DE3524526A1 - Locking device having a locking armature to prevent a switching apparatus being operated inadvertently - Google Patents

Abstract

A locking device (10) for a switching apparatus having an electromagnetic drive (1) has a locking lever (11) which can be laid against a stop (17) by means of a restoring force (14). In this quiescent condition, an end surface (18) of the locking lever (11) is opposite an operating surface (19) which is fitted to a drive lever (7) which carries the armature (6) of the magnetic drive (1). When the magnetic drive (1) is energised, the locking lever (11) (which consists of a soft-magenetic material) is pivoted about its bearing and its end surface (18) is in consequence moved out of the region of the operating surface (19). The switching apparatus can then switch on normally. The locking lever (11) in contrast remains in its quiescent position and prevents the contact elements of the switching apparatus being operated if disturbing forces occurs such as, for example, shocks and vibration or an increased air pressure in the case of vacuum contactors. <IMAGE>

Description

The invention relates to a locking device a locking anchor against inadvertent actuation of a Switchgear with electromagnetic drive, in particular a vacuum contactor.

A locking device of this type is through the DD-PS 2 12 614 become known. The locking anchor is here Part of a blocking relay, the field winding of an auxiliary current depending on the actuation of the Switching device is flowed through. The auxiliary current can both impulsive as well as synchronous with the actuation of the Switchgear.

In another known locking device (EP-A-0 121 963) also becomes an electromagnetic one Locking relay used, in the control circuit a device for Er Detection of the mechanical loads on the switchgear is switched. This device is for electromagnetic Triggers of switching devices are provided and should in particular Incorrect triggering of the switching device due to vibrations prevent. As a switch-on lock for electromagnetically operated Switchgear, this locking device is less ge is suitable.

The invention is based on a locking device direction of the type mentioned the task, a reliable locking device  create that works without an auxiliary current and therefore no separate control circuit required.

According to the invention, this object is achieved in that the locking anchor as under the influence of a magnetic field Magnetic drive of the switching device against a restoring force around a bearing pivotable locking lever is formed and in unexcited state of the magnetic drive with one end face a working surface of a movable part of the magnet driven with a small in relation to its working stroke Distance is arranged opposite. To operate the The locking lever thus becomes the magnetic field of the magnetic drive of the switching device. This by no means means one Restriction for the spatial arrangement of the locking lever, because both the main field and the stray field of the magnet drive can be used for the present purpose and so that there is the possibility of independent of the locking lever to use a certain type of magnetic drive. The effectiveness of the new locking device is based on the fact that from the mass of the moving parts of the Magnet drive and the spring forces acting on them resulting movement resistance is greater than the loading resistance to movement of the locking lever and thus this sets in motion faster than the drive parts. On this ensures that the switching device at normal operation on and off unhindered can be. Against the unintentional actuation the switching device, d. H. the closing of the main contacts, safely avoided without excitation of the magnetic drive because the locking lever maintains its position and thereby the Switch-on movement of the drive parts blocked. Outer sturgeon influences, e.g. B. shocks or increased air pressure in the vicinity of vacuum switching devices, can not harmful.  

It has proven advantageous to close the locking lever with a coil of the magnetic drive with parallel to the Er extension of the lines of force of the coil lying axis of the Arrange camp. The magnetic drive has two spatial coils arranged in parallel, it is recommended that Arrange the locking lever in the space between the coils. In both The end surface of the locking lever moves, which are transverse to the working movement of the magnetan's armature drives and therefore with simple means for the desired locking can be used. The one with the End surface of the locking lever cooperating work surface can thereby on the armature of the magnetic drive or on the armature supporting lever may be formed or it can with the Anchor or the drive lever separate locking body verbun be that.

The locking lever is particularly effective to achieve that the locking lever in a recess a drive lever carrying the armature of the magnetic drive the switchgear arranged and the work area formed by a paragraph within the recess is. An equally safe response of the locking lever is also to be effected in that the armature of the magnet with the air gaps of the magnetic circuit of the locking lever shortening auxiliary pole is provided. This can be in one piece with the anchor or as a separate part be trained.

For a reliable function of the locking device it is important that the locking lever on the one hand if possible is low-mass, but on the other hand one possesses sufficient mechanical strength to withstand the fault absorb forces occurring without deformation  can. This can be achieved in that the locking lever U-shaped in cross section and at rest against an attack in the over-dead center position with respect to the Introduction of a force through the movable part of the magnet drive is arranged to be applied. The stop will be adjustable, so the locking device adjust easily after assembling.

It is particularly important to have a switching device against one To protect incorrect operation by shock loads, so a version of the interlocking clean is suitable for this direction in which the bearing axis the locking lever on the End face away from the center of gravity of the lock levers and where the focus is on the side of the bearing axis facing away from the magnetic drive located. With this arrangement, shocks act in Meaning of maintaining the rest position of the locking lever.

However, according to a further embodiment of the Ver riegelunseinrichtung the arrangement chosen so that the Bearing axis the locking lever near its center of gravity prevails and the focus is on that of the Magnetan Drive side facing, so you get a labile Execution that leads to a particularly quick response of the Locking lever leads to the magnetic field of the magnetic drive. This version is advantageous if the magnet drove the switching device from a relatively low mass leadership with appropriate characteristics of movement has running.

The invention is explained in more detail below with reference to the exemplary embodiments shown in the figures. Figs. 1, 2 and 3 show a magnetic actuator of an electromagnetically operated switching device. Here show the

Fig. 1 and 2 is a side view of the magnetic drive in the open position or in the switched-on position. The

Fig. 3 is a plan view in the direction of the pole faces of the magnetic drive, the armature and a drive lever carrying it are omitted.

The

FIGS. 4 and 5 show a further embodiment of a locking device according to the invention, in a in Figs. 1 and 2 corresponding representation.

In the

FIGS. 6 and 7, another embodiment of a locking device is shown, wherein the armature of the magnetic drive is provided with an auxiliary pole.

In the

Fig. 8 and 9 is based on FIGS . 1 and 2 corresponding representations a different execution of a locking lever shown.

The magnetic drive 1 according to FIGS. 1, 2 and 3 comprises a magnetic yoke 2 with legs 3 on which coils 4 are arranged. In the switched-off state, the pole faces 5 are opposed by an armature 6 which is attached to a drive lever 7 . This can be pivoted about a schematically represented axis of rotation 9 , the distance from the coils of which is shown shortened for purposes of illustration within the drawing area. One or more switching sections of a switching device are actuated in a known manner by the drive lever 7 . As an example of this, a vacuum interrupter 8 is shown schematically in FIGS . 1 and 2, which is actuated by means of likewise known and therefore not separately shown transmission parts by the drive lever 7 .

In FIG. 1, the armature 6 is the pole face 5 over a distance so that the contacts of the vacuum interrupter 8 are opened. In Fig. 2 the armature 6 is shown attracted to the pole surface 5 and the contacts of the vacuum interrupter 8 are closed as a result.

As can be seen when looking at FIGS. 1 and 2, the vacuum interrupters 8 can also be actuated purely mechanically, ie without energizing the magnetic drive 1 . This can e.g. B. by shocks or vibrations. Furthermore, this can happen when the surrounding air pressure increases and the opening force thereby increased by the vacuum interrupters 8 completely or partially overcomes the deactivation spring 9 of the magnetic drive 1 shown schematically in FIGS. 1 and 2. The two disruptive influences can also occur together. In order to prevent undesired actuation of the vacuum interrupter in such cases, a locking device 10 is provided, which is described in more detail below. An essential part of the locking device 10 is a made of a soft magnetic material, for. B. sheet steel, be standing locking lever 11 , which is shown in Figs. 1 and 2 in section. FIG. 3 shows that the locking lever 11 has a U-shaped cross-sectional shape. The locking lever 11 is pivotally mounted about a bearing pin 12 , which is held in a likewise U-shaped bracket 13 . A pivot spring 14 surrounding the bearing pin 12 is supported with its central part 15 on the locking lever 11 and with its legs 16 on the bearing bracket 13 . In this way, the locking lever 11 is placed in the idle state against an adjusting screw 17 serving as an adjustable stop.

In the switch-off position according to FIG. 1, an upper end surface 18 of the locking lever 11 faces a working surface 19 of a locking piece 20 with a small distance. This distance is significantly smaller than the working stroke that the drive lever 7 with the armature 6 between the switch-off position according to FIG. 1 and the switch-on position according to FIG. 2. If the drive lever 7 is moved by any disruptive influence in the direction of the switch position, the working surface 19 of the locking piece 20 hits against the end surface 18 of the locking lever 11 and thereby limits the movement of the drive lever 7 to a value necessary for closing the contact pieces of the vacuum switch tube 8 is not sufficient. As can be seen, the locking lever 11 is in relation to the introduction of a force by the locking piece 20 in an over-center position, so that the force introduced into the locking lever 11 is predominantly guided via the bearing pin 12 to the bracket 13 .

In normal operation of the switching device, the excitation of the coils of the magnetic drive 1 not only attracts the armature 6 with the drive lever 7 , but also the locking lever 11 at the same time. This has a significantly lower mass compared to the drive lever 7 and is consequently pivoted against the force of the torsion spring 14 into the position shown in FIG. 2 before the working surface 19 can strike the end surface 18 of the locking lever 11 . This ensures unimpeded switching on. When the excitation current of the magnetic drive 1 is interrupted, the drive lever 7 with the armature 6 and the locking lever 11 return to the position shown in FIG. 1.

To ensure the fastest possible response of the locking lever of the locking device, the air gaps in the magnetic circle of the locking lever can be shortened. To this end, FIGS. 4 and 5 an embodiment of the locking device, in which a dipping compared with FIGS. 1 and 2 extended executed lock lever 25 in a recess 26 of a drive lever 27. In this recess there is a shoulder 30 which forms the working surface which cooperates with an end surface 31 of the locking lever 25 . As can be seen, the upper end of the locking lever 25 is opposite the armature 6 of the drive lever 27 with a relatively short distance as a result of this embodiment. This increases the pulling force acting on the locking lever 25 when the magnetic drive is excited. The high acceleration of the locking lever therefore allows a relatively small distance between the end surface 30 and Ar beitsfläche 31 and thus gives a great security against unintentional actuation of the switching device. In the switched-on position, the parts assume the position shown in FIG. 5, in which the locking lever 25 projects through the recess 26 .

A shortening of the air corresponding to FIGS . 4 and 5 of the magnetic circuit of the locking lever is however also possible with a relatively short embodiment of a locking lever corresponding to FIGS . 1 and 2 if, according to FIGS . 6 and 7, an auxiliary pole on the armature 6 35 is attached. This is designed so that it is overlapped by the U-shaped locking lever in the switched-on position, as shown in FIG. 7. Also in the embodiment according to FIGS. 6 and 7, the locking lever 37 and a working surface forming shoulder 40 of the locking piece 41 ge selects a relatively small distance between the end face 36 of.

In the exemplary embodiments of locking devices described above, the locking lever is designed such that the center of gravity designated S is located between the bearing pin and the end face of the locking lever and on the side of the bearing pin facing away from the coils. This ensures that impacts acting on the locking lever can only affect the maintenance of the rest position of the locking lever. The mass force attacking at accelerations in the center of gravity S of the locking lever causes a torque around the bearing bolt, which acts in the same sense as the restoring force. This design, which can be described as stable, of a locking device is therefore particularly suitable for those cases in which switching devices are exposed to strong shocks or impacts.

In contrast, the locking lever 45 in FIGS . 8 and 9 is designed so that the center of gravity S is in the space between the bearing pin 12 and the coils of the magnet drive. Furthermore, the focus is closer to the bearing pin than in the previously described embodiment examples. The changed position of the center of gravity S is essentially achieved in that the locking lever is mounted in the reverse position, ie that the middle part of the U-profile is on the side facing the magnetic drive of the bearing pin. The changed position of the center of gravity has the consequence that forces caused by impacts counteract the restoring force. As a result, the locking lever can be set in motion more quickly by the magnetic field of the magnetic drive and can therefore be used in conjunction with quickly responding magnetic drives or those in which there is a particularly small space between the working surface of the drive lever and the end surface of the locking lever.

Claims (8)

1. Locking device ( 10 ) with a locking armature ( 11 ) against unintentional actuation of a switching device with electromagnetic drive ( 1 ), in particular a vacuum contactor, with electromagnetic drive ( 1 ), characterized in that the locking armature as under the influence of the magnetic field of a magnetic drive ( 1 ) of the switching device against a return force ( 14 ) around a bearing ( 12 ) pivotable locking lever ( 11 ) is formed and in the unexcited state of the magnetic drive ( 1 ) with an end face ( 18 ) of a working surface ( 19 ) of a movable part ( 7 ) of the magnetic drive ( 1 ) is arranged opposite each other with a small distance in relation to its working stroke. ( Fig. 1, 2, 3) 2. Locking device according to claim 1, characterized in that the locking lever ( 11 ) is arranged close to a coil ( 4 ) of the magnetic drive ( 1 ) with the axis of the bearing ( 12 ) lying parallel to the extension of the lines of force of the coil ( 4 ). ( Fig. 1, 2, 3) 3. Locking device according to claim 2, characterized in that the locking lever ( 11 ) is arranged in a magnetic drive ( 1 ) with two spatially parallel angeord Neten coils in the space between the coils ( 4 ). ( Fig. 3) 4. Locking device according to claim 1, characterized in that the locking lever ( 25 ) in a recess ( 26 ) of the armature ( 6 ) of the magnet drive drive lever ( 27 ) of the switching device is arranged engaging and the work surface by a paragraph ( 31 ) within the recess ( 26 ) is formed. ( Fig. 4, 5) 5. Locking device according to claim 1, characterized in that the armature ( 6 ) of the magnetic drive with an air gap of the magnetic circuit of the locking lever ( 37 ) shortening auxiliary pole ( 35 ) is provided. ( Fig. 6, 7) 6. Locking device according to claim 1, characterized in that the locking lever ( 11 ) in cross-section U-shaped and arranged in the rest position against a stop ( 17 ) in the dead center position with respect to the introduction of a force by the movable part of the magnetic drive ( 1 ) arranged is. ( Fig. 1, 2, 3) 7. Locking device according to claim 1, characterized in that the bearing axis passes through the locking lever ( 11 ) on the end face ( 18 ) facing away from the center of gravity (S) of the locking lever ( 11 ) and that the center of gravity (S) on the magnetic drive ( 1 ) facing away from the bearing axis ( 12 ). ( Fig. 1, 2, 3, 4, 5, 6) 8. Locking device according to claim 1, characterized in that the bearing axis ( 12 ) sets the locking lever ( 45 ) in the vicinity of its center of gravity (S) and that the center of gravity (S) is on the side facing the magnet drive ( 1 ) . ( Fig. 8, 9)