WO2005062330A1 - Quenching chamber and heavy-duty circuit breaker with powerful arc blow-out - Google Patents

Abstract

The invention relates to a quenching chamber for a heavy-duty circuit breaker, which is filled with a quenching gas, said chamber comprising a first contact part (1) and a second contact part (2), at least one of said parts being displaceable. During a tripping operation, an electric arc (4) that is to be quenched is formed between the two contact parts (1,2) in a quenching zone (3). The chamber is equipped with a heating volume (5) for receiving the quenching gas that is heated by the electric arc (4), said volume being used to blow out the electric arc (4) and a first compression volume (7), which is positioned in such a way that it decreases in size during a tripping operation, allowing quenching gas to be conducted from said first compression volume (7) into the quenching zone (3). The chamber is also provided with a second compression volume (8) and an expansion volume (10) that is separate from the first (7) and second compression volume (8). Said expansion volume (10) is located in such a way that when the total volume of the first (7) and second compression volume (8) increases, its volume decreases and when the total volume of the first (7) and second compression volume (8) decreases, its volume increases. The first (7) and second compression volume (8) are interconnected via an inflow channel (9) that extends longitudinally parallel to an axis (A) of the quenching chamber. The expansion volume (10) is connected to an outflow channel (13) and/or a reservoir volume (17). The invention permits an improved electric arc blow out, in particular using clean quenching gas.

Description

 EXTINGUISHING CHAMBER AND HIGH PERFORMANCE SWITCH WITH STRONG LIGHT BOC BLOWING UNC

DESCRIPTION

Technical field

The invention relates to the field of high-performance switch technology. It relates to an arcing chamber according to the preamble of claim 1 and a corresponding high-performance switch.

State of the art

Such an arcing chamber and a corresponding high-performance switch are known, for example, from published patent application DE 1 95 36 673 AI. This switch has at least one cylindrical quenching chamber which is provided with a fixed contact, with a movable contact and with an extinguishing zone between the two contacts. A shaft of the movable contact is firmly connected to a heating volume which is closed on the fixed contact side by an insulating nozzle penetrated by at least one heating channel. The quenching chamber has a first compression volume, which is operatively connected to the heating volume and a second compression volume. Between The first and the second compression volume are provided with a movable auxiliary piston which is connected to the movable contact via a deflection device. During a switch-off process, the auxiliary piston is moved antiparallel to the direction of movement of the movable contact piece, so that the first compression volume is initially compressed, while the second compression volume sucks in clean extinguishing gas. The auxiliary piston is then moved parallel to the direction of movement of the movable contact piece, so that the first compression volume is supplied with clean extinguishing gas from the second compression volume. This will strengthen

Blowing of the arc, especially with relatively clean quenching gas, reached.

The high-performance switch described has the disadvantage that it requires a deflection device to achieve the relatively complicated auxiliary piston movement.

Presentation of the invention

It is therefore an object of the invention to provide an arcing chamber and a high-performance switch of the type mentioned, which do not have the disadvantages mentioned above. In particular, strong blowing of the arc and thus a more reliable switching, even in difficult switching cases, are to be achieved, without the need for a deflection device. In addition, the blowing should take place using as clean a gas as possible. This object is achieved by a device and with the features of the independent claim.

The quenching chamber according to the invention for a high-performance circuit breaker is filled with an extinguishing gas and has:

a first contact piece and a second contact piece, at least one of which is a movable contact piece and which are movable relative to one another by means of a drive,

- An extinguishing zone arranged between the two contact pieces, in which an arc between the two during a switch-off process

Contact pieces can be trained, and

- A heating volume for receiving quenching gas heated by the arc, by means of which the arc can be blown, a first compression volume being present which is arranged in such a way that it is reduced during a switch-off process, so that quenching gas is conducted from the first compression volume into the quenching zone will, and

- a second volume of compression.

It is characterized in that there is an expansion volume arranged separately from the first and the second compression volume, which is arranged in such a way that when the total volume of the first and the second compression volume increases, its volume decreases and when the total volume of the first and the second compression volume increases its volume.

The expansion volume allows an effective enlargement of the extinguishing gas available for blowing the arc, which is located in the two compression volumes. Because the total volume formed by the two compression volumes does not have to be constant, but can decrease during a switch-off process in favor of the expansion volume. The expansion volume can advantageously be connected to a reservoir volume (tank volume) or an outflow channel, so that an increase in the expansion volume during a switch-off process does not represent any appreciable additional load for a drive that drives the movable contact piece.

In an advantageous embodiment, the expansion volume and the second compression volume are arranged in such a way that a volume change in the second compression volume brings about an opposite, equal volume change in the expansion volume. As a result, the expansion volume and the second compression volume can share the same space (the same total volume), and a piston of a piston-cylinder arrangement including the expansion volume can be identical to a piston of a piston-cylinder arrangement including the second compression volume. This enables a simple construction of the arcing chamber. And the arcing chamber can have a small construction volume.

In a further advantageous embodiment, the first compression volume is connected to the second compression volume by an inflow channel. Particularly advantageously, the quenching chamber has an axis, and the first compression volume is connected to the second compression volume by an inflow channel which extends parallel to the axis. As a result, the two compression volumes can be arranged one behind the other with respect to the axis, which enables a slim design of the quenching chamber (small construction volume of the quenching chamber). In addition, the volume occupied by the inflow channel is small if it is elongated is designed so that, for a given quench chamber volume, the amount of gas available for blowing by compression of the compression volumes can be large.

A pressure control valve is advantageously arranged in the inflow channel to open the inflow channel if there is a pressure p ₂ in the second compression volume which is greater than a pressure pi in the first compression volume by at least a predeterminable pressure difference Δp and otherwise to close the inflow channel. As a result, two different pressures can be realized in the two compression volumes. A two-stage and partially prolonged blowing of the arc can thereby be achieved. This also enables improved mixing of clean and contaminated extinguishing gas to be achieved.

In a particularly advantageous embodiment, at least one of the contact pieces is penetrated by an outflow channel, and the expansion volume is connected to the outflow channel. This makes it possible for quenching gas heated by the arc in the quenching zone to reach the expansion volume through the outflow channel and thus simplify the expansion volume expansion during a switch-off process. In this way, drive support is achieved: the energy to be expended by a drive driving the movable contact piece can be reduced by the extinguishing gas flowing into the expansion volume, which in the

Expansion volume presses against the piston of a piston-cylinder arrangement ending the expansion volume. If this piston is at the same time the piston of a piston-cylinder arrangement containing the second compression volume, the piston represents a differential piston. In addition, this is the expansion volume absorbed gas contaminated quenching gas, so that gas of greater cleanliness is available for arc blowing during further switching operations. Opening the expansion volume to the outflow channel can also prevent the formation of negative pressures in the expansion volume if it is enlarged during a switch-off process. Such a vacuum would lead to an additional load on the drive.

The quenching chamber advantageously has a reservoir volume (tank volume) and the expansion volume is connected to the reservoir volume. As a result, clean extinguishing gas can be sucked into the expansion volume and / or extinguishing gas, in particular contaminated extinguishing gas, can be released from the expansion volume into the reservoir volume. Opening the expansion volume to the reservoir volume can prevent the formation of negative pressures in the expansion volume. The reservoir volume is typically contained in an insulating arcing chamber housing.

In the event that the expansion volume is connected to both the outflow channel and the reservoir volume, a valve is particularly advantageously provided for closing the connection between the expansion volume and the outflow channel during a switch-on process and for opening the connection between the expansion volume and the outflow channel a switch-off process. In this way, contaminated extinguishing gas is absorbed by the expansion volume during a switch-off process and released to the reservoir volume during a switch-on process. In this way, contaminated extinguishing gas is effectively removed from the extinguishing zone with each switching cycle, as a result of which the extinguishing chamber has a permanently good switching effect. The valve can advantageously be sleeve-shaped (sleeve valve), advantageously such that it on a cylindrical outflow pipe containing the outflow channel. The valve can, for example, be designed such that it can be switched by pressure differences, or that it can be switched as a function of the drive movement.

In the event that the expansion volume is connected both to the outflow channel and to the reservoir volume, a valve is particularly advantageously provided for closing the connection between the expansion volume and the reservoir volume during a switch-off process and for opening the connection between the expansion volume and the reservoir volume a switch-on process. This ensures the effect of the differential piston described above.

The two valves mentioned are particularly advantageous.

In a particularly preferred embodiment, the piston of the piston-cylinder arrangement containing the second compression volume is rigidly connected to the movable contact piece. This is a particularly simple and robust realization of the movement of this piston. In this way, a gear-free and link-free drive of the piston can be achieved. This piston and the piston of the piston-cylinder arrangement containing the second compression volume advantageously show movements which are rectified and possibly also of the same size. The piston of the piston-cylinder arrangement containing the second compression volume is also advantageously rigidly connected to the movable contact piece.

In an advantageous embodiment, the heating volume is identical to the first compression volume. In this way, a buffer switch is essentially realized. This has a very good switching ability. In another advantageous embodiment, a reheating valve is arranged between the heating volume and the first compression volume for separating the first compression volume from the heating volume in the event that there is a pressure PH in the heating volume which is greater than a pressure pi in the first compression volume, and for connecting the heating volume to the first compression volume if there is a pressure PH in the heating volume which is less than a pressure pi in the first compression volume. An auto-blow switch is thereby essentially realized. This advantageously has the pressure control valve mentioned above. An auto blow switch can be switched with low drive energy, so it only requires a small drive.

A high-performance switch according to the invention contains an arcing chamber according to the invention and has the corresponding advantages. Such a high-performance switch can be gas-insulated (arranged in an extinguishing gas-filled earthed chamber) or can also be designed as an outdoor switch (with a shield on the extinguishing chamber housing). If the high-performance switch is gas-insulated, a quenching chamber housing can optionally be dispensed with, the reservoir volume of the quenching chamber then being identical to a reservoir volume of the gas-insulated high-performance switch. An arcing chamber according to the invention can of course also be used in combination with other interruption units or switches, for example with a vacuum switch, in a high-performance switch.

Further preferred embodiments and advantages emerge from the dependent patent claims and the figures. Brief description of the drawings

The subject matter of the invention is explained in more detail below on the basis of preferred exemplary embodiments which are illustrated in the accompanying drawings. They show schematically:

1 shows a sectional area through a high-performance switch according to the invention as a buffer switch, open at the top, closed in the bottom;

2 shows a sectional area through a high-performance switch according to the invention as an auto-blow switch, open at the top and closed at the bottom;

The reference symbols used in the drawings and their meaning are summarized in the list of reference symbols. Basically, the same or equivalent parts are provided with the same reference numerals in the figures. The exemplary embodiments described are examples of the subject matter of the invention and have no restrictive effect.

Ways of Carrying Out the Invention

Fig. 1 shows schematically a partial section through a quenching chamber according to the invention, which is advantageously used in a buffer switch. The upper half, marked 0, shows the open state, the lower half, marked C, the closed switching state. The quenching chamber is essentially rotationally symmetrical and has an axis A. The quenching chamber contains an extinguishing gas, for example SFβ or possibly also N ₂ , advantageously under pressure, and is enclosed here by an electrically insulating quenching chamber housing 16 which contains a reservoir volume 17. The housing 16 is typically closed at both ends by metal connecting flanges, not shown. If the circuit breaker is used in a metal-encapsulated gas-insulated high-voltage system, the housing 1 6 may be dispensed with; in this case the metallic encapsulation of the high-voltage system could limit the arcing chamber. A nominal current path that is usually present is not shown for the sake of clarity.

The arcing chamber has an electrically conductive first fixed contact 1 and an electrically conductive movable contact 2. With certain circuit breaker types, however, it is possible for the contact 1 to also be designed to be movable. In the closed state, the movable contact 2 rests resiliently on the fixed contact 1 with its end facing the fixed contact 1. The movable contact 2 has a cylindrically shaped metallic shaft which extends in the opposite direction to the fixed contact 1 and forms an outflow pipe 1 2 which contains a cylindrically shaped outflow channel 1 3 on the inside. The movable contact 2 makes a movement along the axis A during a switching movement. It is driven by a drive, not shown.

If the two contact pieces 1, 2 are separated from one another by means of the drive (switch-off process), an arc 4 is formed between them, which heats and contaminates the gas present in an extinguishing zone 3 arranged between the contact pieces 1, 2. This gas can Escape between an insulating nozzle 1 la and the fixed contact 1, the gas can also expand in the direction away from the fixed contact 1 in the outflow channel 1 3, and it can escape through a heating channel 6, which is formed by a space between the insulating nozzle 1 la and an auxiliary nozzle 1 1 b arranged on the movable contact piece 2.

The movement of the nozzles 1 1 a, 1 1 b and the movement of a piston K2 are also coupled to the movement of the second contact piece 2. The coupling between movable contact 2 and insulating nozzle 1 l a is illustrated by a line of action 23. In the case shown, these couplings have a mechanical rigid coupling. However, transmissions can also be interposed, for example. In places where there is mutual contact between moving and stationary parts (or between differently moving parts), pressure-tight bearings are to be provided, which can be carried out in one of the known ways and are illustrated by black circles.

A first compression volume 7, which in the illustrated case is equal to a heating volume 5, is reduced by the drive. The first compression volume 7 has an annular cylinder base B1, cylinder walls ZI and an annular piston Kl. The latter is formed in the illustrated embodiment by the insulating nozzle 1 1 a. In general, an embodiment of insulating nozzle 1 l a and piston K 1 as separate, preferably adjacent parts is preferred.

A second piston-cylinder arrangement, consisting of the second, annular piston K2, a second, annular cylinder bottom B2 and cylinder walls Z2, contains a second compression volume 8 Compression volume reduced. The first and second compression volumes 1, 2 are connected to one another via an inflow channel 9. Extinguishing gas, which is pressed into the inflow channel 9 when the compression volume 8 is reduced, is previously deflected at the bottom B2. The excess pressure resulting from the compression of the extinguishing gas present in the two compression volumes 1, 2 is reduced by the heating duct 6 and in this way serves to blow the arc 4, which is thereby extinguished. The amount of gas available for arc quenching is thus determined by the amount of gas that is made available by the two compression volumes 7, 8 together.

The two compression volumes 7, 8 are arranged one behind the other with respect to the axis A, as a result of which a slim design of the arcing chamber is achieved. The length of an arcing chamber is generally a maximum provided for the arcing chamber

Given voltage that exists between the contact pieces. In order to achieve an advantageously small construction volume, a small arcing chamber diameter, as is achieved by arranging the two compression volumes 7, 8 in series, is desirable.

The movement of the second piston K2 also changes a third volume, which is referred to as the expansion volume 1 0. The expansion volume 10 is arranged in a third piston-cylinder arrangement, which is formed by a third piston K3, which is identical here to the second piston K2, and a third cylinder base B3, which is essentially formed by the cylinder base B1, and of third cylinder walls Z3, which are essentially identical to the cylinder walls Z2. A change in volume of the second compression volume 8 results in an opposite change in volume of the expansion volume 1 0, which also in the case shown Amount is the same. The expansion volume 10 shares with the second compression volume 8 essentially the same physical space.

In the embodiment shown, the expansion volume 1 0 is opened towards the outflow channel 1 3 by means of a connecting opening 1 4. It is formed, for example, by one or more openings in the outflow pipe. During a switch-off process, gas, in particular contaminated gas, can flow through the connection opening 14 from the outflow channel 13 into the expansion volume 10. This not only ensures that there is no negative pressure in the expansion volume 1 0, which would put an additional load on the drive, but drive support can even be achieved by the heated gas flowing out of the extinguishing zone 3 and flowing into the expansion volume 10. In addition, an improved blowing is achieved because gas is sucked out of the quenching zone 3 through the connecting opening 1, whereby contaminated gas is sucked out of the quenching zone 3 and more gas for blowing the arc 4 can flow through the heating channel 6 into the quenching zone.

In general, at the end of the outflow channel 1 3 facing away from the first contact piece 1, 2 openings in the outflow pipe 1, reservoir volume 1 7 are provided. If the connection opening 1 4 is present, these can be dimensioned smaller or possibly omitted entirely, as a result of which improved drive support can be achieved.

In addition, in the embodiment according to FIG. 1, an outflow opening 15 is also provided, which connects the expansion volume 10 to the reservoir volume 17 and which is channel-shaped as an outlet channel 15. There are typically several such channels crossing the inflow channel 9 and forming the outlet channel 15. During a switch-off process, contaminated gas can be expelled from the expansion volume 10 into the reservoir volume 17 through the outlet channel 15. The expansion volume 1 0 serves as an exhaust volume and the outflow opening 1 5 serves as an exhaust.

The outflow opening 15 can be provided in addition or as an alternative to the connecting opening 14. By appropriate dimensioning of the outflow opening 15 and the connecting opening 14, the gas flows into the expansion volume 10 and out of it can be regulated, so that for example more or less

Drive support is achieved by the gas flow or an increased emission of contaminated gas into the reservoir volume 1 7.

During a switch-on process, the contact piece 2 and the three pistons K1, K2, K3 move in such a way that the compression volumes 7, 8 increase and the expansion volume 1 0 decrease. Clean quenching gas can advantageously be sucked into the compression volumes 7, 8 through an inlet valve 22, so that clean gas for the arc blowing is available for a later switch-off process. This valve 22, like the others in FIGS. 1, 2 shown valves, shown schematically through openings that can be covered by means of a valve disc, usually also a stop limiting the stroke of the valve disc is shown. The contaminated gas is expelled from the expansion volume 1 0 through the outlet channel 15 into the reservoir volume 17 and / or through the connecting opening 14 into the outflow channel 13. The outflow opening 1 5 and the connecting opening 1 4 are advantageously dimensioned such that the major part of the gas expelled from the expansion volume 10 reaches the reservoir volume 1 7. The inlet valve 22 is advantageously not arranged in the vicinity of the outflow opening 15, as is also shown in FIG. 1. This prevents the intake valve 22 from sucking in contaminated gas.

In Fig. 1, the essential gas flows are indicated by dashed lines. Above, in the open state 0, for switching on, below, in the closed state C, for switching off.

An optional pressure control valve 20 is also provided in the quenching chamber in FIG. 1 and is arranged in the inflow channel 9. Without the pressure valve 20, the inflow channel 9 is continuously open as a connection between the two compression volumes 7 and 8. The pressure control valve 20 opens the inflow channel 9 only when a pressure p ₂ prevailing in the second compression volume 8 is greater than at least one predeterminable differential pressure Δp> 0 than one in the first

Compression volume 7 prevailing pressure pi (where here pi is PH, the pressure in the heating volume 5, which is equal to the first compression volume 7 in the buffer switch shown in FIG. 1). To illustrate this, a spring is shown between the valve disc and the stop of the schematically illustrated pressure control valve 20, which strives to close the valve 20.

2 shows a further advantageous embodiment of the invention. It is an arcing chamber for an auto blow switch. This quenching chamber largely corresponds to the quenching chamber shown in FIG. 1 and is described on the basis thereof. The representations of the quenching chambers in Figs. 1 and 2 correspond to each other.

The quenching chamber in FIG. 2 has a reheating valve 21. The reheat valve 21, when closed, separates the first one Compression volume 7 of the reheating volume 5. It is designed so that it opens when the pressure pi in the first compression volume 7 is greater than the pressure PH in the heating volume 5. This avoids the occurrence of higher pressures, such as those caused by the ignition of the arc 4, on the piston Kl. And the quenching chamber can be operated with a smaller drive, i.e. with a lower drive energy.

Furthermore, in FIG. 2, a valve 1 8, which is advantageously designed as a sleeve valve 1 8, is provided at the connection opening 1 4 and an outlet valve 1 9 is provided at the outflow opening 1 5. These valves can be used individually or advantageously together. The respective valve 1, 8.1, 9 can also be used if only one of the two openings 14, 15 is provided. The valve or valves 1, 8.1, 9 can also be used advantageously in a buffer switch (see FIG. 1).

Valve 1 8 opens the connection between outflow duct 1 3 and expansion volume 1 0 during a switch-off process. Thus, the drive can be supported against the piston K3 by the resulting gas flow of contaminated gas. During a switch-on process, the valve 1 8 closes this connection, so that the contaminated extinguishing gas present in the expansion volume 1 0 is not ejected into the outflow channel 1 3 but only into the reservoir volume 1 7 during the reduction in the expansion volume 1 0 due to the movement of the piston K3 , According to passes via the bleed passage 3 1 less or no polluted gas properties are achieved in the quenching zone 3 so that improved switching ^¬.

The valve 1 8 is advantageously designed as a sleeve valve 1 8, which consists essentially of a sleeve 1 8, which is substantially tubular is formed and is slidably mounted on the outflow pipe 1 2. In the case of a vertically mounted quenching chamber (vertically with the gravitationally downward movement of the movable contact piece 2 when switching off), the sleeve 1 8 is in contact with the piston K3 or a stop (not shown) and closes the connection opening 1 4. Only during a switching off process the connection opening 1 4 released because the sleeve 1 8 remains at the top due to its inertia, while the outflow pipe 1 2 moves down. At the end of the switch-off movement, the sleeve 1 8 then moves down (due to gravity) and closes the connecting opening 1 4. In the case of horizontally oriented extinguishing chambers, the corresponding movement of the sleeve can be realized, for example, by a spring which tends to push the sleeve in to move the position in which the connection opening 1 4 is closed. Sleeve valves can also be used in other switches and / or arcing chambers, in which it is necessary to open and close one or more openings in a cylindrical part of the switch. As shown, the sleeve can be arranged on the outside of the cylindrical part (such as, for example, on the outflow pipe 12) or also therein. Of course, a sleeve valve is not limited to circular cross sections, but can also be used if the part of the switch which has the openings to be closed has an oval or square cross section or has another essentially prismatic shape.

The valve 1 8 can also be designed as a rattling valve.

The outlet valve 1 9 serves to close the outflow opening 1 5 during a switch-off process and to open it during a switch-on process. It can work depending on the stroke or pressure, so that an optimal exhaust pressure can be set. It is also possible to design the outlet valve 1 9 as a sleeve, similar to the valve 1 8. During a switch-off process, the outlet valve 19 prevents the gas stream entering the expansion volume 10 through the connection opening 14 from escaping into the reservoir volume 17. In this way, maximum drive support can be achieved. During a switch-on process, contaminated gas can flow through the

Outflow opening 1 5 are discharged into the reservoir volume 1 7, so that the extinguishing zone 3 is not contaminated by the contaminated gas. The outlet valve 1 9 advantageously opens the outflow opening 1 5 only in the open state O, that is to say when the drive no longer drives the movable contact piece 2.

No pressure control valve 20 is provided in the arcing chamber shown in FIG. 2, as in FIG. 1. The use of such a valve 20 is also possible in an auto-blow switch.

A particularly simple quenching chamber is obtained when there is no connection opening 1 4 and thus also no valve 1 8, and when an outlet valve 1 9 is also dispensed with, so that the outflow opening 1 5 is always open. The piston K2, K3 then does not act as a differential piston, and the drive does not receive any support.

The quenching chambers shown include a first piston K1 of a first piston-cylinder arrangement, which contains the first compression volume 7, and a second piston K2 of a second piston-cylinder arrangement, which contains the second compression volume 8. The two compression volumes 7, 8 are arranged and connected to one another in such a way that a change in one of the two compression volumes 7, 8 causes an equally large change in the total volume formed by the compression volumes 7, 8. This can, as shown, can be achieved without an opposite movement of the two pistons K1, K2 being necessary.

During a switching operation, the pistons K1, K2, K3 move in parallel in the embodiments discussed above and with the same

Speed and one way only. They move continuously during a shift. However, it is also possible to provide other movements which do not have one or more of these properties, in particular movements with different speeds for different pistons, for example generated by means of gears, gear ratios or scenes. Reverse movements of pistons, in particular pistons Kl and K2, are also possible.

In the exemplary embodiments shown above, the inner cylinder wall of the essentially hollow cylindrical inflow channel 9 is essentially formed by the outer wall of the hollow cylinder Z2. It is also possible to design the quenching chamber in such a way that the inner cylinder wall of the inflow channel 9 is formed by the outflow pipe 12 and the outer cylinder wall of the inflow channel 9 is formed by the outer wall of the hollow cylinder Z2. The outflow opening 15 could then be designed as a simple opening in the outer wall of the hollow cylinder Z2 instead of as a channel. Such an embodiment is advantageous, for example if no connection opening 14 is provided.

By varying the dead volumes of the first and the second piston-cylinder arrangement, it is possible to achieve different pressures pi, p2 in the two compression volumes 7.8 without a pressure control valve 20. LIST OF REFERENCE NUMBERS

1 first contact piece (fixed contact piece)

2 second contact piece (movable contact piece)

3 extinguishing zone

4 arcs

5 heating volume 6 heating channel

7 first compression volume

8 second compression volume

9 inflow channel

1 0 expansion volume 1 1 a nozzle, insulating nozzle

1 l b nozzle, auxiliary nozzle

1 2 outlet pipe

1 3 discharge channel

14 connection opening (between expansion volume and outflow channel)

1 5 outlet opening, outlet channel (between expansion volume and reservoir volume)

1 6 Extinguishing chamber housing, insulating housing

1 7 reservoir volume, tank volume 1 8 valve, sleeve valve

1 9 valve, exhaust valve

20 valve, pressure control valve

21 valve, reheating valve, rattling valve

22 valve, inlet valve 23 line of action A axis of the arcing chamber

Bl cylinder bottom of the first piston-cylinder arrangement

B2 cylinder base of the second piston-cylinder arrangement

B3 cylinder bottom of the third piston-cylinder arrangement C closed

Kl piston of the first piston-cylinder arrangement

K2 pistons of the second piston-cylinder arrangement

K3 pistons of the third piston-cylinder arrangement

O open (open) pi pressure in the first compression volume p ₂ pressure in the second compression volume

PH pressure in the heating volume

Δp differential pressure p2 - pi

ZI cylinder wall of the first piston-cylinder arrangement Z2 cylinder wall of the second piston-cylinder arrangement

Z3 cylinder wall of the third piston-cylinder arrangement

Claims

1 . Arcing chamber for a high-performance switch filled with an extinguishing gas, comprising 5 a first contact piece (1) and a second contact piece (2), at least one of which is a movable contact piece (2) and which can be moved relative to one another by means of a drive, an extinguishing zone (3) arranged between the two contact pieces (1, 2), in which an arc w (4) can be formed between the two contact pieces (1, 2) during a switch-off process, - a heating volume (5) for receiving the Arc (4) heated extinguishing gas, by means of which the arc (4) can be blown, there being a first compression volume (7) which is arranged in such a way that it reduces in size when the device is switched off

15, so that extinguishing gas is conducted from the first compression volume (7) into the extinguishing zone (3), and - a second compression volume (8), characterized in that one of the first (7) and the second (8) compression volume 0 there is a separately arranged expansion volume (1 0), which is arranged such that when the total volume of the first (7) and the second (8) compression volume is increased, its volume decreases and when the total volume of the first (7) and the second (8) 5 compression volume increases its volume.

2. extinguishing chamber according to claim 1, characterized in that the expansion volume (1 0) and the second compression volume (8) are arranged such that a change in volume of the second Compression volume (8) causes an opposite volume change of the expansion volume (10).

3. extinguishing chamber according to claim 1 or claim 2, characterized in that the extinguishing chamber has an axis (A), and that the first (7) and the second (8) compression volume via an inflow channel extending parallel to the axis (A) (9) are interconnected.

w

4. extinguishing chamber according to claim 3, characterized in that in the inflow channel (9) a pressure control valve (20) is arranged to open the inflow channel (9) when a pressure p2 prevails in the second compression volume (8), which is by at least a predetermined pressure difference Δp> 0 is greater than a pressure pi in the first compression volume

15 (7) and for closing the inflow channel (9) otherwise.

5. extinguishing chamber according to one of the preceding claims, characterized in that at least one of the contact pieces (1, 2) is penetrated by an outflow channel (1 3) and that the 0 expansion volume (10) is connected to the outflow channel (1 3).

6. extinguishing chamber according to one of the preceding claims, characterized in that the extinguishing chamber has a reservoir volume (1 6), and that the expansion volume (10) is connected to the 5 reservoir volume (1 7).

7. extinguishing chamber according to claim 5 and claim 6, characterized in that a valve (1 8) is provided for closing the connection (1 4) between the expansion volume (10) and the 0 outflow channel (1 3) during a switch-on process and for opening the Connection (14) between the expansion volume (10) and the outflow channel (1 3) during a switch-off process.

8. extinguishing chamber according to claim 5 and claim 6 or according to 5 claim 7, characterized in that a valve (1 9) is provided for closing the connection (14) between the expansion volume (10) and the reservoir volume (1 7) during a switch-off process and to open the connection (14) between the expansion volume (10) and the reservoir volume (1 7) during an activation process.

9. extinguishing chamber according to one of the preceding claims, characterized in that a second piston (Kl) of a second piston-cylinder arrangement, which the second compression volume (8)

15 includes, is rigidly connected to the movable contact piece (2).

1 0. Extinguishing chamber according to one of the preceding claims, characterized in that the heating volume (5) is identical to the first compression volume (8). 0 1 1. Extinguishing chamber according to one of claims 1-9, characterized in that a reheating valve (21) is arranged between the heating volume (5) and the first compression volume (7) for separating the first compression volume (7) from the heating volume 5 (5) in the Case in which there is a pressure PH in the heating volume (5) which is greater than a pressure pi in the first compression volume (7), and to connect the heating volume (5) with the first compression volume (7), if in the heating volume ( 5) there is a pressure P _H that is less than a pressure pi in the first 0 compression volume (7). High-performance switch, characterized in that it contains an arcing chamber according to one of the preceding claims.