DE4011443C2 - - Google Patents

Description

The invention relates to a high voltage power switch according to the features of the preamble of the An saying 1.

The one from a drive to the distant Switch poles leading power transmission elements usually consist of push-pull rods or swivel waves. The latter are difficult - with large masses executed and often bring problems with the elastic Twisting (vibrations) with itself.

Train-push linkage must also because of the neces against kink resistance with large moments of inertia - well heavy or elaborately profiled be.  

According to a drive device for a switch DE-AS 15 40 503 is between the actuating shaft and the Switching shaft an active connection in the form of a parallelogram produced. Two-armed levers sit on the shafts on, the ends of which are each articulated by means of tabs are connected. With this arrangement it should - by variation the tab length - be possible, the position of the actuating shaft to change.

In another known switch drive (DE-PS 6 95 051) is a common drive shaft for all phases available. The shaft is held by cranks twisted from a drive; other cranks direct the force into a cross-shaft Thrust for the switching pins of the switch poles.

The invention has in particular the task ge represents the masses of these power transmission elements to reduce significantly to material costs and to save drive energy; it is also desirable that that cannot be hermetically shielded from the environment steering gear requires little maintenance, especially without lubrication fabrics gets along.

This problem is solved with the mark the features of claim 1, namely with a Train-train linkage as a power transmission element with two parallel rods, which are centered at their ends fixed articulated levers are connected to each other, the respective bearing of the pole-side joint lever formed by the driven shaft and the metal articulated lever near the drive a triangular lever is, the free arm has a recess into which a straight connecting bolt with defin th, flattened and plastic-reinforced sliding flanks is used.

With a train-train linkage, they need the long sides of a parallelogram bar only pulls record and are therefore only for such a Bela interpretation. When switching on and off only one of the two rods is pulled at a time, since egg ne pressure load for the opposite one not possible; she would dodge and shorten their length. The invention could therefore be can also be realized with two rigid pull ropes. In which Linkage according to the invention is the moving mass e.g. B. only about 10% compared to that required for rotary shafts mass.  

Parallelogram linkages are known per se; them for the Mastering the underlying task at Lei to use control switches, may surprise, must with not insignificant powers in just a few mil be transmitted in seconds.

Another problem solution is on power transmission at the interface between drive and reversing gear directed. Here was through the interaction of Plastic and metal sliding elements a low-maintenance, because lubricant-free, yet low-wear Ver bond found. This claim is particularly one Just slide connection, in which the plastic polyoxi methylene (POM) with an aluminum alloy works. According to subclaims 2 and 3 therefore the articulated lever made of light metal and the connector POM application bolts are used.

Is used - according to subclaims 4 u. 5 - one in the pole carrier arranged non-rotatably, with which the connecting bolt is guided on a straight line is driven, so over this slide cross forces derived, and reaction forces in the drive kinematics are balanced.

With a three-pole switch with wide apart poles with one pole - expediently with middle - directly, i.e. without train-train linkage over the Slider and the only articulated lever on it Pol shaft acted from the drive. Should about this Connection also to the other external pole shafts are driven, so you get a space-saving Arrangement according to subclaim 8 when the pole shaft Grips crankcase of the middle pole housing. A  The articulated lever on which the drive acts is then opened placed on one pole shaft end and with the train-train Linkage of an external pole connected; on the another articulated lever sits at the other shaft end, the only with the other's pull-pull linkage poles is coupled. The middle pole shaft is here as a power transmission link for an outside related pole.

Embodiments of the invention are the accompanying Figures can be found, which are explained in more detail below will.

Show it:

Figs. 1 to 4 is a diagram of the drive kinematics of a circuit breaker, namely

Fig. 1, the switch-off of a three-pole switch with Einzelpolantrieben,

Fig. 2, the corresponding switch-on,

Fig. 3, the switch-off of a three-pole switch with all the poles the Common men driving element,

Fig. 4, the corresponding switch-on,

Fig. 5 is an elevation view, by a pole carrier in the loading area of the central pole in a switch with Einzelpolantrieben

Fig. 6 and 7 are views of the slider and

Fig. 8 the connecting bolt.

. Indicated in dashed lines - in practice upstanding insulator columns - in Figures 1 to 4 the circuit breaker poles 1, 2 and 3 are. They contain the movable contact pieces 4 , 5 , 6 . The poles are fastened to the box-shaped pole carrier 7 and plunge with their crankcase into them. On the underside of the pole carrier, a housing accommodating the drive 8 is fastened.

From the selected piston-cylinder arrangements A single drives of FIGS . 1, 2 and 5, the drive rods 9 , 10 , 11 protrude, which can be identical to the piston rods out and into the pole carrier 7 . They are moved approximately longitudinally to the polar axes for drive actions. The middle drive is arranged so that its drive rod 10 - seen transversely to the plane - is aligned along the axis of the center pole 2 . At the outside, from their drives to Poles 1 and 3 , the driving force must be brought in via a special reversing gear. For this purpose, train-train linkage with two parallel rods 12 , 12 'lying one above the other in the direction of the polar axis are used. These are connected at their ends with articulated levers, namely the articulated levers 13 , 13 'and the articulated levers 14 , 14 ', 14 ''. Basically, only a lever without joints, ie a crank lever 15 , would be necessary for the central pole. The latter is placed directly on the pole shaft 16 of the middle pole and stored there at the same time. Only in the all-pole drive shown in Fig. 3 and 4, a parallelogram linkage would be possible for all three poles, the central pole also containing an articulated lever 14 ''.

The drive-related articulated levers 13 , 13 'of Figures 1 and 2 are only rotatable on an axis 17 , 17 'on; while the articulated levers 14 , 14 'are worn by the pole shafts 16 ', 16 '' there. The actual switch actuation takes place in the interior of the pole housing via a transmission lever 18 articulated on the respective pole shaft.

The articulated levers are actually triangular levers and their respective free arms 19 , 19 'is coupled to one of the drive rods 9 , 10 , 11 for actuation purposes. The coupling is done with the help of a special Ver connecting bolt 29 which slides in a recess 28 of the arm 19 , 19 '.

When the drive or drives are activated, the articulated levers 13 , 13 ', 14 , 14 ', 14 '' or the crank lever 15 are pivoted and the rods 12 , 12 'are displaced relative to one another. Only one of the rods 12 , 12 'arranged one above the other in the polar axis direction takes over close to the entire driving force of a pole, in the form of a tensile load. It goes without saying that the articulated levers close to the pole or the crank lever each sit firmly on the pole shafts and twist them. The function of the kinematics is additionally illustrated by FIGS . 2 and 4, which represent the respective switch-off positions.

Is shown in Fig. 3 and 4, only one drive with a to rod 10, acting on the pole shaft 16 of the center pole, used to 1, it is recommended for each of the external poles, a separate train-train-Ge strands will FIG. to use. The corresponding articulated levers close to the pole are then placed on the middle pole shaft 16 . This passes through the pole housing in the loading area of the crankcase and protrudes on both sides with shaft ends (not visible). On one of these shafts then the articulated lever 14 '' is placed, and on the other an articulated lever which is designed like the articulated lever 14 , 14 '. The pole shaft 16 is thus used here as a force transmission element for an external pole.

In Fig. 5 a section through the box-shaped pole carrier 7 is placed at the point where the drive rods 9 , 10 , 11 of the individual drives with the articulated levers are coupled. For the sake of clarity, only one connection, namely that of the central drive shaft 10 with the crank lever 15 designed as an articulated lever, is shown completely. The connection is made via a slider 22 - in the Fig. 6 and 7 better visible Lich - in whose threaded bore 26, the drive rod 10 is inserted. It contains 23 bushings with bearing bores 24 on a cantilever part, with which it is pushed onto guide pins 25 which extend parallel to the drive rods in the pole carrier and is thus guided in a directionally stable and non-rotatable manner. The crank lever 15 is gripped by two fork-shaped jaws 27 , 27 '. It contains a recess 28 running along the lever. In this respect, the crank lever 15 with the free arms 19 , 19 'leads the articulated lever identically. A connecting bolt 29 - presented in more detail in Fig. 8 - passes through bores 30 in the jaws 27 , 27 'of the slider and the recess 28 of the articulated or crank lever. At opposite points of the shaft, the connecting bolt 29 has flattened sliding flanks 31 . With these he slides along the inner surface of the recess 28 - transmitting the driving force. The grooves 32 , 33 in the bolt are provided for suitable circlips and plain bearing inserts.

The connecting bolt 29 is preferably made of the plastic POM with embedded steel reinforcements, while the articulated levers 19 , 19 'and 15 cooperating with it are made of an aluminum alloy with an anodized surface.

The guide bolts for the articulated lever 19 , 19 'are indicated in Fig. 5 only by dot-dash lines. The slider 22 has the task of deriving transverse forces, which are introduced in particular by the drive rods 9 , 10 , 11 , via the guide bolts 25 .

The parallel rods 12 , 12 'are screwed at their ends, ie close to their articulation points 42 , each in threaded epass pieces 61 . After loosening the lock nut 38 , the rods can be lengthened or shortened by twisting.

In Fig. 5 you can still see the flange 34 of the middle pole, which is fastened with screws 35 to a reinforcement 36 of the pole carrier 7 and with its crankcase 37 immersed therein.

Claims (9)

1. High-voltage circuit breaker, in particular outdoor switch, with a deflecting gear arranged within a pole carrier, which converts the force, which is preferably introduced linearly from a drive, into a rotary movement for the pole shaft and supplies the individual poles located away from the drive via transmission elements, characterized in that a pull-train linkage with two parallel rods, which are connected to one another at their ends by means of articulated levers ( 13 , 13 ', 14 , 14 ', 14 '') which are rotatably mounted in the center, is used as the power transmission element, the articulated levers on the pole side ( 14 , 14 ', 14 '') each on the driven pole shaft ( 16 , 16 ', 16 '') firmly sit and the drive-related articulated lever ( 13 , 13 ') is a three corner lever, the free arm ( 19 , 19 ' ) has a recess ( 28 ) into which a straight guided connecting bolt Ver ( 29 ) with defined, flattened, plastic reinforced sliding flanks ( 31 ) is used. 2. Circuit breaker according to claim 1, characterized in that with the connecting bolt ( 29 ) cooperating articulated lever ( 13 , 13 ') and the cure lever ( 15 ) made of light metal - in particular an aluminum alloy - are formed and at least the sliding flanks ( 31 ) of the connecting bolt ( 29 ) made of polyoxymethylene. 3. Circuit breaker according to claim 1 or 2, characterized in that the connecting bolt ( 29 ) is formed entirely of steel-reinforced polyoxymethylene. 4. Circuit breaker according to one of claims 1 to 3, characterized in that the coupling of the free arm ( 19 , 19 ') of the articulated lever or the crank lever ( 15 ) with drive rods ( 9 , 10 , 11 ) of a drive via a slide ( 22 ) takes place, which is guided in the pole carrier ( 7 ) along the drive movement against rotation and the free arm ( 19 , 19 ') or the crank lever ( 15 ) with fork-shaped jaws ( 27 , 27 ') - which are penetrated by the connecting bolt zen - embraces. 5. Circuit breaker according to claim 4, characterized in that the slider ( 22 ) along two in the pole carrier ( 7 ) arranged guide pin ( 25 ) is moved and is provided on a cantilever part ( 23 ) with two bearing holes provided for this purpose ( 24 ). 6. Circuit breaker according to one of claims 1 to 5, characterized in that the rods ( 12 , 12 ') of the train-train linkage are permitted at least at one end with a threaded adapter ( 61 ) for varying the rod length. 7. Circuit breaker according to one of claims 1 to 6, characterized in that the articulated lever of the middle, near-drive pole ( 2 ) is formed as a crank lever ( 15 ) which sits directly on the pole shaft ( 16 ) without the interposition of a force transmission linkage. 8. Circuit breaker with a common drive for all three poles, the drive working on the pole shaft of the middle pole according to one of claims 1 to 7, characterized in that the pole shaft ( 16 ) the crankcase ( 37 ) of the middle pole ( 2nd ) protrudes and on one pole shaft end an articulated lever ( 14 '') for the pull-pull linkage of the outer pole ( 1 ) and on the other pole shaft end another articulated lever with two articulated arms for the articulation of the pull-pull linkage of the other, outer pole ( 3 ) sits on. 9. Circuit breaker according to one of claims 1 to 8, characterized in that the rods ( 12 , 12 ') of the train-train linkage, seen in the polar axis direction, are arranged one above the other.