DE2158978A1 - DRIVE FOR ELECTRIC SWITCHES - Google Patents

Description

Drive for electrical switches The invention relates to a Drive for electrical switches, each with one operator energy storage device for switching on and off.

switch off, with one end of two, in the same direction acting Beaern attached to one, these springs together tensioning spring lever is, and the other end of the one operator engages directly on the gear lever, while the force of the other spring is applied via the spring lever and a push rod reaches the gear lever.

pie The object of the invention is to provide a drive, in particular for High-voltage circuit breaker, as wear-resistant as possible, i.e. with a high switching frequency and yet with little manufacturing effort, while maintaining economic dimensions, so small-scale, to create.

The task is far-reaching; it can only be solved, if all drive parts from the energy stores to the operr and release device, and the way in which the force is introduced and how it is transmitted is systematically investigated and be improved. Particularly suitable for this is as the entrance mentioned drive considered0 It is improved according to the invention in that the Spring lever designed as a one-armed lever and its clamping angle on the drive shaft is only about half as large as the corresponding switching angle of the shift lever the switch shaft.

This can be done in a simple manner through the length and shape of the levers achieve, but offers the advantage of designing the switching springs for a low Resilience. The effective length of the switch lever to the switch shaft can be at a Such a large switching angle is advantageous from a minimum to a maximum value can be used, with this effective lever length corresponding to the force required for the switching operations can be precisely adjusted; For example, it can be at the end of the bin line or at the end of the Elimination should be chosen large0 It probably does not need to be particularly emphasized be sure that no energy is wasted unnecessarily by this measure, and consequently the locking and release forces are also limited to a necessary level0 Otherwise the drive according to the invention allows the force to be advantageously applied via a cam 0 As is well known, one can use a cam to set the various Power requirement of the operator to be clamped in connection with the respective effective lever lengths balance. This is particularly important here because the manufacturing costs for the Tensioning device is known to be lowest when the winding torque is over the entire opann time can be kept constant. Such a cam is but only achieve reasonable dimensions if a correspondingly small opannwinkel accrues. With such a tension angle, the length of the spring lever inevitably increases, in order to achieve the necessary resilience. But this is where the invention comes into play the one-armed spring lever for the bearing pressure of its shaft. Would namely the switch-off spring attached to a separate lever arm, so that e.g. levers displaced around 1800 would be formed, so not only would be considerable Bearing pressures occur in the ßinschaltstellung, but also a very space and Material costs. On the other hand, it is easy to see that the new drive Switch-off spring can only exert low forces on the spring lever mounting.

The locking and release device needs special mention of the drive. According to the invention, the storage power is not mainly in it held on the usual half-shafts, but on a support lever in the direction transferred to its storage point in such a way that it is still in it after its unlocking a torque applied for its pivoting to release the storage force will.

All of the accompanying drawings are first shown in FIGS. 1-3 Function of the known drive system described. In the wivig. o and 7 is then the essence of the inventive drive shown, whereby, better understanding because of, partly the designation functionally identical parts of the known drive are given in brackets.

According to Fig. 1, the arc extinguishing device is located in a switch pole 1 2, as well as the stationary plug-in contact 3 and the stationary sliding contact 4. In the latter sic is in the off position of the switching pin 5, which is straight downwards can be pushed through to the two contacts 3 and 4 electrically in the on position to be conductively connected, the bolt 6 is attached to the upper end of the switching pin 5, which is in the frictional connection to the fork 7 at the free end of the switching arm 80 The latter is arranged freely rotatable on the stationary switching point 9, it is at a standstill but in a positive connection to the shift lever 10 and the locking lever 11O All the free end of the switching lever 10 is the lower end of the closing spring 12 hung up on the free one End of spring lever 13 or is hung near it. Binding rod 14 with elongated hole 15 holds the closing spring 12 on bias and forms almost to the left of the spring lever 13 for pivoting relaxed closing spring 12 a non-positive push rod connection of the Pedal lever 13 to the shift lever 10.

The spring lever 13 is freely rotatable on the stationary drive shaft 16 stored, but is available to the spring lever 17 and the drive lever 18, as well the locking lever 19 in frictional connection.

At the free end of the control lever 17 is the lower sand of the opening spring 20 hooked, which is hooked with its upper collar in the fixed bearing 21.

The bias of the opening spring holds in the position shown 20 the switch pin in the stop of the switch position. The is still fixed Switching pin in this position by the locking lever 11, its free pivoting movement is prevented by the half-shaft 22 rotated into the blocking position. The latter can over the release lever 23 can be rotated into the pulp position.

If the drive lever 18 according to Fig. 2 is pivoted to the right in the direction of the arrow, then the Zinschaltfeder is tensioned 12 and the switch-off spring 20o The blocked switching arm 8 can this movement do not follow.

The pivoting of the drive lever 18 is continued until the locking lever 19 in connection with the half-shaft 24 arrives in a locking position.

If now according to Figo 3 via the release lever 23, the half-shaft 22 in Release position rotated, then the rotatable system can turn on the selector shaft 9 under the influence of force pivot the switch-on spring 12; it an activation takes place.

The half-shaft 24 is now in the release position via the release lever 25 rotated, then under the influence of the force of the switching spring 20, the movable system pivoted on the drive shaft 16, this movement is under the frictional connection the rod 14 is transferred to the movable system of the shift shaft 9 and it takes place one switch-off O The entire system returns to the switch-off position shown in Sigo 1, the switching cycle is complete.

As can be seen from the description; leads the drive lever 18 at Tension the two springs 12 and 20 a right turn and relax the Switching off spring20 a left turn. In this arrangement it is for hand or other forms of drive cannot be used, as there is a short circuit when switching suddenly springs back O In the event that the drive is a spring-action drive trained, doh. the. Activation takes place immediately after tensioning the springs, a lightning-like decoupling of the external drive force to this drive lever 18 are provided. Such facilities can only be implemented with expensive means Create wear-resistant, on the other hand, the border was raised, the external driving force to keep it as small as possible, doh. bring them in as evenly as possible without peak values, How this can be carried out expediently is shown in FIG.

The cam disk 27 is attached to a stationary shaft 26, on the outer jacket surface with a full Turn the roll 28 expires, which is rotatably mounted on the free end of the drive lever 18. In the event of a full revolution of the cam disk 27 caused by an external force is accordingly the drive lever 18 for tensioning the switching springs 12 and 20 to the right pivoted so that the frictional connection is canceled after latching and pivot the roller 28 back into the position shown in dashed lines in the event of a switch-off can.

The curve is designed in such a way that, taking into account the Seder characteristics, the transferring levers and their respective constellations for the elevator process t a constant torque is to be applied to the shaft 26.

Since the triggering forces for a disconnection are generally very low are, on the other hand, but also to reduce the wear of the half-shaft 24, sees the invention according to FIG. 5 at this point a force reduction, this is the roller 29 is freely rotatably mounted on the free leg of the locking lever 19; she is supported in the locked position on the support lever 30, which is freely rotatable on the Shaft 31 is stored0 You support surface is to the tangent of the swing circle of this Lever 30 slightly inclined, so that a rotary component for by the Aufstützkraft the lever 30 is generated. using lever 30- this force can only follow when the pawl 33 blocked by the half shaft 32 by actuating the release lever 34 is released. Only then does the roller 29 press the support surface of the support lever 30 down and gives the pivoting movement of the locking lever 19 to a disconnection frei0 The support lever 30 is extended by a further operating lever 35, on its the free end of the return spring 36 is attached is, which in turn on the lower end is attached to the stationary bearing 37.

Naturally, this power reduction system can also be applied to the Transfer locking lever 11.

There are also a number of mutual interlocks of the individual Movement limbs that switch off voluntary or involuntary incorrect manipulation, such as, for example, the further turning of the cam disk 27 after a spring winding or improper actuation of the release levers 23 and 25 etc. Kiese additional equipment but are not the subject of the invention.

In the structural design of the drive according to the invention Very useful simplifications result from FIGS. 6 and 7 Rod 14 with elongated hole 15 by a concentric to the closing spring 12 placed Telescope system 14 replaced. Furthermore, the spring levers 13 and 17 become a common one Lever formed0 Then the shafts 26 and 31 form a common shaft. Further the drive lever 18 is combined with the locking lever 19 and with a roller 29 equipped0 In Figs. 6 and 7 it is shown how in a space-saving manner let the individual components join together in a closed drive block. For a better overview, there are two longitudinal sections in two functional levels with the common Drive shaft 16, the support shaft 31 in structural unit with the shaft 26 and the Shift shaft 9 placed through the drive block. For better utilization of the closing spring 12 is the shift lever 10 angled 3ie rod 14 is functionally equivalent by a Telescope 14 replaced. The common spring lever 13, 17, on which the opening spring above 20 is suspended, forms with the drive lever 18 and the roller 28 a structural EiMheito The drive is shown in the switch-off position (diagram according to Sigo 1) * Accordingly, the roller 28 is in the deep relaxation of the cam disk 27. The latter is attached to the sprocket 38 and this is through the roller chain 39 and the chain pinion 40, which is mounted on the drive shaft 16, is driven and-can be operated by hand or motor drive.

In the Bigo 7, the locking lever 19 with the roller 29 can be seen, Furthermore, the support lever 30 in a structural unit with the pawl 33 with the Lever 35 is collapsed, as well as the half-shaft 32 and the return spring 36 the now denoted by 47 is this Xraftuntersetzungssystem for the opening trip in the present case is also provided for the switch-on triggering, it results analogies to the individual components: locking lever 19 and 41, roller 29 and 42, Support lever 30 and 43, pawl 33 and 44, half shaft 32 and 45 and lever 35 and 46.

Ä> ie the closing spring 12 carrying levers 10 and 13 are according to Fig. 6 designed and arranged so that during the switch-on process the closing spring 12 is continuously relaxed, which is thereby on the switching shaft 9 and thus the transferred to the movable switching elements not shown Torque continuously increases and a maximum value in the switch-on position having. That means on the one hand that the locking force for the cocked Spring has a minimum, but also that the spring itself with relative little manpower needs to be equipped. Conversely, this brings the Switch-off spring 20 at the beginning of the switch-off a particularly large switching torque on, accordingly, it also needs it, since it uses its maximum energy at exactly the right time Bringing steep slopes to use can also only be designed to be relatively small. This condition, that the two main energy stores manage with relatively little storage energy, wearing naturally essential for the economic design of the entire drive and underlines its special ability to cope with a high switching frequency.

Furthermore, the locking lever 41 is designed with a cam piece 48 with the task, after the half-wave 45 has been triggered, i.e. after pivoted Locking lever 411 the support lever 43 and thus the locking pawl 44 in 'their released position to hold so that when switching off an impact load on the levers 43, 44 is excluded.

A common return stop is designated by 49

Claims (10)

A n s p r ü c h e 1.) Drive for electrical switches with each SillOfl) Spring force accumulator for the input or Switching off, with one end of two springs acting in the same direction on one, these springs together tensioning Spring lever is attached, and the other end of a spring directly acts on the shift lever, while the force of the other Neither over the spring lever ulld-a push rod reaches the shift lever, characterized in that the Spring lever (13) designed as a one-armed lever and its clamping angle on the drive shaft (16) is only about half as large as the corresponding switching angle of the shift lever (10) on the switch shaft (9) 2.) Drive according to claim 1, characterized in that that the angled switching lever (10) is in the on position of the switch reaches the largest lever arm to the selector shaft (9). 3.) Locking and triggering device for the drive ach the claims 1 and 2, characterized in that the Storage power over a Roller (29, 42) of a locking lever (19, 41) almost at the center of the bearing point a support lever (30, 43) acts and pivots it after its release, so that the locking lever (19, 41) can roll freely to provide the storage power. 4.) Device according to claim 3, characterized in that the support lever (30, 43) via a pawl (33, 44) connected to it by a half-shaft (32, 45) is blocked or triggered. 5.) Device according to claims 3 and 4, characterized in that it is available for switching off and switching on, and the support levers (30, 43) with the pawls (33, 44) rotatable symmetrically to one another on a Shaft (31) are mounted and which also serve as a bearing for a cam disc (27) serves to tension the drive and its drive member (38, 39). 6.) Device according to claim 3 to 5, characterized in that the locking levers (19, 41) roll on a circular path on the support levers (30, 43). 7.) Device according to claim 3 to 6, characterized in that the locking levers (19, 41) carry a cam piece (48), each of which is associated with it Support levers (30, 43) with their pawls (33, 44) in their respective released position holds. 8.) Device according to claim 3 to 7, characterized in that the one locking lever (19) connected to the spring lever (13) in a force-locking manner a shaft (16) is mounted, which is also the bearing for a drive pinion (40) forms. 9.) Device according to claim 3 to 8, characterized in that a common return conveyor for their symmetrically arranged lever system (30, 33, 43, 44) (47) and a common back stop (49) is present. 10.) Drive according to claims 1 to 9, characterized by the use self-stabilized tension springs (12, 20) as energy stores.