EP1382049B1 - Latching mechanism for locking a spring energy store - Google Patents

Description

The invention is in the field of electrical switches, the with a spring drive for actuating contacts are equipped, and is in the structural design to use a latching mechanism for latching a spring accumulator.

In a known switch lock for a spring drive, in which the associated spring store by means of a Rotary drive and a stretchable toggle lever system tensioned is the extensible toggle system when cocked Spring accumulator by means of a support element, an auxiliary pawl and a main pawl and one of the main pawl associated Arrested stop. In this switch lock, in which the trained as a lever support element on the one Knee joint of the toggle lever system and on the other hand on the auxiliary pawl is hinged, the auxiliary pawl by stretching the Swivel lever system. Here are the auxiliary pawl and the main pawl on each other associated work surfaces, about the position of the main pawl when swinging the auxiliary pawl can be influenced (DE 44 16 088 C1). There is one first working surface of the auxiliary pawl of a semi-circular Formed section of the peripheral edge of the auxiliary pawl, on a trained as a role working surface of the main pawl abuts and the main pawl against the force of a their associated return spring in a first position holds. In this first position is a stop forming Half-wave from the main pawl under spring preload locked. A second trained as a recessed edge Working surface, which is also assigned to the role, gives the main pawl free at the end of the clamping process, so that on the one hand the main paw under the power of her assigned Return spring in overstroke behind the half-wave and on the other hand the released half-wave due to their spring preload into the movement path of the main pawl. Both Pivoting operations must be completed before the main pawl Decoupling of the lever system of the rotary drive under the Force of the spring accumulator in the opposite direction swings. As on the main latch usually a display organ is coupled for the state of the spring accumulator is at the same time it is expedient with regard to display reliability, that the main pawl just before the decoupling of the lever system from the rotary drive in overstroke behind the half-wave swings. These are especially with a high energy content of the spring accumulator rapid movements of the switch mechanism required. - At the mentioned switch lock must Therefore, the main pawl associated return spring a provide correspondingly high restoring force. This restoring force is then again in the design of the Switch mechanism with regard to their power reduction and in the embodiment of the release force for release the latching mechanism.

To safely latch the tensioned spring accumulator especially the tolerance range of the force under which the main pawl abuts against the stop, and the tolerance of the Force necessary to release the latch to the Tolerance of the return spring adapted. At a Breakage of the main pawl associated return spring is a Latching of the tensioned spring accumulator not possible. Starting from a switch lock with the features of the preamble of claim 1 (DE 44 16 088 C1) is the invention the task is based on the latching mechanism so Design that use to pivot the main pawl not acting on the main pawl return spring is required.

According to the invention, this object is achieved in that the auxiliary pawl and the main pawl each at least two Have work surfaces, wherein in a first pivot phase the auxiliary pawl each first of the two work surfaces together abut and wherein in a second pivot phase the second work surfaces gear-like nachgreifend together issue.

Due to such a configuration is ensured that the main pawl force-controlled at the end of the clamping process so far pivoted that they are in decoupling of the lever system from the rotary drive under the action of the Spring accumulator safely comes into contact with the stop. There in the design of the lock mechanism especially at a high energy content of the spring accumulator no high restoring forces to take into account can be both a small tolerance range the force under which the main latch on the stop is present, as well as a small tolerance range of the tripping force be provided.

In itself is a switching mechanism for latching a spring accumulator known in which a main pawl without using a on the main pawl attacking return spring is pivotally (DE 37 33 916 A1) .- In this known switching lock is the main pawl by a stretchable lever system - without interposition an auxiliary pawl - moves and in particular in overstroke behind one of the main pawl associated stop transferred.

An expedient development of the new switching mechanism provides that on the one hand, the first working surface of the auxiliary pawl from a transversely projecting to the pivot plane pin the Auxiliary pawl and the second working surface of the auxiliary pawl of a concave shaped portion of the peripheral edge of the Auxiliary pawl are formed and that on the other hand the first work surface the main pawl of a nose of the main pawl and the second work surface of a held on the main pawl Roll are formed.

To tension the spring accumulator part of the force of Rotary drive and when relaxing the spring accumulator a Part of the power of the spring accumulator on the smallest possible space evenly transferred to the auxiliary pawl is in further embodiment of the invention provided that when locked Position of the lever system a the support element forming roller acting on a hinge pin of the lever system is arranged at a second concave shaped portion the peripheral edge of the auxiliary pawl rests.

Furthermore, at the end of the clamping phase, a lower of the rotary drive on the lever system transmitting hub regardless of the pivoting movement of the coupled to the lever system Supporting element in a wide and thus jump-like pivoting movement the auxiliary pawl are implemented, if in further Embodiment of the invention for controlling the pivoting movement the auxiliary pawl coupled to the lever system driver and a two-armed pivoting control lever provided are, wherein the first lever arm of the control lever in an end portion the trajectory of the driver protrudes and the second lever arm associated with a driving surface of the auxiliary pawl is. - To control the auxiliary pawl may be in addition to the first driver and the control lever a second to the Be provided lever system coupled driver, the Stretching the lever system over a portion of its trajectory abuts a second driving surface of the auxiliary pawl.

Compliance with the smallest possible design of the switching mechanism This is possible because the first driver is formed by the hinge pin of the lever system, wherein the hinge pin a nose-like approach of the control lever than whose first lever arm is associated and wherein on the second Lever arm of the control lever, a pin is formed, the in a trained near the pivot point of the auxiliary pawl slot engages, the inner edge of the first driving surface forms. - The second driver can be designed as a bolt be that of the knee joint of a coupled to the lever system Toggle joint forms, wherein the second driving surface from another section of the circumferential edge of the Auxiliary pawl is formed.

Figur 1 das Schaltschloss bei vollständig entspanntem Federspeicher,

Figuren 2 bis 6 das Schaltschloss in fünf verschiedenen Phasen des Spannprozesses und

Figur 7 das Schaltschloss bei vollständig gespanntem und verklinktem Federspeicher.

An embodiment of the new switching mechanism is shown in Figures 1 to 7. Showing:

FIG. 1 shows the switching mechanism with completely relaxed spring accumulator;

Figures 2 to 6, the switching mechanism in five different phases of the clamping process and

Figure 7 shows the switching mechanism with fully tensioned and latched spring accumulator.

Figures 1 to 7 show a in a drive device integrated for a low-voltage circuit breaker Switch lock. The drive device used for actuation a switching contact arrangement, not shown in the figures serves, points to provide the actuation energy designed as a helical compression spring spring accumulator 1 on. To tension the spring accumulator 1 is in this Drive device by means of a rotary drive designed stretchable lever system, for locking the Switch lock is used. - The lever system is one of them a cam follower 2 carrying roller lever 3, one on the spring accumulator 1 hinged clamping lever 4 and a roller lever 3 with the tensioning lever 4 connecting coupling member 5 is formed. The roller lever 3 is on a first bearing pin 6 and the Tensioning lever 4 rotatably mounted on a second bearing pin 7. Here, the roller lever 3 and the coupling member 5 by means of a first hinge pin 8 and the clamping lever 4 and the coupling member 5 is connected by means of a second hinge pin 9. The tensioning lever 4 is designed as a two-armed lever, wherein one arm on the coupling member 5 and the other arm is hinged to the spring accumulator 1. From the rotary drive, the For example, electric motor and / or a hand lever can be operated is in the figures 1 to 7 respectively only a clockwise rotatable clamping shaft 10 and a fixed shown on the clamping shaft 10 arranged cam 11.

The cam 11 and the lever system 3, 4 and 5 are for Transmission of the driving force of the rotary drive coupled, as soon as the scanning roller 2 carried by the roller lever 3 at the circumferential edge of the cam 11 abuts.

The switch lock has on the one hand to lock the lever system a trained as a roller 12 support element, one order a third bearing pin 13 pivotable auxiliary pawl 14, a pivotable about the first bearing pin 6 main pawl 16 as well one of the main pawl 16 associated stop 17 and on the other for controlling the feeding movement of the auxiliary pawl 14 one formed by the first hinge pin 8 of the lever system first driver - the via a two-armed control lever 19 acts on a first driving surface 20 of the auxiliary pawl 14 - And the knee joint one to the lever system coupled toggle connection 21 forming the second driver 22 - the directly on a second driving surface 23 of the Auxiliary pawl 14 attacks - on. To the pivoting movement of Main pawl 16 when pivoting the auxiliary pawl 14 to influence are on the one hand on the auxiliary pawl 14 one of Pin 24 formed first work surface and one of a formed first concave shaped portion 25 of the auxiliary pawl second work surface and the other on the main pawl 16 a pin 24 associated, from a nose 26 of the main pawl formed first work surface and one concave the first shaped portion associated with 25, one at the The main pawl held a roll of 27 formed second worktop intended. In this case, when pivoting the auxiliary pawl 14th clockwise (i.e., under the force of the rotary actuator 10 and 11) the main pawl 16 counterclockwise rotated as soon as the pin 24 and the nose 26th and later toothed like the first concave shaped Section 25 of the peripheral edge of the auxiliary pawl and the Roll 27 abut each other. The lever system 3, 4 and 5 is locked as soon as the support element forming roller 12, the arranged on the first hinge pin 8 of the lever system is, at a second concave shaped portion 28 of the circumferential Edge of the auxiliary pawl, the first concave shaped Section 25 of the auxiliary pawl on the roller 27 of the main pawl and the main pawl 16 on the trained as a half-wave stop 17 abut. At the main latch is an indicator 29 coupled, which signals the state of the spring accumulator. For this purpose, a trained at the main paw attacks Pin 30 in a curved slot 31 of the display member 29th such that the indicator member upon pivoting of the auxiliary pawl 16 mitschwenkt.

FIG. 1 shows the switching mechanism before the beginning of the clamping process. At this time, the cam 11 is located in its initial position and carried by the roller lever 3 cam follower 2 is located at the circumferential edge of the cam 11 on. The lever system 3, 4 and 5 is located in a first Position in which the spring accumulator 1 is completely relaxed is. In this case, the main pawl 16 is supported on a stop pin 32, the auxiliary pawl 14 by means of a roller 27 of the main pawl 16 adjacent straight section 33 of its peripheral edge on the main pawl 16 and the coupled to the lever system 3, 4 and 5, the Support member forming roller 12 at a third concave shaped Section 34 of the peripheral edge of the auxiliary pawl from. A portion 35 of the peripheral edge of the main pawl 16 is so below the half-wave 17 that the half-wave 17 - the trigger mechanisms not shown further against the force of a likewise not shown Return spring is rotatable - under spring preload is held. The coupled to the main pawl 16, with a Display surface 36 provided indicator 29, located while in a first position, in which a not shown Viewing window, a first portion 39 of the display area 36 of the display member is opposite. This first Subregion 37 signals that the spring accumulator 1 is not completely tense. A suitable symbol is For example, a relaxed pressure spring. To that in FIG. 1, neither the first driver is located 18 on the control lever 19 nor the second driver 22nd on the second driving surface 23 of the auxiliary pawl.

Referring to Figures 2 to 6, the switching mechanism during various Phases of the tensioning process will show that of the Roller lever 3 and the coupling member 5 formed lever connection the lever system plugged in that with increasing distance the circumferential edge of the cam 11 from the pivot point 39 of the cam of the cam follower bearing bolt 40 and thus also the roller lever 3 counterclockwise swing. The movement of the roller lever 3 is by means of the coupling member 5 is transmitted to the clamping lever 4, so that hinged to the spring accumulator 1 arm of the clamping lever to the second bearing pin 7 is pivoted clockwise and thus the spring accumulator 1 is tensioned. To that shown in Figure 1 Time comes the second driver 22 in Appendix with the second driving surface 23 of the auxiliary pawl and pivots the auxiliary pawl 14 to the third bearing pin 13 in Clockwise so far, until according to Figure 3 at the auxiliary pawl 14 trained, perpendicular to the pivoting plane of the auxiliary pawl from the auxiliary pawl projecting pin 24 against the at the Main pawl 16 trained nose 26 runs. At this time the first driver 20 runs against one in an end portion projecting its trajectory, as a nose-like approach the control lever formed first arm 41 and pivots the control lever around his from the first bearing pin 6 formed counterclockwise pivot point. These Pivoting movement is via the second arm 42 of the control lever, which is longer than the first arm is formed on the Transfer auxiliary pawl. This is at the end of the longer formed second arm 42 of the control lever 19 a transversely to the pivoting direction of the control lever of the control lever more projecting Control pin 43 is arranged. This control pin 43 protrudes into a near the third bearing pin 13 (fulcrum of Auxiliary pawl) formed second curved slot 44, the inner edge of the second driving surface of the auxiliary pawl forms. Since the distances of the formed on the auxiliary pawl 14 Work surfaces 24 and 25 to the pivot point of the auxiliary pawl 13 are larger than the distance of the control pin 43 of the control lever to the pivot point of the auxiliary pawl 13 and there continue the distances of the working surfaces of the main pawl 26 and 27 for first bearing pin 6 (pivot point of the main pawl) lower are as the distance of the stop 17 associated portion 45 of the peripheral edge of the auxiliary pawl to the fulcrum the main pawl, according to the figures 3 to 6 at the end the tensioning process a small arc length of the pivoting movement of the first driver 8 in a large arc length of Pivoting movement of the stop associated with the section 45th the peripheral edge of the main pawl translated. For this lie in a first pivoting phase according to FIGS. 3 and 4 respectively the first working surfaces 24 and 26 of the auxiliary pawl and the main latch on each other. They are at the transition in a second pivot phase of the auxiliary pawl - in accordance with Figures 5 and 6, the second work surfaces 25 and 27th tooth-like abutting against each other - from each other decoupled. In this second pivot phase of the auxiliary pawl reaches the stop associated with the section 45 of the rotating Edge of the main pawl in overstroke behind the stop 17 shortly before the cam follower 2 of the roller lever 3 of the circumferential edge of the cam 11 is decoupled.

According to the figure 7, the switch lock at fully tensioned and latched spring accumulator 1 shows supports the decoupled from the rotary actuator lever system under the force of the spring accumulator 1 via the coupled to the lever system Support member 12 on the third concave-shaped portion 34th the peripheral edge of the auxiliary pawl, the auxiliary pawl 14 on the second work surfaces 25 and 27 on the main pawl 16 and the main pawl on the stop 17 from. At this time is located on the main pawl coupled indicator 29 in a second position, at the viewing window a second portion 38 of the display surface 36 is opposite. This second portion 38 signals that the spring accumulator 1 is fully tensioned. A suitable one For example, symbol is a cocked one Spring.

To the game between the mutually assigned work surfaces the auxiliary pawl and the main pawl as low as possible can hold, for example, at the main paw attacking Be provided spring.

LIST OF REFERENCE NUMBERS

1

spring

2

cam follower

3

roller lever

4

clamping lever

5

coupling member

6

First bearing pin (bearing pin of the roller lever of the Main pawl and two-armed control lever)

7

Second bearing pin (bearing pin or pivot of the Clamping lever)

8th

First hinge pin; forms the first driver

9

Second hinge pin (hinge pin between tension lever and coupling member)

10

clamping shaft

11

cam

12

Roller that forms the support element

13

Third bearing pin (bearing pin or pivot point of Auxiliary jack)

14

auxiliary jack

16

primary lock

17

attack

19

Two-armed control lever

20

First driving surface of the auxiliary pawl

21

Toggle link

22

Second driver

23

Second driving surface

24

Pin (first working surface of the auxiliary pawl)

25

First concave shaped portion of the circumferential edge the auxiliary pawl (second working surface of the auxiliary pawl)

26

Nose of the main pawl (first working surface of the main pawl)

27

Roller held on the main pawl (second work surface the role)

28

Second concave shaped portion of the peripheral edge the auxiliary latch

29

Signaling device

30

First bent slot of the indicator

32

stop pin

33

Straight section of the peripheral edge of the auxiliary jack

34

Third concave shaped portion of the circumferential edge the auxiliary latch

35

Trained at the peripheral edge of the main pawl section

36

Display surface of the indicator

37

First subarea of the display area

38

Second subarea of the display area

39

Fulcrum of the cam

40

Bolt that carries the cam follower

41

First arm of the two-armed control lever

42

Second arm of the control lever

43

control pin

44

Second curved slot formed in the auxiliary latch is

45

The stop associated with the section of the circumferential Edge of the main pawl

Claims (7)

1. Latching mechanism for locking a spring energy store (1) of an electrical switch tensioned by means of a rotary drive (10, 11) and an extensible lever system (3, 4, 5),

   in which the extensible lever system (3, 4, 5) is locked with the spring energy store (1) under tension by means of a support element (12), an auxiliary lock (14) and a primary lock (16) in addition to a stop (17) allocated to the primary lock,

   wherein the auxiliary lock (14) can be pivoted by extension of the lever system and

   wherein the auxiliary lock and the primary lock have working surfaces allocated to one another, by means of which the position of the primary lock during the pivoting of the auxiliary lock can be influenced,

   characterized

   in that the auxiliary lock (14) and the primary lock (16) respectively have at least two working surfaces (24, 25 or 26, 27),

   wherein, in a first pivoting phase of the auxiliary lock, respective first surfaces of the two sets of working surfaces (24, 26) lie adjacent to one another and

   wherein, in a second pivoting phase of the auxiliary lock, the second working surfaces (25, 27) lie adjacent to one another, intermeshing in the manner of a toothed gear.
2. Latching mechanism according to Claim 1, characterized in that the first working surface (24) of the auxiliary lock (14) is formed by a pin of the auxiliary lock protruding transversely with respect to the pivoting plane and the second working surface (25) of the auxiliary lock is formed by a concavely shaped portion of the peripheral edge of the auxiliary lock, and
   in that the first working surface (26) of the primary lock (16) is formed by a lug of the primary lock and the second working surface (27) is formed by a roller held on the primary lock.
3. Latching mechanism according to Claim 1 or 2, characterized in that, in the case of the locked position of the lever system (3, 4, 5), a roller which forms the supporting element (12) and is arranged on a joint bolt (8) of the lever system lies adjacent to a second concavely shaped portion of the peripheral edge of the auxiliary lock (28).
4. Latching mechanism according to one of Claims 1 to 3, characterized in that a driver (8) coupled to the lever system and a two-armed pivotable control lever (19) are provided for controlling the pivoting movement of the auxiliary lock (14),
   the first lever arm (41) of the control lever (19) protruding into an end portion of the path of movement of the driver (8) and the second lever arm (42) being allocated to a driving surface (20) of the auxiliary lock (14) .
5. Latching mechanism according to one of Claims 1 to 4, characterized in that a second driver (22), which is coupled to the lever system and during the extension of the lever system lies adjacent over a portion of its path of movement to a second driving surface (23) of the auxiliary lock, is provided for controlling the pivoting movement of the auxiliary lock (14).
6. Latching mechanism according to one of Claims 4 or 5, characterized in that the first driver is formed by the joint bolt (8) of the lever system,
   the joint bolt (8) being allocated a lug-like projection of the control lever as its first lever arm (41), and
   there being formed on the second lever arm (42) of the control lever a pin (43) which engages in a slot (44) which is formed close to the pivot point of the auxiliary lock and the inner edge of which forms the first driving surface (20).
7. Latching mechanism according to one of Claims 5 or 6, characterized in that the second driver (22) is designed as a bolt which forms the toggle joint of a toggle lever connection (21) coupled to the lever system and
   in that the second driving surface (23) is formed by a further portion of the peripheral edge of the auxiliary lock.

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