EP2764526A1 - Switching-device tripping apparatus - Google Patents

Abstract

The invention relates to a switching-device tripping apparatus for a switching device (1) has contact pieces (2, 3) that can be moved relative to one another. Relative motion between the contact pieces (2, 3) is generated by means of a transmission assembly. The transmission assembly has a pawl (7) in order to control motion of the contact pieces (2, 3) relative to each other. A first and a second tripping means (11, 12) are provided, which work against the same pawl (7) and drive the same pawl (7).

Description

description

The invention relates to a switching device tripping device for a switching device with relatively movable contact pieces, comprising a gear arrangement for generating a relative movement between the contact pieces with a pawl and with a to an actuation of the

Pawl against the pawl movable trigger.

Such a switching device tripping device is known for example from the utility model DE 297 15 900 Ul. The switchgear tripping device there provides for use of a gear arrangement for operating a switching device with contact pieces movable relative to one another, the gear arrangement having a pawl and a movable triggering means being used to actuate the pawl. The known switching device tripping device has for a switching device with a plurality of switching poles for each switching pole je ^¬ Weils a pawl and an associated release means. Thus, it is possible to synchronize the release means with each other and to trigger the plurality of switching poles approximately time ^¬ equal or to set a desired time offset of triggering switching movements at the individual switching poles of the switching device. A disadvantage of all ^¬ recently that the entire switching device falls at a failure of a switching device triggering device to one of the switching poles from ^¬. Such failures should be avoided.

It is therefore an object of the invention to provide a switching ^{device trigger ¬ device} , which has an increased reliability. According to the invention, the object would be achieved in a Schaltgeräteaus ^¬ release device of the type mentioned in that a first triggering means and a second triggering means drive the same pawl. An electrical switching device is for example a Leis ^¬ processing circuits, which serves an interrupt or a producing a current path between two current path sections. As such, a switching device, for example rela ^¬ tively mutually movable contact pieces. For interrupting and for producing a current path of a Relativbewe ^¬ movement between the contact pieces is to be produced. So it is for instance possible that for producing a current path of the two contact pieces approach each other and finally a galvanic contact with the same is carried out, so that a ge ^¬ connected current path. In the opposite case, when opening a current path, a distance between the two relatively movable contact pieces from each other superiors see so that finally a galvanic separation dersel ^¬ ben carried out. Accordingly, a separation point is formed in the current path and the current path is interrupted.

The electrical switching device can be carried out unipolar or multipolar. A single-pole switching device is to be ^¬ aimed to connect a single current path. A mehrpoli ^¬ ges switching device has a plurality of switching poles. A multi-pole switching device can be used to switch several current paths of a multi-phase electric power transmission network. Accordingly, switching movements of the individual take place

Switching poles of a multi-pole switching device temporally ^{aufeinan ¬} matched.

Depending on the configuration of the electrical switching device, switching on or off of the switching device is connected to one another with comparatively rapid relative movements of the contact pieces. This may need to be available to perform a switching operation quickly within a few mil ^¬ lisekunden. Usually, therefore, storage devices are used which can be charged for a relatively long period of time. The cached in the storage device energy may be delivered in a shorter time ^¬ space, as charging of the tank supply direction. Proven, for example, mechanical storage, such as spring storage, wel ^¬ che have at least one memory spring, which is stretched for charging and can be relaxed to produce a relative movement of the switching contact pieces to each other abruptly.

Memory springs can be used in various designs. For example, coil springs, coil springs, bar springs, gas springs, etc. can be used. For example, a tensioning of the storage spring or a release of the storage spring can be carried out by a gear arrangement. The storage spring is part of the gear arrangement, wherein the energy taken from the storage spring during relaxation is converted into a movement of a movable contact piece or a plurality of movable contact pieces. In order to allow easy release of a tensioned storage spring, the gear assembly is further equipped with a pawl, which holds the storage spring in the tensioned state or blocks. A pawl can example ^¬ include a mechanism which allows blocking of a tensioned spring, wherein a small amount of energy is necessary to release the tensioned spring. In ^¬ example, the pawl a multi-part mechanism such. B. have a toggle construction, which is brought by a trigger means for burglary. The pawl is movable by a trigger means, wherein the tensioned memory spring is released by a BEWE ^¬ tion of the pawl. Accordingly, by means of the gear arrangement for generating a relative movement between the contact pieces of the switching device, a release of a cached force can be made, which serves to drive at least one of the contact pieces. Preferably, a movement of a triggering means should cause a switch-off, ie a separation of the relatively movable contact pieces.

If one uses now a first and a second release means, which are movable against the same pawl or the same Drive pawl, so it is possible to increase the reliability of the switching device tripping device. Even in the event of a fault in one of the triggering means, it is possible for the remaining triggering means to cause only a movement of the triggering means

Pawl causes. The two triggering means are designed ^¬ the art that each of the trigger means one alone can muster from ^¬-reaching energy to the pawl to be ^¬ due and release energy temporarily stored in the following one in a storage device. The two tripping devices should be connected in parallel mechanically.

A further advantageous embodiment can provide that the release means are each mounted linearly displaceable. Slidable mounting of the release means allows space-saving designs to be selected to position the release means within the gear assembly. By a linearly displaceable mounting a completed in the direction of the displacement axis of the trigger means stroke can be delivered to the pawl in a simple manner. Thus, it is mög ^¬ Lich to drive the pawl directly and immediately by the two triggering means and so to dispense with intermediate construction ^¬ groups of a kinematic chain. As a result, an increased reliability of the operation is achieved. In addition to a direct driving of the pawl on the trigger means and an indirect or indirect drive of the pawl can be provided on the release means. For example, a movement of a triggering means can be conducted via a kinematic chain. Thus, an immediate spatial proximity of release means and pawl is not absolutely necessary. As parts of a kinematic chain Kgs ^¬ NEN example, lever, push rod, bolts, gears,

Racks, chain hoists, cables, etc. are used. A further advantageous embodiment may provide that the first trigger means are driven by a first drive means and the second actuating means through a second Antriebsein ^¬ direction. The use of a first drive device and a second drive device for each one of the release means has the advantage that regardless of the state of the one triggering means, the other release means can remain operable. For this purpose, the drive devices should independently develop their force effects. As drive means, for example, electrodynamic actuators, pneumatic actuators, hydraulic drives, etc., which are able to initiate a Be ^¬ movement of the activation means in response to a driving signal suitable. Advantageous ha ^¬ this electrodynamic drives ben proven, since this high in compact designs restoring forces can exert on the Auslösemit ^¬ tel. Furthermore, a control of an electrodynamic drive is comparatively easy. The drive devices can be controlled by one and the same control device. However, it can also be provided that independently operating control devices in each case control the first drive device or the second drive device. Advantageously, it should be provided that the control of the two drive means takes place as possible at the same time. This can be achieved, in particular, by providing a common control device for both drive devices, so that the same pulses can be used to drive the first and second drive devices. However, it can also be provided that two control devices operating according to different criteria are used which, for example, operate according to different algorithms and thus additionally reduce a malfunction of a switching device triggering device.

Furthermore, it can advantageously be provided that the first and the second drive device independently exert a ne force effect on the respectively associated release means. If the two drive devices each act independently on the respective triggering means, it is possible for each of the triggering means to exert a force on the pawl independently of the other triggering means. Thus, the pawl of each of the tripping ^¬ tel, regardless of the operating state of the other from ^¬ solvent or its associated drive means, cause a movement of the pawl. A further advantageous embodiment may provide that the second triggering means with the interposition of the first Auslö ^¬ semittels against the locking pawl is movable.

If the switching device drive device is set up such that the second triggering means interposition of the first

Triggering means against the locking pawl is movable, so for example a space-saving solution for the switching device triggering device can be found. The two release devices are connected mechanically in series. Characterized in that the second triggering means with the interposition of the first Auslö ^¬ semittel is movable against the locking pawl, the first triggering means is part of a kinematic chain, which serves a force and motion transmission from the second triggering means to the pawl. In addition, a driving force can also be coupled in the course of the kinematic chain in the kinematic chain via the first drive means. Thus, the force effects of both trigger means can overlap each other to increase the force on the pawl. However, it can also be provided that the second release means helps to overcome one of the first Losreißmoment From ^¬ solvent means. Particularly in the case of relatively seldom switching switching devices, it may happen that the transmission device or the release means are blocked in their bearings. For example, greases and oils can harden, metal parts can corrode and bearings become so stiff. By a mechanical series connection of the two triggering means, a setting of the first triggering means by the additional force effect of the second triggering means can be exceeded. sores and the switching device tripping device are made operational again.

A further advantageous embodiment can provide that axes of movement of the first and second release means are aligned parallel, in particular coaxially to each other.

In particular, in the case of a linearly displaceable mounting of the triggering means, the triggering means should be aligned as parallel as possible, in particular coaxially with one another. A par ^¬ allelität makes it possible to allow forces acting in the direction of BEWE ^¬ supply Saxony of the two tripping means acting similarly to the Ver ^¬ riege lung jack so mechanically simple locking latches can be constructed, the egg can muster nerseits great holding power for a tensioned storage spring and on the other hand, can release the memory spring by smaller actuating forces. In particular, in the case of a coaxial alignment of the movement axes of the triggering means, it is also possible, for example, to operate the locking pawl in a simple manner via the second triggering means with the first triggering means being interposed. For example, the release means may be designed essentially in the shape of a bolt, wherein the bolts are aligned axially one behind the other and one bolt can be driven in the axial direction against the other bolt.

Furthermore, it can be advantageously provided that the second triggering means is guided on the first triggering means. In particular, with increasingly required miniaturization of drive devices and thus also of switching device tripping devices with a gear arrangement, it is necessary to position the individual modules closer together. If you use now that the first release means to cause the second release means or to store, can at ^¬ paid the necessary bearing elements are reduced. In ^¬ example, the first triggering means may have a groove or a recess on which the second triggering tel supported or on which the second trigger means is guided.

Furthermore, it can be advantageously provided that the second triggering means projects into a recess of the first triggering means, in particular passes through.

The use of a recess, for example a sleeve on said first trigger means makes it possible to allow the second trip means, for example, a variable position the recess durchset ^¬ zen. The recess can also serve to guide the triggering means to one another, in particular to support or support the second triggering means on the first triggering means. The second release means may be rotatably and / or displaceably mounted in the recess, in particular a bushing. Thus, the first release means, which in turn is supported on a bearing device are used to partially ^¬ as lead, the second releasing means at least designed so that a separate storage device for the second trigger means comprises at least simplified or can be completely eliminated by this. For example, it can be provided that the recess allows a linear movement of the second triggering means, so that in the Nut ^¬ tion of two linearly displaceable release means are both parallel, in particular coaxially guided to each other. It may be further advantageous if the first release means is a ro ^¬ tationssymmetrischer body and the recess coaxially penetrates the first trigger means to the rotation axis. Advantageously, it can be provided that the first Auslö ^¬ semittel the second releasing means at least partially engages around hohlzy ^¬ lindrisch.

The first release means may be at least partially hollow cylindrical, wherein the hollow cylindrical running portion of the first triggering means surrounds the second Auslö ^¬ semittel. By encompassing a recess is formed, which, for example, the leadership of the second Solvent serves. For example, the first trigger ^¬ tel at least partially hollow cylindrical, wherein the wall thickness in the hollow cylindrical portion of the first triggering means may be designed differently. The hollow cylindrical portion can for example have a circular ^¬ annular cross-section, a rectangular, oval, polygonal, etc. cross-section. Advantageously, the first triggering means as well as the second triggering means should be rotationally symmetrical.

Furthermore, it can advantageously be provided that at least one of the release means is arranged as an armature on a drive element designed as a plunger coil. A drive element serves to cause a movement of a triggering means. The drive element thus converts an energy form into kinetic energy. Advantageously, electrodynamic drives have been shown for the conversion of electrical energy into mechanical energy, since they are well controllable or controllable. The use of a plunger coil as a drive element makes it possible to directly impart a linear motion to the triggering means designed as an armature. The armature may for example be mounted linearly displaceable along an axis, wherein the armature dips into the plunger coil and is moved out of the plunger coil. Restoring forces can be generated for example by Rückstellfe ^¬ countries, gravity, etc., to move the armature back to a rest position. Upon actuation of the triggering means designed as an armature, it is moved out of its rest position in order to bring about a movement or release of the pawl. For this purpose, the anchor is moved indirectly or directly against a force introduction point of the pawl. After release of the pawl, the triggering device is returned to its rest position. In the following, an embodiment of the invention is sche ^¬ matically shown in a drawing and described in more detail below. It shows the

Figure 1 shows a first embodiment of a switching device tripping device, Figure 2 shows a second embodiment of a switching device tripping device, the

Figure 3 shows a third embodiment of a switching device tripping device, the

Figure 4 parts of a fourth embodiment of a

Switching device tripping device in unassembled state and the figure 5 the fourth Aus ^¬ management variant of a switching device tripping device in the assembled state known from the Figure 4 in parts.

In FIGS. 1, 2, 3 and 5, the illustrated embodiments of a switching device tripping device are shown by way of example with different gear arrangements. The gear assemblies are schematically drawn and executed single ^¬ Lich exemplary. The gear arrangements shown in the figures and elements thereof are interchangeable. In the figures, equivalent components are therefore provided with the same reference numerals. In addition, alternative design variants of a gear arrangement can be used. The figures are to serve with the gear arrangements shown there a simplified understanding of the effectiveness or use of a switching devices ^¬ tripping device. 1 shows a first embodiment of a

Switching device triggering device, in which a switching device 1 is shown schematically. The switching device 1 has a first contact piece 2 and a second contact piece 3. The first contact piece 2 is presently arranged stationary. The second contact piece 3 is designed to be linearly displaceable, so that between the first and the second contact piece 2, 3 a relative mobility (see double arrow) is given. The contact piece 3 is coupled to a storage spring 4 so that a switch-off movement, ie a separation of the two contact pieces 2, 3, is driven by energy, which is taken from the tensioned storage spring 4. The memory spring 4 is part of a gear arrangement for generating the relative movement between the contact pieces 2, 3. The memory spring 4 is ^presently executed in the form of a Schraubenfe ^¬ , which is mounted stationary. For tensioning the accumulator spring 4, an electric motor 5 is provided. The electric motor is provided 5 is connected via a kinematic chain 6 with the SpeI ^¬ cherfeder. 4 The kinematic chain 6 has a cable, which is about a by the electric motor. 5

driven shaft is wound. Thus, it is possible to perform spring tension work on the accumulator spring 4 by operation of the electric motor 5 and to tension the accumulator spring 4.

The following functional description of the release means as well as their interaction with the other modules also applies in an analogous manner to the embodiment variants of FIGS. 2, 3 and 5. Therefore, the modules that exercise the same radio ^¬ tion, provided with the same reference numerals. In the tensioned state, the accumulator spring is blocked by a pawl 7, so that a relaxation of the accumulator spring 4 is possible only after an actuation of the pawl 7. The pawl 7 is designed as a one-piece locking bolt. A relaxation of the accumulator spring 4 takes place abruptly, so that a sudden relative movement between the two Contact pieces 2, 3, in particular in the course of a switch-off occurs. Is to enable a corresponding abrupt for drinks ^¬ NEN the storage spring 4 is in the kinematic chain 6 for example to provide a decoupling module to the driven shaft so as to prevent a braking effect on the kinematic chain 6 or by the electric motor. 5

The pawl 7 is mounted linearly displaceable. A linear displaceability is possible in the direction of an axis 8. By way of example, a displacement direction of the locking pawl 7 according to the figure 1 by the pawl 7 is ^¬ arranged extending in the direction of the axis 8 elongated holes 9 is set, the long holes 9 are penetrated by guide pins 10 degrees. The guide pins 10 are each end equipped with threads, so that the guide pins 10 can be attached egg ^¬ nerseits to a base plate and ^¬ on the other hand on the guide pins 10 by means of nuts screwed on the respec ^¬ tive thread removal of the pawl 7 of the Guide pin 10 is prevented.

For driving the pawl 7, a first trigger means 11 and a second trigger means 12 are provided. The two release means 11, 12 are bolt-shaped, wherein the bolts of the release means 11, 12 are guided displaceably in each case in an iron core 13. The iron cores 13 perform each ^¬ weiligen triggering means 11, 12 wherein the triggering means 11, 12 are arranged linearly displaceable parallel to the axis 8 parallel to axis 8. The iron cores 13 can function egg nes the triggering means 11, 12 housing enclosing percep ^¬ men. The two release means 11, 12 are each formed as a plunger armature of a plunger coil 14, which serves as a drive ^¬ element. A plunger coil 14 is an electrodynamic drive element with an armature. The respective triggering means 11, 12 serve as anchors of the respective plunger coils 14. FIG. 1 shows the position of the triggering means 11, 12 in the rest position. By means of a respective coaxial with the release means 11, 12 arranged return spring 15, the two release means 11, 12 are each pressed to the pawl 7 in their rest positions. Instead ei ^¬ ner use of a return spring 15 to generate a restoring force, alternative devices may be used to advertising. For example, the release means 11, 12 "fall back" by ih ^¬ re weight force into their rest positions. An abutment for the outgoing of the return spring 15 force and stops for the end positions of the triggering means 11, 12 are provided by the respective iron core 13. The release means 11, 12 are provided at their facing of the pawl 7 from ^¬ end with a radially projecting shoulder, each of which alternately abut against the stops of the end positions of the respective iron core. 13 in an energization of the voice coil 14, a magnetic force acting on the respective actuating means is carried out 11, 12, whereby the triggering means 11, 12 are moved against the force of jeweili ^¬ gen return spring 15 in the direction of the locking pawl. 7 the release means 11, 12 make each a Li-linear stroke in the direction of the axis 8, beat on the pawl 7 at force application points and move the pawl 7 toward As a result, the pawl 7, the tensioned storage spring 4 free. The SpeI ^¬ cherfeder 4 relaxes suddenly and abruptly opens the switching path between the two contact pieces 2; 3.

After the release of the memory spring 4, the energization of the plunger coils 14 ends. The two release means 11, 12 are moved back by the force of the respective return spring 15 in its rest positions. Furthermore, a reverse pawl return spring 17 also causes a return movement of the pawl 7, so that the pawl 7 is again ready to hold the tensioned storage spring 4 after a tensioning of the accumulator spring 4 in order to release this accumulator spring 4 after triggering by the release means 11, 12 release and generate a switching movement or relative movement between the contact pieces 2, 3. The first triggering means 11 and the second triggering means 12 each have independently acting drive elements in the form of plunger coils 14, so that in the event of failure of one of the plunger coils 14 or blocking one of the triggering means 11, 12 the respective other non-disturbed triggering means 11, 12 or the undisturbed plunger coil 14 can perform an actuation of the pawl 7. The two release means 11, 12 act independently on the same pawl. 7

FIG. 2 shows the switchgear tripping device known from FIG. 1, wherein the configuration of the detent pawl varies. Again, the use of a memory spring 4 is provided, which can be tensioned by means of an electric motor 5 via a kinematic chain 6, wherein a Blockie ^¬ ren of the tensioned memory spring 4 is provided by means of a pawl 7. In the figure 2, the relaxed position of the accumulator spring 4 is shown, wherein the contact pieces 2, 3 are shown in the open position. Dash-dotted on the accumulator spring 4 is an extended position of the accumulator spring 4 symbolized in the tensioned state, wherein the pawl 7 blocks the accumulator spring 4 in the tensioned state. In the following, only the alternative embodiment of a pawl 7 will be discussed. The pawl 7 in this case has a two-armed stationary mounted lever 18. The stationary lever 18 is pivotable about a fixed pivot point, so that the pawl 7 can release a tensioned Spei ^¬ cherfeder 4. With one arm of the stationary lever 18, a connecting rod 19 is connected. The connecting rod 19 connects the stationary lever 18 with an angle lever 20. The angle ^¬ lever 20 is fixedly mounted, wherein the angle lever 20 of a first and with a second release means 11, 12 be ^¬ wegbar. Force application points of the two release means 11, 12 are located on the angle lever 20 of the pawl 7. By a movement of the release means 11, 12 is a BEWE ^¬ tion of the pawl 7 causes, similar to the embodiment described in Figure 1 causes a relaxation of a tensioned accumulator spring 4 , The to move the trigger semittel 11, 12 necessary assemblies are analogous to the building ^¬ groups of Figure 1 executed and therefore provided with the same reference numerals. In contrast to Figure 1, the pawl 7 is designed in the form of a lever chain.

In Figures 3 and 5 each show a principle depicting ^¬ lungs Verklinkungsmechanik and the gear assembly. Equivalent components are provided with the same Bezugszei ^¬ Chen, as in Figures 1 and 2. Since the function is analogous to Figures 1 and 2, only the manner of the design of tripping means and drive means to the figures 3, 4 and 5 will be described in more detail.

FIG. 3 shows a force introduction point of two triggering means 11, 12 on a pawl 7. The locking pawl ^¬ 7 is pivotable about a fixed bearing point. A first trigger means 11 and a second triggering means 12 are arranged axially one behind the other, wherein the at ^¬ the triggering means 11, 12 are configured in each case bolt-shaped. It is provided that the second release means 12 with the interposition of the first triggering means 11 against the pawl 7 is movable to the pawl 7 to swing ^¬ ken. Accordingly, it is provided that the respectively executed in the form of plungers release means 11, 12 are arranged lying behind each other, that the plunger of the second trigger means 12 is driven in a movement from its rest position into a release position against the first triggering means 11 and thus, for example in case of failure of the plunger coil 14 of the first triggering means with the interposition of the first release means 11, the pawl 7 is actuated. Accordingly, it is provided that in the iron core 13 of the first triggering means 11, a coaxial with the axis 8 formed recess is seen ^¬ through which the second triggering means 12 can protrude into the interior of the iron core 13 of the first triggering means 11, so that a force effect from the second triggering means 12 to the first triggering means 11 can be exercised. If both release means 11, 12 are set in motion by the plunger coils 14, then the total of The force effect, which can be generated by one of the plunger coils 14, however, is dimensioned such that even in case of failure of the plunger coils 14 sufficient for actuating the pawl 7 Kraftwir ^¬ kung can be caused by a single plunger coil 14. Even with failure of the plunger 14 of the first trip ^¬ means 11 creates a force on the second triggering ^¬ medium 12 and a displacement of the first triggering means 11 in the direction of the axis 8 to the pawl 7. The second triggering means 12 moves the first triggering means 11 toward the axis 8 against the pawl 7 and with the interposition of the first triggering means 11, an actuation of the pawl 7 is effected by the second triggering means 12. In the reverse case in case of failure of the plunger coil 14 of the second trigger means 12, the second trigger means 12 remains at rest and only the first trigger means 11 moves the pawl 7. The two trigger means 11, 12 act on the same force application point (indirectly or directly) on the Pawl 7 a.

In the following, a modular construction of release means as well as plunger coils and iron cores will be described in more detail with reference to Figures 4 and 5.

4 shows the structure of the iron cores 13 of a first and a second triggering means 11, 12. The iron cores 13 and the drive means for the first and second Auslö ^¬ semittel 11, 12 are each listed identically. Therefore, the structure of the iron core 13 and drive means 14 of the first Auslösemit ^¬ means of 11 will be described by way of example with reference to Figure 4 by way of example in the following. The iron core 13 is arranged rotationally symmetrical to a longitudinal axis 8 and has a first sub-element 13a and a second sub-element 13b. The two sub-elements 13a, 13b are contacted to each other supplied ^¬ facing end faces, said end faces are oriented perpendicular to the axis. 8 In the mutually ^{¬ facing} end faces are annular circumferential recesses introduced, which serve to receive a lying between the two part ^¬ elements 13 a, 13 b of the iron core 13 immersion coil 14. The plunger coil 14 is so ^¬ bet in the iron core 13 and aligned coaxially to the axis 8. The iron core 13, in particular its first partial element 13a is a steering system of a producible by the plunger 14 of the Magnetfel ^¬.

In the direction of the axis 8, the iron core 13 is centrally penetrated by a continuous recess, which has substantially cylindrical inner circumferential surfaces, wherein meh ^¬ rere projecting shoulders to form attacks for the first trigger means 11 are provided. In the present case, the first triggering means 11 is designed as a hollow cylinder which is slidably mounted in the first subelement 13a of the iron core 13. Thus, the first triggering means 11 can be moved in the direction of the axis 8. At its end lying within the iron core 13, the first triggering means 11 is formed radially widened, so that projecting shoulders are formed, which are attached to opposing stops of the iron core 13 in the end positions z. B. abut in a rest position. The radial extension of the first release means 11 is a hollow cylinder formed, wherein a Außenmantelflä ^¬ surface of the radial extension is slidably guided in an equal and opposite inner lateral surface of the second element 13b of the iron core ^¬. 13 Due to the radial expansion, the free mobility of the first triggering means 11 in the direction of the axis 8 is limited on the first triggering element 11. Thus, on the one hand a rest position of the first triggering means 11 can be taken in the iron core 13, wherein the first triggering means 11 is retracted almost completely in its rest position in the iron core 13. In order to securely hold the first triggering means 11 in its rest position, a return spring 15 is provided which supports the radial extension of the first triggering means 11 on the first subelement 13a of the iron core 13 against a protruding shoulder of the second ^subelement 13b of the iron core 13. Thus, it is possible that when energizing the plunger coil 14, the first Actuating means 11 immersed in the immersion ^¬ coil 14 against the force of the return spring 15, where ^¬ the first triggering means 11 emerges from the front end of the iron core 13 and after stopping the energization of the plunger coil 14 by the restoring force of the tensioned rear ^¬ 15 is a return movement of the first triggering means 11 in its rest position. As previously for Figure 1 being ^¬ leads can be omitted, a return spring or an alternative apparatus can be used.

The first releasing means 11 is equipped with a recess 21 from ^¬ which extends coaxially to the axis 8 and the first release means 11 passes completely through. At its end remote from the radial extension, the first release means 11 is provided with an internal thread 22. Through the recess 21, the first triggering means 11 is designed in the form of a socket, so that the socket can serve for example a guide or storage, for example, a second triggering means 12.

The second releasing means 12 comprises a base body wel ^¬ cher corresponds to its construction according to the first trip means. 11 In an internal thread 22 of the recess 21 of the main body of the second triggering means 12, a rod 23 is screwed, which completes the second triggering means 12 ^¬ benefits. The rod 23 is aligned as well as the main body of the second triggering means 12 coaxial with the axis 8. The rod 23 has a cross section such that the ^¬ ser is inserted into the recess 21 of the first triggering means 11 in the manner of a clearance, so that the rod 23 is slidably mounted in the recess 21 of the first triggering means. Thus, a bearing bushing on the first triggering ^¬ medium 11 is given for the second triggering means 12. Thus, a first and a second release means 11, 12 are formed, which each deliver a linear movement and each act on the same pawl or these antrei ^¬ Ben, the two release means 11, 12 coaxial with each other are aligned, that is, the first triggering means 11 surrounds the second triggering means 12 at least partially outside coat side, wherein each of the two release means 11, 12 is drivable via a separate drive means.

FIG. 5 shows the arrangement with rod 23 known from FIG. 4, which passes through the socket of the first triggering means 11. The two iron cores 13 of the two triggering means abut each other in the direction of the axis 8 and are aligned with each other. The rod 23 or the two ^¬ th trigger means 12 is mounted on the rod 23 of the second trigger ^¬ by means of 12 to the first triggering means 11. The at ^¬ the triggering means 11, 12 are at one end face of one of the iron cores 13, here of the iron core 13 of the first Auslösemit- means of 11, the pawl 7 faces, each of said Auslö ^¬ semittel 11, 12 may act directly on the pawl. 7 Thus, there is the possibility that both the first release ^agent 11 and the second triggering means 12 can effect a movement of the pawl 7 independently of the state of the respective other triggering means or its plunger coils, return springs, etc. The first and the second trigger ^¬ medium 11, 12 act at almost the same force initiation point ^¬ the pawl 7 on this one. So tilting and tilting are avoided, the pawl 7 can be a

Perform pivoting movement.

Claims

claims

1. Switching device triggering device for a switching device (1) having contact pieces (2, 3) movable relative to one another, comprising a gear arrangement for generating a relative movement between the contact pieces (2, 3) with a pawl (7) and with a to an actuation of Pawl (7) against the pawl (7) movable release means (11,12), characterized in that

a first trigger means (11) and a second trigger means (12) driving the same pawl (7).

2. Switchgear drive device according to claim 1,

d a d u r c h e c e n c i n e s that

the release means (11, 12) are each gela ^¬ siege linearly displaceable.

3. Switchgear drive device according to claim 1 or 2, characterized in that a

the first trigger means (11) via a first Antriebseinrich ^¬ device (14) and second trigger means (12) via a second drive means (14) are driven.

4. Switchgear drive device according to claim 3,

d a d u r c h e c e n c i n e s that

the first and second drive means (14) independently exert a force on the respective associated release means (11, 12).

5. Switchgear drive device according to one of claims 1 to 4,

d a d u r c h e c e n c i n e s that

the second triggering means (12) is movable against the locking pawl (7) with the first triggering means (11) being interposed.

6. Switchgear drive device according to one of claims 1 to 5, characterized in that

Movement axes (8) of the first and second release means (11, 12) parallel, in particular coaxially aligned.

7. Switchgear drive device according to one of claims 1 to 6,

d a d u r c h e c e n c i n e s that

the second release means (12) is guided on the first release means (12).

8. Switchgear drive device according to one of claims 1 to 7,

d a d u r c h e c e n c i n e s that

the second triggering means (12) projects into a recess (21) of the first triggering means (11), in particular passes through it.

9. switching device drive device according to one of claims 1 to 8,

d a d u r c h e c e n c i n e s that

the first release means (11) at least partially surrounds the second release means (12) in a hollow cylindrical manner.

10. Switchgear drive device according to one of claims 1 to 9,

d a d u r c h e c e n c i n e s that

at least one of the triggering means (11, 12) designed as an armature of a plunger coil (14) drive member (14) is integrally arranged ^¬.