EP3586348B1 - Switchgear driving arrangement - Google Patents

Description

The invention relates to a switching device drive arrangement with a transmission element for transmitting a movement through a wall of a housing, the transmission element being supported in a linearly displaceable manner on the wall of the housing, a first guide bearing having a bearing sleeve on which the transmission element is displaceably supported and the bearing sleeve surrounds a reversibly deformable section of the wall.

A switching device drive arrangement is, for example, from DE 42 01 823 A1 known. The known switching device drive arrangement has a transmission element which passes through a wall of a housing. The transmission element is connected to the housing by means of a reversibly deformable section. Movement of the transmission element must be compensated for in the reversibly deformable section. Forces can act on the reversibly deformable section, which can represent a point overload. Overloading the transmission element can lead to premature signs of fatigue, which can limit the function of the reversibly deformable section.

The disclosure document DE 35 29 386 A1 An encapsulated high-voltage switching device can be removed. The encapsulated high-voltage switching device has a drive linkage comprising a drive rod and a cylinder. The cylinder passes through an end cover and is displaceably arranged. The international publication WO 03/071567 A1 A vacuum interrupter with a switching contact piece can be removed. To guide a drive rod, an intermediate piece with an enlarged cross section is provided, which is slidably inserted into a holding fitting. From the document DE 10 2015 214 509 A1 an electrical switching chamber works which has a moving contact connection bolt which is guided in a bearing, with a bellows extending into the interior of a vacuum interrupter of the electrical switching chamber. This continues from the translation of the European patent specification DE 69522282 T2 a load disconnect switch having a sliding contact to electrically connect a movable rod of a vacuum piston. The sliding contact has an enlarged cross section compared to the rod. The sliding contact is provided with channels for ventilation. From the patent specification GB1206297 A vacuum interrupter is known which has several switching chambers. The switching chambers are each equipped with a movable switching contact piece, which are each sealed using a metallic bellows which extends into the interior of the respective tube of the switching chamber. From the US patent US 5,387,771 a high voltage vacuum breaker pops out. A plain bearing is arranged within an evacuated space to support a movable handle.

The object of the invention is therefore to provide a switching device drive arrangement which prevents overloading.

According to the invention, the object is achieved in a switching device drive arrangement of the type mentioned in that a spacer is arranged between the bearing sleeve and the reversibly deformable section.

A switching device drive arrangement is used to transmit or generate a drive movement for switching contact pieces of an electrical switching device that can be moved relative to one another. For this purpose, the switching device drive arrangement has a kinematic chain which has a transmission element which passes through a wall of a housing. The wall can preferably be designed to be fluid-tight, with penetration of the wall by means of the transmission element maintaining the fluid-tightness of the wall. A fluid-tight transition between the wall and the transmission element can be ensured, for example, by a reversibly deformable section. The housing can surround an interrupter unit/a switching point of the switching device. The housing can preferably represent a fluid-tight encapsulation housing, which accommodates the interrupter unit/switching point of the switching device in its interior. The switching device drive arrangement can, for example, have a drive device outside the housing which serves to generate a movement, this movement being transmitted to the switching point of the switching device by means of the kinematic chain. The switching device can have switching contact pieces that can be moved relative to one another and which can be moved relative to one another by the drive device.

By means of a linearly displaceable transmission element, a movement to be transmitted can pass through the wall of the housing. The transmission element itself can preferably be slidably supported on the wall itself, with the transmission element passing through the wall. The wall is preferably penetrated in a fluid-tight manner. For example, a sliding seal can be arranged between the transmission element and the wall. However, it can also be provided that a section is designed to be reversibly deformable, with the transmission element being connected to the wall in a fluid-tight manner via the reversibly deformed section. For example, a cohesive bond between the transmission element and the wall can be provided via the deformable section. The transmission element can, for example, be shaped like a switching rod, which extends inside or outside of the housing. If necessary, the transmission element can be composed of several sections so that a permanent fluid-tight connection between the shift rod and the wall of the housing can be achieved. By supporting the transmission element on a wall of the housing, guidance of the transmission element is ensured, so that undesirable buckling or tilting of the transmission element is prevented. This creates a defined movement transmitted through the wall, whereby undesirable loading, in particular of sealing elements between the wall and transmission element, is avoided. This ensures a permanent, low-wear transmission of a movement by means of the transmission element. The transmission element can be, for example, a switching rod which has different sections, the sections being arranged one after the other in order to transmit a linear movement by means of the transmission element. For example, the switching rod can have contact pressure springs, sealing elements, metallic or electrically insulating sections, etc.

The transmission element can be supported, for example, by means of a guide bearing. To ensure linear guidance of the transmission element, the use of several guide bearings can preferably be provided, which are arranged axially spaced apart from one another, whereby stable linear guidance of the transmission element can be ensured. For example, plain bearings or roller bearings come into consideration as guide bearings in order to provide linear guidance of the transmission element.

In addition to axial displaceability of the transmission element, a superimposed rotary movement can also be provided. For example, rotation of the transmission element around the displacement axis can be permitted.

A further advantageous embodiment can provide that the transmission element is guided in a linearly displaceable manner within the housing.

The housing surrounds the interrupter unit of a switching device inside. By means of the transmission element, a movement can be transmitted to at least one of switching contact pieces that are movable relative to one another. By supporting the transmission element within the housing, the transmission element can be supported on the one hand in order to To ensure that a movement is transmitted as straight as possible through a wall of the housing. In addition, however, the transmission element can also serve to guide a switching contact piece with its stabilized mounting. Thus, a guide bearing arranged within the housing can, on the one hand, stabilize a movement of the transmission element. On the other hand, a movement of a switching contact piece can also be stabilized via this guide bearing. This allows the transmission behavior of the kinematic chain to be improved. This counteracts inaccuracies or undesirable elasticities within the kinematic chain. Furthermore, this guidance through the housing is protected from external access by supporting or guiding the transmission element within the housing. This means, for example, that delicate mechanics can be used that are protected from contamination by the housing. Furthermore, a guide inside the housing can also serve to provide electrical contact, for example of a switching contact piece, at least in sections via a guide bearing for the transmission element. This is particularly advantageous when stabilizing both a transmission element and a switching contact piece by a guide bearing in order to achieve stabilization as close as possible to a relatively movable switching contact piece. For this purpose, for example, electrical sliding contact arrangements can be used as part of a guide bearing. Support can advantageously be provided on the housing.

A further advantageous embodiment can provide that the transmission element is guided in a linearly displaceable manner outside the housing.

Outside an encapsulation housing, it is possible to provide simplified access to a guide bearing. Furthermore, the installation space inside the housing is usually limited, so that a linear guidance of the transmission element outside the housing reduces the number of internals inside of the housing reduced. It is advantageous if the transmission element is stabilized relative to the wall of the housing through which the transmission element passes. In an advantageous case, a linear guide of the transmission element can be provided both inside and outside of the housing. For this purpose, for example, a guide bearing can be arranged inside and outside of the housing. Outside the housing, the construction of the guide bearing can be designed to be correspondingly more robust, since the installation space is not limited by the housing.

A further advantageous embodiment can provide that a second guide bearing is arranged on a phase conductor of a switching device.

A switching point of a switching device is used to interrupt or switch a current path/phase conductor. The current path/a phase conductor can be electrically switched, for example, by means of switching contact pieces that can be moved relative to one another. A second guide bearing can be arranged on such a phase conductor. For this purpose, the second guide bearing is at least partially exposed to the electrical potential that the respective phase conductor carries. For example, the phase conductor can function as a guide bearing in the manner of a bearing sleeve, with the transmission element being able to be moved linearly. For example, the transmission element can dip into the bearing sleeve in the manner of a piston. This still makes it possible to use the second guide bearing for electrically contacting a switching contact piece that is movable relative to another switching contact piece. There is also the possibility of stabilizing and supporting a movable switching contact piece via the second guide bearing. The second guide bearing can therefore serve to stabilize a linear movement of the transmission element as well as to stabilize a movement of a switching contact piece of the switching device. Furthermore, it can advantageously be provided that a first guide bearing guides a fluid-tight section to close an opening in the wall.

A first guide bearing serves to stabilize a movement of the transmission element. The first guide bearing can guide part of a fluid-tight section. The fluid-tight section can be formed by the transmission element. The fluid-tight section can be part of the housing. For example, a fluid-tight section of a transmission element can be displaceably mounted in a bearing sleeve. It is therefore possible to achieve a fluid-tight throughput of the wall using a transmission element. For example, the fluid-tight section can be sealed relative to the fluid-tight wall via a bellows, which can be formed like a bellows. For example, the transmission element can be inserted into a bellows in a fluid-tight manner (e.g. in the form of a disk). The fluid-tight section/disc can be displaceably guided in a bearing sleeve. A bearing sleeve can serve as the first guide bearing.

Advantageously, it is further provided that a first guide bearing has a bearing sleeve on which the transmission element is slidably supported.

A bearing sleeve can serve to guide the transmission element, the transmission element being guided in an axially displaceable manner in the bearing sleeve. The bearing sleeve can, for example, be supported on the housing, wherein a reversibly deformable section for sealing the transmission element can be arranged within the bearing sleeve. The bearing sleeve can thus serve to guide the transmission element. Furthermore, the bearing sleeve can provide mechanical stabilization of the reversibly deformable section as well as mechanical protection.

For this purpose, it is further advantageously provided that the bearing sleeve surrounds a reversibly deformable section of the wall.

A reversibly deformable section can be, for example, a bellows, the axial extent of which can be changed essentially in the axial direction. For example, a fluid-tight section, for example of a transmission element, can be attached in a fluid-tight manner to the end face of the reversibly deformable section, which effects a front end closure of the reversibly deformable section. A linear guidance of the transmission element within the bearing sleeve can also be provided via this front end. The bearing sleeve can encompass the reversibly deformable section on the outer casing side, so that when the reversibly deformable section is reshaped, the reversibly deformable section is prevented from buckling or buckling out. This ensures positive guidance of both the guided fluid-tight section and the reversibly deformable section (bellows) within the bearing sleeve. The bearing sleeve is free of a sealing function on the housing, so that transverse openings can also be provided in it, for example, through which external access or control of the reversibly deformable section is possible.

Furthermore, it is provided that a spacer is arranged between the bearing sleeve and the reversibly deformable section.

When the reversibly deformable section is reshaped, the reversibly deformable section can bulge or deflect in the radial direction. Deflection can be limited by the bearing sleeve. By using a spacer between the deformable section and the bearing sleeve, direct contact between the bearing sleeve and the reversibly deformable section can be prevented. Particularly when the reversibly deformable section is folded like a bellows, friction can be reduced between reversibly deformable section and bearing sleeve can be reduced. The spacer can be arranged between mutually facing surfaces of the bearing sleeve and the reversibly deformable section. For example, the spacer can be made of friction-reducing material. For example, the spacer can be used as an intermediate sleeve, for example. B. made of PTFE enable low-friction relative sliding of the bearing sleeve and reversibly deformable section. This prevents excessive abrasion at prominent points of the reversibly deformable section.

Furthermore, it can advantageously be provided that the spacer is displaceable relative to the bearing sleeve.

The spacer can be arranged to be displaceable relative to the bearing sleeve, so that it is moved, for example, together with a movement of the transmission element. In a preferred case, this causes a relative movement between the spacer and the bearing sleeve with a larger stroke than a relative movement of the spacer to points of the reversibly deformable section that are at risk of abrasion. This also makes it possible, for example, to arrange a further spacer on the reversibly deformable section on the inside of the casing, so that when the spacer and further spacer slide into one another with the reversibly deformable section of the wall of the housing in between, improved guidance (inside and outside) and preferred Reshaping of the reversibly deformable section is forced. In addition to improved linear guidance of the transmission element, the reversibly deformable section can be reshaped in a preferred manner, thereby counteracting premature aging of the reversibly deformable section as a result of point fatigue of the material.

It can advantageously be provided that the second guide bearing and the first guide bearing are aligned with one another arranged to stabilize a linear movement of the transmission element.

An aligned arrangement of the second and first guide bearings spaced apart from one another enables improved storage of the transmission element. A tendency for the transmission element to break out is counteracted by spacing the guide bearings from one another. A wall of the housing can preferably be arranged between the two guide bearings, which makes it possible to fix both the second and the first guide bearing relative to the housing, with the second and first guide bearings being able to be fixed independently of one another. This forms a base over the housing in order to adjust both the second and the first guide bearing.

A further advantageous embodiment can provide that the housing is a pressure vessel.

The housing can be designed as a fluid-tight encapsulation housing, whereby a fluid can be enclosed and encapsulated inside the housing. If the housing is designed as a pressure vessel, the fluid inside the housing can have a different pressure than the surroundings. This makes it possible to create a differential pressure between the inside of the housing and the outside of the housing. For example, a higher pressure can be generated inside the housing compared to the surroundings of the housing. However, it can also be provided that inside the housing there is a pressure that is reduced compared to the environment, for example a vacuum, so that the housing is exposed to a differential pressure which the housing withstands. The housing can, for example, encapsulate an electrically insulating fluid or a vacuum. Suitable fluids include, for example, fluoride-containing gases such as sulfur hexafluoride, fluoronitriles, fluoroketones or other fluids such as carbon dioxide, nitrogen, oxygen, etc corresponding fluid mixtures. The fluid inside the housing can preferably be in gas form.

A further advantageous embodiment can provide that a switching point of a switching device is arranged within the housing.

An electrical switching device is used to switch or interrupt a current path, for which switching contact pieces that can be moved relative to one another are preferably used. A switching point is formed between the switching contact pieces in order to cause the switchable current path of the switching device to be interrupted or switched on. A kinematic chain with the transmission element can be used to generate a relative movement of the switching contact pieces of a switching point. The switching point is mechanically protected by the housing. Furthermore, the housing can enclose a special atmosphere, whereby the switching point itself is also exposed to this atmosphere. For example, an electrically insulating fluid, see above, can preferably be arranged within the housing, with which the switching point can also be flooded. With the appropriate choice of the electrically insulating fluid, an interruption or occurrence of switching arcs can be reduced or the extinction of the switching arcs can be supported. A switching point can also be arranged within a closed environment (bottle in a bottle) within the housing. For example, a vacuum tube, within which the switching point is arranged, can be arranged in the housing.

Advantageously, it can be provided that the switching point is at least partially supported on the housing.

The switching point can advantageously be supported on the housing. This has the advantage that both the switching point, i.e. the location to which a movement is to be transmitted via the transmission element, and the transmission element are supported on the same base. This means that both the switching point and the transmission element can be adjusted independently of each other relative to the housing. This means that a movement can be carried out particularly precisely and repeatably. This reduces the load on the transmission element and thus also on the switching point, resulting in a permanently stable switching device drive arrangement.

A further advantageous embodiment can provide that the second guide bearing and the first guide bearing are arranged electrically insulated from one another.

An electrically insulating separation of the second and first guide bearings enables the guide bearings on a switching device arrangement to have different electrical potentials. The two guide bearings can be connected via the transmission element. In order to ensure electrical insulation of the two guide bearings here too, the transmission element can have an electrically insulating effect, at least in sections. An electrically insulating section is preferably guided or supported at each end by the second or first guide bearing. The transmission element can, for example, have an electrically insulating drive rod. The drive rod can be formed, for example, by a hollow tube which extends at least within the housing. Due to the electrically insulated arrangement of the guide bearings from one another, a guide bearing can be brought close to a switching contact piece of the switching point that carries an electrical potential. For example, a guide bearing can be integrated into a phase conductor of a switching point. Furthermore, a guide bearing can, for example, also be designed as part of the housing and, for example, carry earth potential there. This makes it possible to carry out the linear guidance of the transmission element using guide bearings positioned at a distance from one another, with the linear guidance due to the axial spacing of the transmission element can be carried out in an exact manner.

A further object of the invention is to propose a suitable use of the switching device drive arrangement. According to the invention, it is provided that a switching device with switching contact pieces that can be driven relative to one another has a switching device drive arrangement with the features described above.

An electrical switching device is used to switch or interrupt a current path. For this purpose, the switching device has switching contact pieces that can be moved relative to one another. In order to generate a relative movement of the switching contact pieces to one another, the use of a switching device drive arrangement with the features described above is preferably provided. Via the switching device drive arrangement, a movement outside a housing can be generated, for example by a drive device, wherein a movement can be transmitted through a wall of the housing into the interior of the housing to a switching point of the switching device. As part of the kinematic chain, a transmission element can be used, which can carry out a linear movement supported by a guide bearing. This linear movement can be transmitted to the switching point. There the linear movement can be transformed, for example, using a gear.

An exemplary embodiment of the invention is shown below in a schematic drawing and then described.

The figure shows a section through a switching device drive arrangement and a switching device which has the switching device drive arrangement.

The switching device drive arrangement has a transmission element 1. The transmission element 1 can be moved linearly stored. The transmission element 1 passes through a housing 2. The housing 2 is designed as a fluid-tight pressure vessel, with a switching point 3 being arranged inside the housing 2. The switching point 3 is in the present case designed as a vacuum tube, which is essentially rotationally symmetrical, with a first switching contact piece 4 and a second switching contact piece 5 protruding into the interior of the vacuum tube on the front side. The two switching contact pieces 4, 5 are aligned coaxially with one another, with the first switching contact piece 4 being arranged to be axially movable. The second switching contact piece 5 is arranged in a stationary manner. In order to fix the switching device in a stationary manner within the housing 2, a first section 6 and a second section 7 of a phase conductor run are connected to the switching point 3 in an angle-rigid manner. The first section 6 is electrically conductively connected to the first switching contact piece 4, the second section 7 is electrically conductively connected to the second switching contact piece 5. To support the second section 7, a support insulator 8 is arranged on the inside wall of the housing 2. The support insulator 8 holds the second section 7 in an angularly rigid manner relative to the housing 2. Via the connection of the second section 7 of the phase conductor, the end face of the switching device 3, on which the second switching contact piece 5 is arranged, is fixed in an angularly rigid manner relative to the housing 2. The first section 6 is essentially hollow cylindrical and supports the end face of the switching device 3, on which the first switching contact piece 4 is movably arranged. In order to stabilize the first section 6 and thus also the switching point 3, a hollow support 9 is arranged on the first section 6, specifically at the front end, which faces away from the switching point 3. An electrically insulating connection between an inner wall of the housing 2 and the first section 6 is therefore provided via the hollow support 9. On the shell side, a branch 10 is arranged on the first section 6, via which the phase conductor is guided outwards from the first section 6 through a wall of the housing 2. To the electric Insulated guidance of the branch 10, a jacket-side connection 11 is insulated by a disk insulator 12, which is passed through in a fluid-tight manner by the branch 10. Additional assemblies, such as e.g. B. flange an outdoor duct or other housing assemblies. Analogous to the discharge of the branch 10 through a wall of the housing 2, the second section 7 is electrically insulated and guided in a fluid-tight manner from the interior of the housing 2 to the outside by a further sleeve-side connection piece 11a and a further disc insulator 12a. In the present case it is provided that the housing 2 is essentially formed from an electrically conductive material which is subjected to ground potential.

The transmission element 1 passes through the hollow support 9 and continues within the first section 6 of the phase conductor up to the first switching contact piece 4. The transmission element 1 is composed of several sections. The transmission element 1 has, for example, an electrically insulating tube section 1a. The electrically insulating pipe section 1a is connected with its end facing away from the switching point 3 to a disk-shaped section 2a of the transmission element 1. The disk-shaped section 2a closes an opening in the housing 2 via a so-called bellows 13 (reversibly deformable section). The bellows 13 is closed in a fluid-tight manner on one end face with the disk-shaped section 2a. With its other end, the bellows 13 is connected at the front in a fluid-tight manner to an angularly rigid section of the housing 2 (encompassing the opening). The transmission element 1 continues outside the housing in a drive rod 14 via the disk-shaped section 2a. At one end of the transmission element 1 facing the switching device 3, the transmission element 1 has a contact pressure spring 15, which is arranged in a spring housing 16. The spring housing 16 is provided with a guide collar 17, so that the spring housing 16 of the transmission element 1 is centered within the hollow cylindrical Recess of the first section 6 of the phase conductor is slidably guided. In addition, a contact disk 18 is arranged in the course of the transmission element 1. The contact disk 18 is electrically conductively connected to the first switching contact piece 4. The contact disk 18 slides in the same hollow cylindrical recess of the first section 6 as the guide collar 17 of the spring housing 16. If necessary, electrical contact can be made both via the contact disk 18 and additionally via the spring housing 16 in order to achieve movable electrically conductive contact between the first switching contact piece 4 as well as the phase conductor to be interrupted via the first section 6.

The bellows 13 is surrounded by a bearing sleeve 19 on the outer casing side. The bearing sleeve 19 is arranged outside the housing 2. The bearing sleeve 19 accommodates the disk-shaped section 2a in its hollow cylindrical recess, so that it is guided in a linearly displaceable manner. A spacer 20 is arranged between the annular gap formed on the inner casing side in the bearing sleeve 19 and on the outer casing side on the circumference of the bellows 13. In the present case, the spacer 20 is designed to be essentially hollow cylindrical, with the front side being fixed to the disk-shaped section 2a. In order to reduce the friction on the outer circumference, axially spaced circumferential annular shoulders are arranged on the spacer 20. An additional spacer 21 is arranged inside the housing 2 between the inner wall of the bellows 13 and the electrically insulating pipe section 1a. The additional spacer 21 is connected in a stationary manner to the housing 2, the axial extent of both the spacer 20 and the additional spacer 21 being selected such that an overlap of the two spacers 20, 21 (with the bellows 13 in between) is always ensured. The spacers 20, 21 ensure guidance of the bellows 13 if it is deformed.

A second guide bearing for the transmission element 1 is provided within the first section 6 via the guide collar 17 or the contact disk 18 there. The second guide bearing is thus arranged on a phase conductor of the switching device. The second guide bearing is arranged within the housing 2. A first guide bearing is formed on the bearing sleeve 19, within which the disk-shaped section 2a is slidably guided. The disk-shaped section 2a of the transmission element 1 is guided outside the housing 2 on the first guide bearing. The guide bearings are each arranged at the ends of the electrically insulating pipe section 1a. The bearing sleeves of both the second guide bearing and the first guide bearing are aligned in a stationary manner with respect to the housing 2. The two guide bearings are aligned with one another in the axial direction, so that a linear movement of the transmission element 1 (in particular of the electrically insulating section/electrically insulating pipe section 1a) is guided both inside the housing 2 and outside the housing 2. During a switch-on process (the figure shows a switched-off state of the switching point 3), a movement is emitted by the drive device coupled to the transmission element 1, with a linear movement of the transmission element 1 taking place, as a result of which the first switching contact piece 4 approaches the second switching contact piece 5. The transmission element 1 is linearly guided both via the second guide bearing and the first guide bearing. When the first switching contact piece 4 and the second switching contact piece 5 make contact, the drive device overtravels, as a result of which the contact pressure spring 15 is compressed. Thus, starting from the transmission element 1, a contact force is generated between the first switching contact piece 4 and the second switching contact piece 5. The phase conductor is switched on. During the switch-on process, the bellows 13 is compressed, with the overlap of the two spacers 20, 21 increasing, which results in increased guidance of the folding of the bellows 13.

During a switch-off process, the direction of movement of the transmission element 1 is reversed. The contact pressure spring 15 is initially relaxed, after which the first switching contact piece 4 moves away from the second switching contact piece 5 until the switch-off position is reached.

The interior of the housing 2 can be filled with an electrically insulating fluid under excess pressure. This electrically insulating fluid is preferably in gaseous form inside the housing 2. For example, sulfur hexafluoride, fluoroketone, fluoronitrile, carbon dioxide, nitrogen, oxygen and other electronegative substances, preferably in a mixture, have proven to be useful as electrically insulating fluids. The switching device drive arrangement shown in the figure or the switching device 3 shown can be used, for example, in a so-called gas-insulated switchgear or also in an outdoor switching device. In addition to the one in the Figure 1 Single-pole electrical insulation shown can also be used variants with multi-pole electrical insulation, ie with several phase conductors electrically insulated from each other arranged within one and the same housing 2.

Claims (12)

1. A switchgear drive arrangement comprising a transmission element (1) for transmitting a movement through a wall of a housing (2), wherein the transmission element (1) is guided such that it is supported in a linearly displaceable manner on the wall of the housing (2), wherein a first guide bearing has a bearing sleeve (19) on which the transmission element (1) is supported in a displaceable manner and the bearing sleeve (19) engages around a reversibly deformable section (13) of the wall, characterized in that a spacer (20) is arranged between the bearing sleeve (19) and the reversibly deformable section (13) .
2. Switchgear drive arrangement according to Claim 1, characterized in that the transmission element (1) is guided such that it is supported in a linearly displaceable manner within the housing (2).
3. Switchgear drive arrangement according to Claim 1 or Claim 2, characterized in that the transmission element (1) is guided such that it is supported in a linearly displaceable manner outside the housing (2).
4. Switchgear drive arrangement according to one of Claims 1 to 3, characterized in that a second guide bearing is arranged on a phase conductor (6) of a switchgear.
5. Switchgear drive arrangement according to one of Claims 1 to 4, characterized in that the first guide bearing guides a fluid-tight section (2a) for closing an opening of the wall.
6. Switchgear drive arrangement according to one of Claims 1 to 5, characterized in that the spacer (20) is displaceable relative to the bearing sleeve (19).
7. Switchgear drive arrangement according to one of Claims 4 to 6, characterized in that the second guide bearing and the first guide bearing stabilize a linear movement of the transmission element (1) in a manner arranged in alignment with one another.
8. Switchgear drive arrangement according to one of Claims 1 to 7, characterized in that the housing (2) is a pressure vessel.
9. Switchgear drive arrangement according to one of Claims 1 to 8, characterized in that a switching point (3) of a switchgear is arranged within the housing (2).
10. Switchgear drive arrangement according to Claim 9, characterized in that the switching point (3) is at least partially supported against the housing (2).
11. Switchgear drive arrangement according to one of Claims 4 to 10, characterized in that the second guide bearing and the first guide bearing are arranged such that they are electrically insulated from one another.
12. Electrical switchgear comprising switching contact pieces which can be driven relative to one another, characterized in that the switchgear has a switchgear drive arrangement according to one of Claims 1 to 11.

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