DE102011077768A1 - An outdoor switching equipment - Google Patents

Abstract

An outdoor switching device has an outdoor switching section and a first contact piece (5) and a second contact piece (6). The first contact piece (5) can be moved relative to the second switching contact piece (6) by means of a drive arrangement (3). The first contact piece (5) is arranged on a swivel arm (3b) of the drive arrangement (3). The swivel arm (3b) is mounted on a lifting gear (3a).

Description

The invention relates to an open-air switching device with an outdoor switching path, with a first contact piece, with a second contact piece, wherein the first contact piece is arranged by means of a drive arrangement relative to the second contact piece and movable on a pivot arm of the drive assembly.

Such outdoor switching device is for example from the translation of the European patent specification DE 60 2005 000 144 T2 known. The local outdoor switching device is referred to as a pivotable earthing switch, which has a first contact piece and a second contact piece. The first contact piece is pivotable about a pivot point, so that it is movable relative to the second contact piece. Thus, it is possible to form an open-circuit switching path between the two contact pieces.

In the known outdoor switching device of the swivel arm is formed using two electrically conductive sub-elements, which are aligned and stiffened by means of transverse bolts. This creates a torsion-resistant structure. With the use of outdoor switching devices in higher voltage levels, it is necessary to increase the open-circuit switching sections accordingly to be able to form sufficient striking distances between the contact pieces. A simple enlargement of the known outdoor switching device allows the moving mass of the swing arm to increase sharply. If one uses filigree elements for mass reduction, there is a risk that the pivoting arm will become unstable and contact with the contact pieces will only be unreliable.

Thus, it is an object of the invention to provide an open-circuit switching device, which allows safe contact with the contact pieces even with an increased outdoor switching path.

According to the invention the object is achieved in an outdoor switching device of the type mentioned above in that the pivot arm is mounted on a screw jack.

An open-air switching device is a switching device which uses atmospheric air to represent an outdoor switching path between relatively movable contact pieces. Atmospheric air has an average dielectric strength, so that to achieve a secure isolation of different electrical potentials leading contact pieces, they are spaced from each other accordingly. Depending on the position of the contact pieces, the open air section may have different impedances. The open-circuit switching path has an impedance with contacting contacts, which should tend towards zero. For remote contact pieces, the outdoor switching path has an impedance that should tend towards infinity.

By connecting a swivel arm with a lifting gear is given the opportunity by means of the lifting gear to remove the swivel arm for producing a high impedance outdoor switching path (separation line) together with the first contact piece mounted thereon of the second contact piece and for electrical contacting of the two contact pieces with each other, the swivel arm to be moved thereto first contact piece in the direction of the second contact piece. By means of the lifting gear, it is possible to vary the pivot point about which the pivot arm is pivotally movable, in its position relative to the second contact piece. The lifting gear moves a pivot point of the pivot arm between a contacting position and a separating position. The fulcrum can be moved to contact the contact pieces to a preferably fixed contact piece. To produce a safe separation distance in the open-circuit switching path, the pivot point can be moved away from a preferably stationary contact piece. Thus, the possibility is given to design the pivot arm short, so that a pivoting of the pivot arm is only necessary within a small space. Thus, the swivel arm can be constructed comparatively filigree, so that only small masses are herumzuschwenken around the fulcrum. Due to the reduced length of the swivel arm, a sufficiently stable swivel arm can be formed even with a filigree structure. The mass to be pivoted is reduced and reliable contacting of the contact pieces is possible. It is possible to optimize the screw jack in terms of mechanical stability, since this moves the bearing point with a swivel arm in the room. A contact / separation of the contact pieces is completed by a pivoting movement of a pivoting arm.

It can be provided that the lifting gear and the pivot arm are independently controlled in their movements. For example, movements of the swivel arm and the lifting gear can take place in succession. However, it is advantageous if the movement of the swivel arm and the movement of the lifting gear superimpose each other at least in sections, so that a resulting movement of the second contact piece is composed of a movement of the lifting gear and a movement of the swivel arm. Thus, it is possible to move the contact piece on a trajectory different from a circular path.

It can be provided that a synchronization of the movements of swivel arm and lifting gear takes place. For example, it can be provided that, depending on the distance covered by the lifting gear, the swivel arm covers a specific swivel angle. In this case, a direct proportionality between the movement of the lifting gear and the pivoting movement of the swivel arm can be provided.

A further advantageous embodiment may provide that the screw jack emits a linear movement.

By means of the lifting gear it is possible to deliver a linear movement. This linear movement can be transmitted to the swivel arm, for example. The linear movement can be transmitted by a correspondingly robust construction, so that a linearly displaceable platform for a rotary mounting of the swivel arm is provided on the lifting gear. As a screw jack, for example, a spindle gear can be used, which convert a rotary motion into a linear stroke movement in a simple manner and so deliver a rotational movement proportional stroke to a seated on the spindle nut. In addition, however, other forms of transmission can be used. For example, the screw jack can be telescopic. The lifting gear and / or the swivel arm can be formed as part of a current path, so that contacting of the first contact piece arranged on the swivel arm takes place via a swivel arm designed as a current path.

Advantageously, it can further be provided that the pivot arm has a pivot point at a free end of the lifting gear.

A pivot point for the pivot arm at a free end of the lifting gear makes it possible to spend the fulcrum as close as possible to the environment of the second contact piece. By means of the swivel arm, the last remaining piece of the outdoor switching path can then be bridged until the two contact pieces are in electrically conductive connection. A position of the fulcrum at a free end makes it possible to spend the fulcrum as free as possible of conversions or attachments in the vicinity of the second contact piece.

A further advantageous embodiment may provide that the fulcrum is movable on a substantially linear trajectory.

A method of fulcrum along a linear trajectory makes it possible to keep lateral accelerations away from the fulcrum. Preferably, the pivot point should be designed in the form of a rotation axis, which is aligned radially to the linear trajectory. As a result, forces in a linear direction can be initiated directly in the bearing of the fulcrum. Tilting and possibly accidental pivoting of the pivot lever by lateral forces in a non-linear method of the fulcrum is avoided.

A further advantageous embodiment may provide that the lifting gear is a toggle mechanism, in particular a scissors gear.

A toggle mechanism has holmartige lever elements which are hinged together and can be pulled apart accordion-like or pushed together. Thus, the possibility is given to vary the lifting height of the lifting gear, for example, on the one hand by the number of lever elements to be deflected or, moreover, to change the axial extent of the lever elements. Thus, a comparatively large stroke can be generated in a compact space. Furthermore, it is advantageous in the case of a scissors transmission that it can execute a substantially linear movement freely in space, since the lever elements / pivoting elements support one another. Guide elements such as supporting frames, scenes or other components, which would be positioned along the path of the lifting gear, are not required in a scissors gear. The existing on a scissors gear toggle support each other. Thus, there is a possibility to freely move the scissors gear in the direction of the second contact piece and to move away from it. Disturbances of the dielectric strength of an outdoor switching path are not to be expected by the scissor gear. A scissors gear can be designed in various ways. Scissor elements can cross each other and be rotatably connected at the intersection. However, it can also be provided that the scissors elements are divided into coupled toggle lever. This has the advantage that sub-arms of the toggle can be hinged stationary pivotally, so that a rotational movement stationary in the sub-spars are einteilbar, so that a movement can be transmitted to Oberholme the toggle. The toggle can be oriented in opposite directions and driven in opposite directions, so that the free ends of the toggle stabilize each other and deliver a linear movement. So can be formed by means of two toggle a pair of scissors.

A further advantageous embodiment may provide that the toggle mechanism, in particular scissors gear, at least one upper beam and a lower beam, wherein the pivot arm is connected to the upper beam.

A scissors gear has at least one upper spar and a lower spar, which are rotatably connected to each other and thus form, for example, a knee lever. As a result, a pair of scissors are formed, with the upper beam of the swivel arm is connected. Swivel arm and upper beam can be connected to each other with angular rigidity or rotation. At the top of the pivot point of the pivot arm can be arranged.

Advantageously, it can further be provided that the first contact piece is a Einschlagkontaktstück.

An embodiment of the first contact piece as a Einschlagkontaktstück allows the first contact piece to move freely through the room and to let in the second contact piece, which acts as a counter-contact piece. The first contact piece, for example, bolt-shaped, knife-shaped, tulip-like, slot-shaped with contact fingers, etc., be configured. A Einschlagkontaktstück needed for its function a counter contact piece, which applies a counter force to allow a resilient contact of the two contact pieces. By using a Einschlagkontaktstückes it is possible to move the swivel arm at the free end through the room. A counterforce is provided by the mating contact piece. Thus, the first contact piece can be kept structurally simple and gripping arms, etc. can be avoided on the first contact piece. Advantageously, the second contact piece should be stored stationary.

A further advantageous embodiment may provide that the second contact piece is surrounded by an annular shield electrode.

Through the use of an annular shield electrode, it is possible to shield the contacting region of the first and second contact piece dielectrically. Thus, as contact pieces, for example, sharp-edged blade contact pieces can be used. The annular shield electrode prevents the occurrence of discharges within the shielded area. The second contact piece can be arranged approximately centrally in the ring electrode. By a pivoting movement of the pivoting arm and a superposition of this pivoting movement with a linear lifting movement, the first contact piece can dip into the screen area of the ring electrode. Since the movement of the first contact piece is composed of a superposition of a linear and a pivoting movement, in particular in the formation of the first contact piece as a blade contact a pivoting driving into the second contact piece is made possible. In addition, a thrust movement takes place transversely to the direction of impact. Thus, the contact region of the two contact pieces can be positioned within the shielded region of the ring electrode. The pivoting first contact piece can be moved by a stroke into the interior of the ring electrode.

A further advantageous embodiment may provide that the toggle mechanism, in particular scissors gear, has force-reducing countermass pieces.

The toggle mechanism with upper and lower beam can be equipped with force-reducing countermass pieces, so that a movement of the moving spars is supported by the countermass pieces. Thus, when a switch-on of the open-air switching device, the necessary driving force to move the transmission elements can be reduced. The movement is supported by gravity-driven countermass pieces. Conversely, in the case of a switch-off movement, it is counteracted against the force of the countermass pieces, so that a switch-off movement is slowed down by the countermass pieces. For example, it is possible to quickly move the toggle mechanism in a switch-on supported by the countermass pieces and decelerate a movement of the toggle mechanism by the countermass pieces during a switch-off, so that deformation of the toggle mechanism are avoided. Alternatively or additionally, a movement can be supported or braked by a spring. Springs can be used individually or in packages. The design of the spring can vary. Thus, tension springs, compression springs, torsion springs, etc. can be used.

A further advantageous embodiment may provide that the pivot arm is connected at an obtuse angle with an upper beam of the toggle mechanism, in particular the scissors gear.

An obtuse-angled attachment of the pivot arm to an upper beam makes it possible to reduce unloading of the pivot lever transversely to the stroke direction. Thus, the pivot lever in the direction of the linear movement of the lifting gear in relation to its lateral unloading perform a relatively large swing. Furthermore, it is possible to manufacture the pivot arm and the upper beam of the toggle mechanism / scissors gear in one piece, so that over the upper spar electrical contacting of the free end of the pivot lever located first contact piece is possible. Thus, in addition contact transitions in the region of the pivot point of the pivot lever are avoided.

A further advantageous embodiment may provide that the upper beam is folded in a pivot point of the pivot arm.

A fold in the pivot allows a spacing of the first contact piece of the screw jack. Thus, a safety distance is formed by the first contact piece to the lifting gear, which prevents a striking of the first contact piece to the lifting gear.

A further advantageous embodiment can provide that the outdoor switching device is a grounding switching device.

The use of an open-circuit switching device as a grounding switching device makes it possible, for example, under outdoor conditions on outdoor-insulated switchgear or outdoor transmission lines grounding of phase conductors. For example, it can be provided that the first contact piece permanently leads to ground potential, wherein a contacting of the first contact piece via the pivot lever and the screw jack can be done. For this purpose, for example, be provided that elements of the Hubgetriebes and the pivot lever itself are electrically conductive formed as a grounding current path. However, it can also be provided that pivoting lever and screw jack are accompanied by a reversibly deformable grounding current path, which leads a ground potential up to the first contact piece. A grounding switching device can be arranged for example on an electrically insulating support insulator, which serves as a chassis for the lifting gear and the swivel arm.

The outdoor switching device can be designed for example as a single-pole open-air switching device. However, it can also be provided that the outdoor switching device is designed as a multipolar, in particular three-pole, outdoor switching device. In the case of a multi-pole open-circuit switching device, a number of pivoting levers and lifting gears corresponding to the number of phase conductors are to be used, which for example serve to form a respective separate grounding current path to each of the phase conductors of a multi-phase electrical power transmission network.

In the following, an embodiment of the invention is shown schematically in a drawing and described in more detail below. It shows the

1 a perspective view of an outdoor switching device, the

2 a detail of in the 1 shown outdoor switching device and the

3 a plan view of the in the 1 illustrated outdoor switching device.

The 1 shows a perspective view of an outdoor switching device in the form of a grounding switching device. The outdoor switching device has a first post insulator 1 on. The first support insulator 1 is exemplary here as a columnar first support insulator 1 represented, which is supported on a foundation. The longitudinal axis of the first post insulator 1 is vertically aligned. At its end for supporting the foundation is on the first support insulator 1 a base plate 2 arranged. The base plate 2 serves to position a drive assembly 3 , For actuating the drive arrangement 3 is at the base plate 2 furthermore a drive cabinet 4 arranged. In the drive cabinet 4 are arranged means of moving the drive assembly 3 serve. In the drive cabinet 4 For example, an electric motor can be arranged, which converts an electrical energy into a movement that is due to the drive arrangement 3 is transmitted. Furthermore, control and monitoring units, protective devices, locking devices, etc. may be arranged in the drive cabinet.

The drive arrangement 3 has a lifting gear 3a and a swivel arm 3b on. The design of screw jack 3a and swivel arm 3b are in the 2 and 3 shown in more detail. In the 1 is the drive arrangement 3 shown schematically.

At the free end of the swivel arm 3b is one in the 1 not shown in detail first contact piece 5 arranged. The drive arrangement 3 is subjected to ground potential, so that the first contact piece 5 permanent earth potential leads. Between the first contact piece 5 and a second contact piece 6 is an air-insulated switching path (outdoor switching path) arranged. The second contact piece 6 is electrically isolated from the first contact piece 5 arranged. For holding the second contact piece 6 is a second post insulator 7 intended. The second support insulator 7 is analogous to the first post insulator 1 attached to a foundation and at its end remote from the foundation end is the second contact piece 6 rigidly attached. The second contact piece 6 is electrically conductive with a phase conductor 8th connected. Between the phase conductor 8th and the second contact piece 6 is formed a permanent composite, so that the second contact piece 6 always has the same electrical potential as the phase conductor 8th , In the present case is the phase conductor 8th designed as overhead line. In addition to using a separate second post insulator 7 for positioning the second contact piece 6 Alternatively, alternative support elements can be used to the second contact piece 6 to position. For example, to support the phase conductor 8th provided insulation arrangements, the second contact piece 6 position. In this case, the use of a separate second post insulator 7 not necessary. Regardless of the type of positioning of the second contact piece 6 should be the second contact piece 6 held rigidly, so that the second contact piece 6 relative to the first post insulator 1 / the base plate 2 immovable.

To enable the use of the outdoor switching device under high and high voltage, is the second contact piece 6 from a ring electrode 9 surround. The ring electrode 9 is in the present case designed in the manner of a toroid. The ring electrode 9 leads the same electrical potential as the second contact piece 6 , Inside the ring electrode 9 is a field-free space formed. Inside of the ring electrode 9 dielectrically shielded space is the second contact piece 6 arranged with its contact region, so that when contacting with the first contact piece 5 a contact is made within the dielectrically shielded room.

The 2 shows an example of the configuration of the drive assembly 3 in a side view. The lifting gear 3a is presently executed in the form of an oppositely deflecting toggle aufeisenden scissors gear. The scissors gear has a lower beam 10 as well as an upper beam 11 , The lower beam 10 is pivotable with its one end to the base plate 2 attached. At its other end is the lower spar 10 with one end of the upper spar 11 via a so-called middle joint 12 connected. For a guide of the middle joint 12 to assist on a circular path are mirror-symmetrical to the longitudinal axis of the first post insulator 1 against another another upper spar 11a as well as another lower beam 10a arranged. The other sub-spar 10a is in turn with its one end to the base plate 2 pivoted. At the other end is the further lower spar 10a over another middle joint 12a with one end of the other upper spar 11a connected. The other end of the other upper Holmes 11a is with the other end of the Oberholms 11 over a universal joint 13 connected. The lower beam 10 and the other sub-spar 10a , the upper beam 11 as well as the additional upper beam 11a thus each form a toggle that over the universal joint 13 are connected to each other, so that in an opposite direction of rotation of the lower spar 10 as well as the further Unterholmes 10a a lifting movement of the universal joint 13 he follows. The universal joint 13 moves on a substantially linear trajectory. The two toggle levers are part of a scissors gearbox.

A linear trajectory of the lifting gear 3a / Universal joint 13 is in the direction of the longitudinal axis of the first post insulator 1 aligned. To a movement of the lifting gear 3a to assist are at the lower beam 10 as well as on the other lower beam 10a each countermass pieces 14a . 14b arranged. The countermass pieces 14a . 14b generate during a lifting movement of the lifting gear 3a a counterforce to the moving sub-beams 10 . 10a as well as Oberholmen 11 . 11a , This is the for moving the drive assembly 3 reduced energy consumption.

The universal joint 13 represents a pivot point for the swivel arm 3b available, with the swivel arm 3b along the trajectory of the universal joint 13 with the universal joint 13 is displaceable. Preferably, a pivot point of the pivot arm should 3b in the area of the universal joint 13 be arranged. Thus, a pivoting of the swivel arm 3b allows a pivot point, which along the trajectory of the movable universal joint 13 is displaceable. Around the pivot point of the swivel arm 3b is the swivel arm 3b pivotable. As a result, the first contact piece 5 around the pivot point of the swivel arm 3b be moved on a circular path.

By an overlay of the swivel arm 3b on the first contact piece 5 producible circular path and the linear trajectory, which by the Hubgetriebe 3a is provided, the second contact piece is on a along the stroke of the lifting gear 3a curved trajectory moves. In the 2 are the corresponding trajectories of the middle joints 12 . 12a of the universal joint 13 and a resulting trajectory of the first contact piece 5a represented by dash-dotted lines. A pivoting movement of the swivel arm 3b can be time independent of a movement of the lifting gear 3a be executed. So it is possible, for example, that initially the screw jack 3a a linear displacement of the pivot point of the pivot arm 3b causes and subsequently (or vice versa) a pivoting of the pivot arm 3b is triggered and a contact of the two contact pieces 5 . 6 he follows. However, it can also be provided that a movements of the lifting gear 3a and the swivel arm 3b takes place at the same time, so that the first contact piece 5 resulting in a resultant movement resulting from a superposition of a through the Hubgetriebe 3a caused linear trajectory and one of the swivel arm 3b composed circular path composed. In the embodiment according to the 2 is a synchronized movement of lifting gear 3a and swivel arm 3b intended. This is ensured here by the fact that the swivel arm 3b angularly rigid with the other upper beam 11a connected is. In the present case, the other upper beam 11a a linear elongated rod shape, wherein the pivot arm 3b also has a linear elongated rod shape. In the pivot point of the swivel arm 3b push the swivel arm 3b and the other upper beam 11a to each other, wherein between the longitudinal axes of the other upper spar 11a and the swivel arm 3b an obtuse angle is included. Thus, the first contact piece 5a from the mechanics of the lifting gear 3a removed, causing damage to the same through the mechanism of the lifting gear 3a can not occur.

The first contact piece 5 is presently designed as Einschlagkontaktstück. The first contact piece 5 is designed to bolt-shaped, this pin in a counter-shaped second contact piece 6 is taken to the end of a movement. The second contact piece 6 In this case, it is positioned at a fixed angle in such a way that it applies a counterforce in order to contact the first contact piece 5 to enable.

The 3 shows a plan view of the drive assembly 3 to 2 , For a favorable guidance of the upper spar 11 as well as the other Oberholmes 11a to allow, are the lower beam 10 as well as the further sub-spar 10a each carried out twice, so that these congruent lying one behind the other bearings for the middle joints 12 . 12a provide. In the axial direction of the middle joints 12 . 12a are between the pairs executed Unterholmen 10 or other sub-bars 10a , the upper beam 11 or the other upper beam 11a rotatable with the respective middle joint 12 . 12a connected. The upper beam 11 and the other upper beam 11a support each other in the universal joint 13 , Only one of the upper spars 11 . 11 is with the first contact piece 5 over the swivel arm 3b rigidly connected.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 602005000144 T2 [0002]

Claims (12)

Outdoor switching device with an outdoor switching path, with a first contact piece ( 5 ), with a second contact piece ( 6 ), wherein the first contact piece ( 5 ) by means of a drive arrangement ( 3 ) relative to the second contact piece ( 6 ) and on a swivel arm ( 3b ) of the drive assembly ( 3 ), characterized in that the swivel arm ( 3b ) on a screw jack ( 3a ) is stored. Outdoor switching device according to claim 1, characterized in that the lifting gear ( 3a ) gives off a linear motion. Outdoor switching device according to one of claims 1 or 2, characterized in that the swivel arm ( 3b ) at a free end of the lifting gear ( 3a ) a fulcrum ( 13 ) having. Outdoor switching device according to claim 3, characterized in that the fulcrum ( 13 ) is movable on a substantially linear trajectory. Outdoor switching device according to one of claims 1 to 4, characterized in that the lifting gear ( 3a ) is a toggle mechanism, in particular a scissors gear, is. Outdoor switching device according to one claim 5, characterized in that the toggle mechanism, in particular scissors gear, at least one upper beam ( 11 . 11a ) and a lower beam ( 10 . 10a ), wherein the swivel arm ( 3b ) with the upper beam ( 11 . 11a ) connected is. Outdoor switching device according to one of claims 1 to 6, characterized in that the first contact piece ( 5 ) is a Einschlagkontaktstück. Outdoor switching device according to one of claims 1 to 7, characterized in that the second contact piece ( 6 ) of an annular shield electrode ( 9 ) is surrounded. Outdoor switching device according to one of claims 1 to 7, characterized in that the toggle mechanism, in particular scissors gear, force-reducing countermass pieces ( 14a . 14b ) having. Outdoor switching device according to one of claims 7 to 9, characterized in that the swivel arm ( 3b ) at an obtuse angle with an upper spar ( 11 . 11a ) of the toggle mechanism, in particular scissors gear, is connected. Outdoor switching device according to claim 10, characterized in that the upper beam ( 11 . 11a ) in a fulcrum ( 13 ) of the swivel arm is folded. Outdoor switching device according to one of claims 1 to 11, characterized in that the outdoor switching device is a grounding switching device.

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