limited upwards, thereby avoiding that the density of the pressurized gas is reduced inadmissibly. If an optimal pressure rise is set, the extinguishing capacity of the circuit breaker is advantageously increased.

The further developments of the invention are the subject of the dependent claims.

The invention, its further development and the advantages which can be achieved thereby are explained in more detail below with reference to the drawing, which only represents one embodiment.

BRIEF DESCRIPTION OF THE DRAWING

• Fig.1 einen ersten, stark vereinfachten Teilschnitt durch eine erste Ausführungsform eines erfindungsgemässen Leistungsschalters mit eingeschalteter Löschkammer,
• Fig.2 einen zweiten, stark vereinfachten Teilschnitt durch die erste Ausführungsform des erfindungsgemässen Leistungsschalters mit einer kurz nach der Kontakttrennung beim Abschalten dargestellten Löschkammer,
• Fig.3 einen dritten, stark vereinfachten Teilschnitt durch die erste Ausführungsform des erfindungsgemässen Leistungsschalters mit einer in Ausschaltposition mit noch brennendem Lichtbogen dargestellten Löschkammer,
• Fig.4 einen stark vereinfachten Teilschnitt durch eine zweite Ausführungsform des erfindungsgemässen Leistungsschalters, und
• Fig.5 einen stark vereinfachten Teilschnitt durch eine dritte Ausführungsform des erfindungsgemässen Leistungsschalters.

Show it:

• 1 shows a first, greatly simplified partial section through a first embodiment of a circuit breaker according to the invention with the arcing chamber switched on,
• 2 shows a second, greatly simplified partial section through the first embodiment of the circuit breaker according to the invention with an arcing chamber shown shortly after the contact separation when switching off,
• 3 shows a third, greatly simplified partial section through the first embodiment of the circuit breaker according to the invention with an arcing chamber shown in the open position with the arc still burning,
• 4 shows a greatly simplified partial section through a second embodiment of the circuit breaker according to the invention, and
• 5 shows a greatly simplified partial section through a third embodiment of the circuit breaker according to the invention.

Elements with the same effect are provided with the same reference symbols in the figures. All elements not necessary for the immediate understanding of the invention are not shown.

WAYS OF CARRYING OUT THE INVENTION

1 shows a first, greatly simplified partial section through a first circuit breaker according to the invention. This circuit breaker has a quenching chamber 1 filled with an insulating medium movable contact piece 2 and a fixed contact piece 3, which are connected to one another in an electrically conductive manner by a sliding contact arrangement 4 in the switched-on state. SF ₆ gas is very often used as the insulating medium. Both the movable contact piece 2 and the fixed contact piece 3 can have central bores. The sliding contact arrangement 4 is indicated here, for example, by contact fingers, which are held together by a holder, not shown, to form a type of contact tulip. The movable contact piece 2, the sliding contact arrangement 4 and the fixed contact piece 3 together form the power current path of the quenching chamber 1. The power current path extends along an axis 5, which at the same time is the axis of the quenching chamber 1, which is generally cylindrical. Of the quenching chamber 1, which is filled with an electrically insulating medium under pressure, such as SF ₆ gas, the housing enclosing it and also the drive moving the contact piece 2 are not shown.

The movable contact piece 2 penetrates an electrically conductive race 6, which surrounds it concentrically. The race 6 is positioned by an electrically insulating holder 7. The race 6, the electrically insulating holder 7 and a wall 8 indicated only by a line enclose a blowing volume 9 concentrically surrounding the movable contact piece 2. On the side of the blow volume 9 opposite the race ring 6, this is sealed by means of a sealing ring 10 embedded in the wall 8 against the moving contact piece 2 passing through. At least one piston-cylinder arrangement 11, which has a cylinder 12 and has a piston 13 sliding in it. The piston 13 is guided by elements not shown, and an effective stroke limitation is also provided, so that the piston 13 cannot be moved too far in the direction of the blowing volume 9. The piston 13 is with a piston rod 14 which is provided for the actuation of a schematically illustrated auxiliary switch 15. In the present exemplary embodiment, the auxiliary switch 15 is shown as a closer, the contact bridge 16 of which can be moved in the closing direction by the piston 13 with the piston rod 14. The auxiliary switch 15 has two contacts 17, 18, which are connected to one another in an electrically conductive manner by the contact bridge 16 in the closed state. When the piston 13 moves in the closing direction of the auxiliary switch 15, the force of a prestressed spring 19 counteracts this movement.

The race 6 is connected by means of an electrically conductive connection 20 to a first turn 21 of a blow coil 22, for example a single-layer design. Only the cross sections of the individual windings of the blow coil 22 are shown here, the insulation of the windings and their bracing required because of the high dynamic current forces are not shown. The blow coil 22 can be made in one or more layers. The other end of the blow coil 22 is electrically conductively connected to the fixed contact piece 3. The first turn 21 is also connected to the contact 18 of the auxiliary switch 15. The contact 17 of the auxiliary switch 15 is connected to the fixed contact piece 3 by an electrically conductive connecting line 23. A plurality of piston-cylinder arrangements 11 and correspondingly assigned auxiliary switches 15 together with the associated electrically conductive connections can be provided in the arcing chamber 1. Through a schematically illustrated connection 24, which is provided with a sliding contact 25, current flows, as indicated by an arrow 26, into the movable contact piece 2 of the power current path. In this switched-on position of the quenching chamber 1, the current continues to flow through the sliding contact arrangement 4 and the fixed contact piece 3 to a further connection 27, where the current, as indicated by a further arrow 28, the quenching chamber 1 leaves. The blow coil 22 is not supplied with a current.

2 shows a second, greatly simplified partial section through the first circuit breaker according to the invention, in whose quenching chamber 1 the contact piece 2 which is movable in the direction of an arrow 29 has just moved out of the sliding contact arrangement 4. During this contact separation, an initially comparatively short arc 30 was drawn, the one base point of which initially burned briefly on the sliding contact arrangement 4 commutated very quickly onto the race 6. The other base point of the arc 30 burns on the movable contact piece 2. After commutation of the arc 30, current no longer flows through the sliding contact arrangement 4. The current now flows from the movable contact piece 2 through the arc 30 into the race 6 and from there through the connection 20, the blow coil 22 and an electrically conductive connection 31 into the fixed contact piece 3. Accordingly, a new current path was activated by commutation. An arrow 32 indicates the current flow through this current path. With the further movement of the movable contact piece 2 in the direction of the arrow 29, the distance between the movable contact piece 2 and the race 6 increases, the arc 30 also being lengthened at the same time. The current-carrying blow coil 22 generates an axial magnetic field, which acts on the arc 30 and sets it in rotation about the axis 5.

3 shows a third, greatly simplified partial section through the first circuit breaker according to the invention, in whose quenching chamber 1 the movable contact piece 2 is in the switch-off position while the arc 30 is still burning. The arc 30 has in the meantime generated such a high gas pressure in the blow volume 9 that the pistons 13 of the piston-cylinder arrangements 11 are moved outward from the blow volume 9 against the force of the springs 19. If the for the piston-cylinder arrangements 11 predetermined maximum response pressure is reached, the contact bridges 16 connected to the pistons 13 close the auxiliary switches 15. With this closing, the blow coil 22 is short-circuited, so that no more current flows through it and the connection 31, which also means that until this moment, the axial magnetic field acting on the arc 30 is switched off. The current now flows through the closed auxiliary switch 15 and the connecting line 23 directly to the fixed contact piece 3, as indicated by an arrow 33.

4 shows a greatly simplified partial section through a second circuit breaker according to the invention. The position of the movable contact piece 2 corresponds to the position shown in Fig.2. The blow coil 22 has a tap 34 which is connected to the contact 18 of the auxiliary switch 15 via an electrically conductive connection 35. The direct connection between the first turn 21 of the blow coil 22 and the contact 18 is omitted in this embodiment.

5 shows a greatly simplified partial section through a third circuit breaker according to the invention. The position of the movable contact piece 2 corresponds to the position shown in Figure 3. The structure of the power circuit, the blow volume 9, the race 6 and the blow coil 22 corresponds in this embodiment to the structure of the first circuit breaker variants. The auxiliary switch 15 is here provided with a magnetic release 36. The blow volume 9 is also provided with a pressure sensor 37. The pressure sensor 37 works together with an evaluation unit 38 which monitors the signal delivered by the pressure sensor 37. When the evaluation unit 38 determines that a predetermined maximum pressure in the blow volume 9 has been exceeded, it generates a trigger signal which is amplified in an output amplifier of the evaluation unit 38.

This amplified trigger signal then passes through a control line 39 into the magnetic release 36, excites it and the auxiliary switch 15 closes and thus short-circuits the blow coil 22. Another control line 40 also leads into the magnetic release 36. The control line 40 is connected to a higher-level system control system, so that the auxiliary switch 15 can also be actuated independently of the pressure in the blow volume 9 if this should be necessary.

In addition to the design variants described, a large number of other circuit breaker designs are also possible. It is also possible, in particular, if a circuit breaker has to interrupt predominantly comparatively small currents, to couple the movable contact piece 2 to an additional piston-cylinder arrangement in which the insulating medium is compressed in a known manner and then either directly into the area of the arc is blown in or introduced into the blowing volume 9 via a check valve. Furthermore, it is also possible to arrange a nominal current path parallel to the power current path in order to protect the nominal current contacts from the effects of the arc and any commutation arcs. Such a separate nominal current path is particularly advantageous for circuit breakers with a comparatively large nominal current carrying capacity. It is also possible to short-circuit the blow coil 22 depending on the stroke of the arcing chamber.

To explain the mode of operation, the figures are now considered in more detail. 1 shows the quenching chamber 1 in the closed state, the alternating current to be interrupted flows through the power current path that extends between the two connections 24 and 27, this current is indicated by the arrows 26 and 28. If the circuit breaker receives an opening command from a higher-level system control system or a protective relay, the moves Switch drive the movable contact piece 2 in the switch-off direction, in Fig.2 this direction is indicated by the arrow 29. As soon as the movable contact piece 2 loses electrical contact with the sliding contact arrangement 4, an arc 30 arises, one of which, initially briefly burning on the sliding contact arrangement 4, commutes very quickly onto the race 6. The other base point of the arc 30 burns on the movable contact piece 2. After commutation of the arc 30 on the race 6, no current flows through the sliding contact arrangement 4. The entire current now flows from the movable contact piece 2 through the arc 30 into the race 6 and from this further through the connection 20, the blow coil 22 and an electrically conductive connection 31 into the fixed contact piece 3. Accordingly, a new current path was activated by the commutation, through which the entire current to be switched off flows. The blow current 22 through which current flows now generates an axial magnetic field, which acts on the arc 30 and rotates it around the axis 5 of the arcing chamber 1. An arrow 32 indicates the current flow through this new current path. With the further movement of the movable contact piece 2 in the direction of the arrow 29, the distance between the movable contact piece 2 and the race 6 increases, the arc 30 also being lengthened at the same time.

Due to the arc energy, which increases with the length of the arc, the electrically insulating gas located in the region of the rotating arc 30 is heated, as a result of which the pressure in this zone increases. The stronger the axial magnetic field, the faster the arc 30 rotates and the more intense the heating and thus the pressure increase of the gas. The gas under pressure flows into the blowing volume 9, the pressure in the blowing volume 9 also increases. However, part of the pressure generated in this way can already flow out through the inner bore of the fixed contact piece 3, especially when the current to be switched off has a zero crossing. If the movable contact piece 2 also has a central bore, a gas flow can already build up through this. As a rule, however, this area is designed such that a predominant portion of the pressurized gas is stored in the blowing volume 9. This gas stored there is then used for blowing the arc 30, which then takes effect when the current to be switched off goes to zero.

In the case of very high-current shutdowns, for example if a short circuit in the network has to be shut down, or in the case of shutdowns with comparatively long arcing times, it can happen that the pressure in the blow volume 9 exceeds a predetermined maximum response value. In this case, the pistons 13 of the piston-cylinder arrangements 11 are moved in the direction of an arrow 41, as shown in FIG. 3, since the compressive forces in the blow volume 9 are so great that they overcome the oppositely directed force of the springs 19. The result of this is that the contact bridge 16 closes the auxiliary switch 15, so that the current to be switched off commutates away from the current path through the blow coil 22 onto the current path through the connecting line 23. After this commutation, the blow coil 22 is short-circuited and the axial magnetic field no longer exists. The absence of the axial magnetic field means that the arc 30 no longer rotates, so that the intensity of the heating of the gas and thus also the intensity of the pressure generation is greatly reduced. As a result, the pressure in the blow volume 9 does not increase any further, so that the pressure load on the wall 8 of the blow volume 9 is limited. The wall 8 therefore only needs to be designed for comparatively low pressures. In addition, the dimensions of the blowing volume 9 can be kept comparatively small, since no additional volume reserve is required in order to be able to absorb any excessively high pressures.

Such circuit breakers are used in a wide variety of networks and under completely different operating conditions. It is therefore quite possible that a complete short-circuiting of the blow coil 22 would result in an excessively low gas pressure in the blow volume 9, as a result of which the deactivation capacity of the arcing chamber 1 would be reduced. In this case, as shown in FIG. 4, the blow coil 22 can be provided with a tap 34, so that only part of the blow coil 22 is short-circuited when the auxiliary switch 15 is closed. As a result, the first turn 21 and the turns following up to the tap 34 remain effective. The partial short-circuiting in this case has the effect that the axial magnetic field is somewhat weakened, as a result of which the speed of rotation of the arc 30 and thus also the pressure generation is reduced . The number of remaining effective turns can now be optimized in such a way that, in the case of switch-off cases that are critical in this case, a sufficiently large blowing pressure is always provided in the blowing volume 9, so that an intensive blowing of the arc 30 is ensured even in the event of longer arcing times. This version of the circuit breaker can be used particularly advantageously in networks with a 16 2/3 Hz network frequency.

In the embodiment according to FIG. 5, the pressure in the blow volume 9 is measured by means of the pressure sensor 37, further processed electronically and, if necessary, when a predetermined threshold value is exceeded, the magnetic trigger 36 is actuated, which closes the auxiliary switch 15 and thus short-circuits the blow coil 22 prompted. This version has a minimum of moving parts to be maintained, so that its operational availability is advantageously large.

It can also prove to be advantageous, for example if a higher-level system protection detects an extremely high short-circuit current, the blow coil 22 regardless of the pressure as a precautionary short-circuit in the blowing volume 9. In this case, an arc 30 of such intensity is to be expected that only the energy of the non-rotating arc 30 is sufficient to generate a sufficiently high blowing pressure in the blowing volume 9. The control line 40 in FIG. 5 indicates this possibility of short-circuiting, triggered for example by system protection.

In vacuum interrupters, which in particular tend to cut off small inductive currents, which leads to undesirably high overvoltages in the network, the use of fully or partially short-circuitable blow coils is particularly advantageous since the switching behavior of these tubes can be optimized in a simple manner.

LIST OF DESIGNATIONS

1

Arcing chamber

2nd

movable contact piece

3rd

fixed contact piece

4th

Sliding contact arrangement

5

axis

6

Race

7

electrically insulating bracket

8th

wall

9

Blowing volume

10th

Sealing ring

11

Piston-cylinder arrangement

12th

cylinder

13

piston

14

Piston rod

15

Auxiliary switch

16

Contact bridge

17.18

contacts

19th

feather

20th

connection

21

first turn

22

Blow coil

23

Connecting line

24th

connection

25th

Sliding contact

26

arrow

27

connection

28.29

arrow

30th

Electric arc

31

connection

32.33

arrow

34

Tap

35

connection

36

Magnetic release

37

Pressure sensor

38

Evaluation unit

39.40

Control line

41

arrow

Claims (7)

Circuit breaker with at least one quenching chamber (1) having a power current path and filled with an insulating medium, with a movable contact piece (2) arranged in the power current path and with a fixed contact piece (3), with at least one blow coil (22) at least temporarily energized by current , with a blowing volume (9) which stores the increased pressure of the insulating medium occurring during a switch-off process, characterized in that - That the at least one blow coil (22) is fully or partially short-circuitable, and - That means are provided which enable this short-circuiting. Circuit breaker according to claim 1, characterized in - That the short-circuiting takes place depending on the pressure of the insulating medium in the blowing volume (9). Circuit breaker according to claim 2, characterized in - That the short-circuiting takes place only after a predetermined pressure of the insulating medium in the blowing volume (9). Circuit breaker according to claim 3, characterized in - That at least one piston-cylinder arrangement (11) acted upon by the pressure of the insulating medium in the blowing volume (9) is provided as a means for short-circuiting, which acts on an auxiliary switch (15). Circuit breaker according to claim 3, characterized in - That the means for short-circuiting comprise at least one pressure sensor (37) measuring the pressure of the insulating medium in the blow volume (9), an evaluation unit (38) interacting with it and a magnetic release (36) actuated by the evaluation unit (38). Circuit breaker according to claim 1, characterized in - That the blow coil (22) can be short-circuited regardless of the pressure in the blow volume (9). Circuit breaker according to claim 6, characterized in - That the short-circuiting of the blow coil (22) can be triggered by a system protection.

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