DE3906786A1 - Drive mechanism - Google Patents

Abstract

The invention relates to a drive mechanism for operating a vacuum switch having a push-rod drive, in the case of which the coupling rod (6) is moved by means of its rotating joints (11, 12) in a longitudinal guide (1) and a transverse guide (2). In this case, the transverse guide (2) has a first section (3) which runs in the form of a circular arc and in which the second rotating joint (12) is at any point when the vacuum switch (20) is in the switched-on position, without the spring (13) which produces the contact force in this case exerting reaction forces via the drive rod (8) on the energy store. The transverse guide (2) is terminated by a third section (5) which likewise has a course in the form of a circular arc. The design according to the invention of the transverse guide (2) of the push-rod drive allows the production of a uniform switch stroke (h) independently of the manufacturing tolerances of the switch drive and of its parts, and independently of scatters in the movements (I) of the drive linkage (8) of the individual poles of a multipole switch. <IMAGE>

Description

The invention relates to a drive mechanism with the features of Preamble of claim 1.

Such a switch is known from DE-PS 31 47 016. At this switch is the coupling rod with its pivot points in one Axial direction arranged longitudinal guide and one at right angles to it extending transverse guide. The two pivot points are located in the on position in the axis of the switch and thus in Dead center. In the frictional contact of the contact pin of the movable Switching contact is an elastic link for generating the contact force intended. The known switch is in the dead center position unstable balance; d. H. that acting on the switch contact elastic link produced with increasing deviation from the Equilibrium is a rapidly growing force component in the direction the lateral guide. With the usual manufacturing tolerances of Vacuum switches can only make such deviations through a complex Fine adjustment of the drive rod or other components with Security can be avoided. If the reversing gear of the known If the switch stops before the dead center position, the increases Force component including the release force of the lock for the Switch-off memory; it remains after passing through the dead center position stand, the switch-off memory must also have the energy for Overcoming the path to dead center, which is at least an increase in the switch-off time, if not one Failure to switch off can result. By designing the transverse guide become the usual manufacturing tolerances in the known switch also too far from each other in contact distances  the switch off position.

The object of the invention is to improve the kinematic Design of the drive mechanism of a vacuum switch according to Preamble of claim 1 seen, in which the usual Manufacturing tolerances of the entire switch have no influence on the Compliance with the locked position in the switch-on position and on the Can exercise contact distance in the off position.

The task is characterized by the distinctive features of the first Claim resolved.

Instead of the singular dead center position of the two swivel joints in the Switch-on position of the vacuum switch provided blocking area at the end the transverse guide is designed so that the second hinge of the No coupling rod at any point within this restricted area Reactive force on the drive rod and thus on the energy storage of the vacuum switch. This restricted area is several Millimeters long to affect the tolerances of all the switch stroke Compensate components so that the second swivel in the Switch-on position at any location within this restricted area stands. With the second restricted area at the other end of the cross guide similarly achieved regardless of all dimensional tolerances that the Contact distance of the open switch contacts in the off position a certain value that only depends on the required insulation reached.

Advantageous developments of the invention are in the subclaims specified.

For a better understanding of the invention, reference is made to the drawings, which represent the following:  

Fig. 1 Structure of a vacuum switch with the drive mechanism according to the invention.

Fig. 2 Schematic representation of the kinematics of the drive mechanism; Lateral guide on one side of the axis of the vacuum switch.

Fig. 3 as Fig. 2; Lateral guide on both sides of the axis of the vacuum switch.

Fig. 4 Schematic representation of the longitudinal and transverse guidance with different switching paths.

Fig. 5 Schematic representation of the drive mechanism when installing the elastic member in the coupling rod.

In Fig. 1, a vacuum switch 20 is shown with its connections; the upper connection 21 is connected via a movable contact and the contact pin 7 to the movable switching contact, not shown, while the lower connection 22 is connected to the fixed switching contact. The drive mechanism consists of the longitudinal guide 1 , the transverse guide 2 , the coupling rod 6 and the drive rod 8 , which establishes the connection to an energy store, not shown. The coupling rod 6 is slidably supported by a first swivel joint 11 in the longitudinal guide 1 and by a second swivel joint 12 in the transverse guide 2 . Between the contact pin 7 and the first swivel joint 11 there is an elastic member in the form of a spring 13 for generating the contact force required between the switch contacts, which is limited in a known manner by the bolt 14 connected to the swivel joint 11 and the sleeve 15 .

The two slot guides 1 and 2 are advantageously incorporated into a common plate 16 , two identical plates 16 surround the coupling rod 6 . Cylindrical bolts connect the coupling rod 6 to the guides 1 and 2 , thus forming the first and second swivel joints 11 , 12 . The drive rod 8 is also connected to the second swivel joint 12 ; it can also be arranged between the two plates 16 . In Fig. 1 of the vacuum switch is shown in the switched position 20..

The kinematic principle on which the invention is based can be seen in FIG. 2. There, the axis of the vacuum switch is designated by AA , in which the guide 1 of the first articulation point 11 is arranged. The transverse guide 2 , in which the second hinge point 12 is guided, lies at any angle to the axis AA . The two hinge points 11 and 12 are connected by the coupling rod 6 in any position. The first pivot point is in its lower position 11 a in the switched-on position of the vacuum switch, while it is shown in the upper position 11 b in the switched-off position of the vacuum switch. The transverse guide 2 has a first section 3 , the center line of which lies on a circular arc around the articulation point in the position 11 a , the radius r _{e being} equal to the effective length of the coupling rod 6 . The first section 3 is followed by the second section 4 of the transverse guide, which generally runs in a straight line. The transverse guide 2 is closed with the third section 5 , the center line of which in turn lies on a circular arc, the center of which is arranged in the upper position 11 b of the first articulation point and the radius r _{e of} which corresponds to the effective length of the coupling rod 6 . The bolt 14 is also articulated to the first articulation point 11 and acts on the contact bolt 7 of the movable switching contact via the spring 13 . At the second hinge point 12 , a connection to the energy store of the vacuum switch is established by the drive rod 8 .

During a switch-on and switch-off, the force K is exerted from the energy store (not shown) via the drive rod 8 onto the second articulation point 12, the force moves via a path l which is transmitted from the thrust gear as a total stroke h to the vacuum switch.

The manufacturing tolerances of the energy storage device and the remaining switch components can result in the known multi-pole switches that the common energy storage device transmits the same path l to each pole and does not cover the end positions. On the other hand, the tolerances can also result in different paths l ₁ , l ₂ , l ₃ being transmitted to the individual poles of the switch. The transverse guide is always designed according to the invention in such a way that in both end positions for all poles the second swivel joints 12 are in the respective first or third section 3 , 5 of the transverse guide 2 . Due to the specified dimensioning of the transverse guide with the described end sections 3 and 5 , it succeeds in spite of the specified tolerance problems for all switches of an embodiment, for. B. for a certain nominal voltage, ensure the same total stroke h of the switch contacts.

In addition, the circular arc-shaped guidance of the second articulation point 12 in the first section 3 of the transverse guide 2 means that the contact force of the vacuum switch in the switched-on position, despite all dimensional tolerances, cannot cause any repercussions on the energy store or its triggering mechanisms.

In order to further improve the accuracy of the drive movement on the switching contacts, it is advantageous according to FIG. 1 to mount the guides 1 and 2 in a common plate 16 . These plates can be produced economically with a suitable tool with high uniformity. While in Figs. 1 and 2, the drive mechanism according to the invention is accommodated on one side of the switch axis AA, may be according to Fig. 3 is the same on both sides of this axis order. In this case, the throat of the plate 16 carrying the guides 1 , 2 against the earth potential can be minimized. The same reference numerals apply as in FIGS. 1 and 2. An arrangement according to FIG. 3 is preferably suitable for small switches with small distances to ground potential, such as vacuum contactors for a nominal voltage of 7.2 KV or less.

The idea of the invention can also be advantageously used for the rational design of the drive mechanism of vacuum switches for different voltage ranges, ie for vacuum interrupters with different switching strokes. In Fig. 4 it can be seen that for a given longitudinal guide 1 for three different switch sizes, a single specific position of the first swivel joint 11 is assumed in the switch-on position. With a given coupling rod 6, this results in a specific position of the transverse guide 2 with its first section 3 . For the switches with a relatively small nominal voltage, e.g. B. 12 kV, the switch stroke h _c is sufficient, from which the position of the second swivel joint 12 results at a specific constant drive path l of the drive rod. The coupling rod 6 therefore has the position indicated by 6 c in the off position of this switch. This determination results in the position of the third section 5 c of the transverse guide 2 and an average angle of inclination α _c with respect to the longitudinal axis AA , taking into account that described above.

For a switch of a medium voltage range, e.g. B. 24 kV, it is assumed that the switch stroke has the size of h _b . With a constant drive path l , there is again a specific position for the second swivel joint 12 in the switch-off position. It lies on the same ordinate through the point that the second swivel joint 12 has occupied for the first switch. The average angle of inclination of the transverse guide α _b is smaller than α _c .

For a switch of the larger nominal voltages, e.g. B. 36 kV, a larger switch stroke h _{a is provided} in the longitudinal guide 1 . The transverse guidance is determined in a similar way to that of the other two switches, the position of the coupling rod in the switched-off position of the vacuum switch is given as 6 a . The average inclination of the transverse guide is even smaller here and is α _a . On the basis of the features given in FIG. 2 for the transverse guide 2 , there is a constant position for its first section 3 for all three switch sizes.

If the elastic member according to FIG. 1 is arranged as a spring 13 between the contact pin 7 and the first swivel joint 11 , a coupling rod 6 with a constant length results during the entire movement sequence. According to FIG. 2 where the radii R _e and R _a are equal and correspond to the effective length of the coupling rod 6 between the two pivot joints 11, 12.

However, the invention can also be applied to drive mechanisms in which, according to FIG. 5, the elastic member, as known, for example, from US Pat. No. 3,597,556, is installed as a compression spring 9 in the coupling rod. The coupling rod consists of the rod 17 , which is connected to the first swivel joint 11 and whose piston-shaped extension forms the spring abutment 18 , and of the sleeve 19 , which is articulated to the second swivel joint 12 and the end plate 10 as a stroke limitation for the compression spring 9 acts and encompasses the rod 17 .

In the switched-on position of the vacuum switch, the two swivel joints are in positions 11 a and 12 a and the compression spring 9 is compressed and acts on the switching contacts. The radius r _e for the first section 3 of the transverse guide 2 corresponds to the distance between the rotary joints 11 a - 12 a . In the off position of the switch, the two pivot joints have taken the positions b 11 and 12 b and the compression spring 9 is supported between the sleeve 19 and spring abutment 18 wherein letzters abuts the end plate 10 degrees. The radius r _a for the third section 5 of the transverse guide corresponds to the distance 11 b - 12 b , it is larger than r _e .

Reference symbol list

1 longitudinal guide
2 lateral guidance
3 first section of the transverse guide
4 second section of the transverse guide
5 third section of the transverse guide
6 coupling rod
7 contact bolts
8 drive rod
9 compression spring
10 end plate
11, 11 a , 11 b first swivel joint
12, 12 a , 12 b second swivel joint
13 spring
14 bolts
15 sleeve
16 plate
17 rod
18 spring abutments
19 sleeve
20 vacuum switches
21 upper connection
22 lower connection

Claims (11)

1. Drive mechanism for actuating a vacuum switch

• - With an elastic member included in the power flow of the drive mechanism for generating the contact force in the switched-on position of the vacuum switch, and
• - With a sliding joint gearbox, which connects a contact pin of a switch contact movable in the axial direction of the vacuum switch with a switch drive, which consists of at least one coupling rod, which is connected to the contact pin via a longitudinally guided first swivel joint in the axial direction of the vacuum switch and via a second, transversely guided swivel joint a drive rod is connected and the swivel joints are displaceable in the respective guides so that they are in a dead center position in the switched-on position of the vacuum switch, characterized in that the transverse guide ( 2 ) has an arcuate section ( 3 , 5 ) at each of its two ends. has, in which the second swivel joint ( 12 ) is in the last part of each switching movement transmitted by the drive rod ( 8 ) in a blocking area and thereby no longer transmits movement to the movable switching contact.

2. Drive mechanism according to claim 1, characterized by the following features:

• a) the transverse guide ( 2 ) consists of
• - a first section ( 3 ) with an at least approximately circular arc-shaped course, the center of which is formed by the first articulation point ( 11 a ) in the switch-on position and the radius ( r _e ) of the associated length of the coupling rod ( 6 ),
• - A second, adjoining the first section, preferably with a straight course, and
• - A third, at the second adjoining section ( 5 ) with an at least approximately circular arc-shaped course, the center of which is formed by the first articulation point ( 11 b ) in the off position of the switch and the radius ( r _a ) of the associated length of the coupling rod ( 6 ) is and
• b) the second pivot point ( 12 ) passes through all three sections ( 3 , 4 , 5 ) of the transverse guide ( 2 ) in one direction or the other during each switching movement.

3. Drive mechanism according to claim 1 or 2, characterized in that one of the drive rods (8th) predetermined, constant Drive path (l) of the second swivel joint (12th) by varying the inclination (α _a,α _b,α _c) the lateral guide (2nd) different sized strokes (H _a, H_b, H_c) of first swivel (11) and thus also the movable switch contact are achievable. 4. Drive mechanism according to one of claims 1, 2 or 3, characterized in that the elastic member is designed as a stroke-limited spring ( 13 ). 5. Drive mechanism according to claim 4, characterized in that the stroke-limited spring ( 13 ) is arranged coaxially with the contact bolt ( 7 ) of the movable switching contact. 6. Drive mechanism according to one of claims 1 to 4, characterized in that the stroke-limited spring ( 13 ) in the coupling rod ( 6 ) is included, and that the radius ( r _e ) of the first section ( 3 ) of the transverse guide ( 2 ) the working stroke of the spring between the switch-off position and the switch-on position of the vacuum switch is smaller than the radius ( r _a ) of the third section ( 5 ). 7. Drive mechanism according to any one of the preceding claims, characterized in that all three sections ( 3 , 4 , 5 ) of the transverse guide ( 2 ) are arranged on one side of the longitudinal axis of the vacuum switch. 8. Drive mechanism according to any one of claims 1 to 5, characterized in that the sections ( 3 , 4 , 5 ) of the transverse guide ( 2 ) are arranged on different sides of the longitudinal axis of the vacuum switch. 9. Drive mechanism according to each of the preceding claims, characterized in that the longitudinal guide ( 1 ) and the transverse guide ( 2 ) are designed as elongated holes, in which the rotary joints ( 11 , 12 ) are guided displaceably by means of bolts. 10. Drive mechanism according to claim 9, characterized in that the longitudinal ( 1 ) - and the transverse guide ( 2 ) on both sides of the rotary joints ( 11 , 12 ) are arranged. 11. Drive mechanism according to claim 9 or 10, characterized in that the two guides ( 1 , 2 ) are housed in common, preferably plate-shaped bearing parts ( 16 ).