EP3636863B1 - Securing device for a joint - Google Patents

Description

The invention relates to a joint safety device for securing two levers which can be rotated relative to one another about a joint axis and are connected via a joint pin. Furthermore, the invention relates to a shutter drive and a shutter.

Joint locks are used in very different areas of technology and can be used when two levers are to be connected to one another so that they can pivot. As a rule, such levers are connected to one another via a pivot pin, which enables a relative rotational movement of the levers in the sense of a hinge joint about the pivot axis extending through the pivot pin.

In particular, if axial forces also act on the levers or if the levers deform due to the forces acting on them, there is a risk that at least one lever will slip off the hinge axis or the hinge pin. If a lever is designed as a lever rod, for example, and a compressive force then acts on this rod in the longitudinal direction of the rod, the rod is designed in the sense of a buckling rod perpendicular to the longitudinal rod axis. Due to the deformation, axial forces can therefore also act on the lever even if the lever is subjected to a pure compressive load, which in the worst case can lead to the lever slipping off the pivot pin.

Various possibilities are known for securing the two levers against a corresponding axial movement on the hinge pin. On the one hand there are some possibilities from the documents DE 10 2010 015058 A1 , U.S. 2015/003897 A1 and U.S. 2013/333379 A1 famous. On the other hand, for example, the pivot bolt can be provided with a thread and then one or more nuts can be screwed onto the thread to secure the lever or levers. Although such a nut lock is very easy to assemble, it has the disadvantage that relative movement between the levers and the nut can result in the nut being able to be twisted off the pivot bolt after a long period of use. In addition, this type of securing requires a comparatively large overhang of the hinge pin in relation to the levers for receiving the nut.

Due to these disadvantages, securing rings such as snap rings are also often used in practice for securing. These joint locks are usually mounted in a groove on the joint pin and then block an axial movement of the lever or levers in the direction of the joint axis. However, the assembly of such retaining rings is comparatively complex, since additional tools are usually required to widen the retaining rings. Furthermore, the pivot bolts must be provided with grooves into which the locking rings can engage.

Proceeding from this, the object of the invention is to specify a joint safety device that can be installed in a simple manner and at the same time ensures reliable safety.

This problem is solved by the characterizing features of claim 1 with a joint securing device of the type mentioned at the outset.

The joint securing device can be attached to one of the two levers in a simple manner by means of the connecting section. It is advantageous if the connecting section can be connected to the second lever. In contrast to the securing rings or nuts mentioned at the outset, it is not necessary to arrange the joint securing device on the joint bolt, which is why it is also not necessary for the joint bolt to be provided with a thread or with a groove.

The two levers are reliably secured against axial movement on the hinge pin by the bracket section, so that they cannot move in the axial direction on the hinge pin, in particular not relative to one another.

It has turned out to be advantageous if the connecting section enables a detachable connection to one of the two levers. This enables easy disassembly and variable use of the joint lock.

According to the invention, the connecting section is designed as a latching section. A snap-in connection enables a very simple connection of the joint lock with one of the levers, without the use of a tool being required. The joint lock can therefore be assembled and disassembled very easily and quickly.

By applying a specific force to the latching section, it can be elastically deformed and widened, so that the latching section can be pushed over one of the levers or onto one of the levers. If the force is removed again, the latching section resumes its original shape due to the elasticity of the material and leads to a latching connection with one of the levers. The joint securing device and the lever can then be connected to one another with a friction fit or with a form fit. The force required to deform the latching section can be dimensioned in such a way that the joint securing device can be fastened to one of the levers by hand and without the additional use of tools. The locking section can be designed as a clip section for clip connection with one of the two levers. Such an embodiment simplifies assembly and disassembly even further, since the joint securing means can simply be clipped onto one of the two levers for connection to the latter.

It has also turned out to be advantageous if the joint securing device is made from a plastic. In addition to the required elasticity, plastic also offers the possibility of simple series production, for example in an injection molding process. Furthermore, plastic is also robust enough to ensure that the two levers are reliably secured. It is advantageous if the joint securing device is designed as an injection molded part.

The connecting section or the latching section can be connected in one piece to the other elements of the joint securing device. This section can thus also be made of plastic. Especially with one Clip portion can be made possible by the intrinsic material stress of the plastic, a simple clipping of the joint security on one of the two levers.

It has also proven to be advantageous if the connecting section has a rod receptacle for receiving one of the two levers. If one of the two levers is designed as a lever rod and the connecting section is designed as a rod receptacle, the joint securing device can be installed very easily. To connect, it is sufficient to press the connecting section onto the lever. Due to the geometry, the connecting section can expand independently and can thus be connected to the lever very easily.

It is advantageous if the connecting section has a non-closed profile, in particular a non-closed ring profile. Such a non-closed profile allows easy connection of the connecting portion to the lever. The connecting section can be designed, for example, in the manner of a slotted hollow cylinder or in the manner of a hollow cylinder segment. The connecting section can have a segment angle of more than 180°. This requires the connecting portion to be deformed to connect with the lever, but ensures a reliable connection. The inner diameter of the connecting section is preferably dimensioned such that a radial force acts on the lever in the connected state, so that a frictional connection is achieved between the joint securing device and the lever. For this purpose, the inner diameter of the connecting section can be adapted to the outer diameter of the lever. Furthermore, it is possible for the inner diameter of the connecting section to be smaller than the diameter of the lever. This leads to an increase in the friction acting on the lever.

According to the invention, the bracket section has two bracket legs. A bracket leg can be assigned to the first lever and a bracket leg to the second lever. Each of the bracket legs can interact with one of the two levers and thus secure it against axial movement.

Furthermore, according to the invention, the two hanger arms lie opposite one another and a receiving space for receiving the two levers is arranged between the two hanger arms. The receiving space can be limited by the two bracket legs, which ensures that the lever is reliably secured in the receiving space. The two bracket legs can extend essentially parallel to one another.

Furthermore, it has proven to be advantageous if the two bracket legs are each connected to the connecting section at one end and have a free end at the opposite end. The joint securing device can thus have a U-shaped cross section or a fork-shaped cross section with two prongs. The two bracket legs can each represent a tine of the fork. It is advantageous if the bracket legs are connected in one piece to the connecting section.

It has also proven to be advantageous if the first bracket leg has a bolt receptacle, in particular a semicircular design, for receiving the hinge bolt at a free end. The joint securing device can interact with the joint bolt via the bolt receptacle. The position of the joint safety device in relation to the joint bolt can be fixed via the bolt receptacle. In an alternative embodiment, it is also possible for the bolt receptacle to be designed as a circular recess, in particular as a bore, through which the hinge pin can be pushed through. The bolt receiver can have a central axis that can coincide with the hinge axis.

It has also proven to be advantageous if the first bracket leg has a sliding surface for sliding on one of the levers. Since the joint safety device can be connected to the second lever via the latching connection, the joint safety device can also move relative to the first lever when the two levers rotate relative to one another. With a corresponding movement, the sliding surface can slide off the first lever. The sliding surface can be arranged on the side of the first bracket leg facing the second bracket leg. The sliding surface can thus also delimit the receiving space.

With regard to the construction of the first bracket leg, it has proven to be advantageous if this is designed in the form of a plate. A plate-shaped design means that forces can be introduced into the bracket leg over as large an area as possible, which enables the two levers to be reliably secured on the joint axis, in particular against axial movement.

It has also proven to be advantageous if the second bracket leg has a bolt receptacle at the free end for receiving the hinge bolt. The bolt receptacle can have a circular recess, in particular a bore, through which the hinge bolt can be inserted. However, it is particularly advantageous if the bolt receptacle of the second bar arm is also designed in a semicircular manner, at least in sections, and the hinge bolt can be accommodated in this semicircular receptacle. Furthermore, the bolt receptacle can also additionally have a borehole arranged behind the semicircular receptacle in the direction of the joint axis, in particular in the form of a round hole, which offers manufacturing advantages. The bolt receiver can have a central axis that can coincide with the hinge axis. The bolt receptacle of the second bracket limb can be aligned with the bolt receptacle of the first bracket limb, so that the hinge bolt can be reliably accommodated. The hinge bolt can extend through the bolt receptacle of the two bracket legs. The second bracket leg can have a recess at the free end, which enables the joint securing device to be slipped onto the joint pin.

Furthermore, it has proven to be advantageous if the second bracket leg has a lever receptacle for receiving one of the two levers, in particular the second lever. The lever receptacle can be adapted to the design of the lever to be accommodated. If the lever to be accommodated is designed as a rod, the lever mount can be designed, for example, as a hollow-cylindrical receiving shell. The radius of the receiving shell can be adapted to the outer radius of the lever to be accommodated. The receptacle can have a longitudinal axis that can coincide with the longitudinal axis of the connecting portion. The lever receptacle can pass over the connecting section at least partially, in particular seamlessly.

It has also proven to be advantageous if the bolt receptacle of the second bar arm has a projection for interacting with a shoulder of the lever to be accommodated in the bolt receptacle. This configuration enables a secure and predefined connection between the joint securing device and the corresponding lever. Furthermore, with regard to the object mentioned at the outset, a locking drive for a locking device, in particular a door locking device, is provided with two levers which can be rotated relative to one another about a joint axis and are connected via a joint pin, and a joint safety device according to any one of the preceding claims.

The advantages already described with regard to securing the joint result.

Furthermore, with regard to the shutter drive, it has proven to be advantageous if the hinge pin extends through the two levers. This configuration ensures in a simple manner that the two levers can be pivoted or rotated in relation to one another. The two levers can have corresponding recesses, for example in the form of bores, through which the hinge pin can extend. The two levers can thus be connected to one another in the manner of a hinge joint. The levers can have a flat area in the area of the bore, so that they are designed flat at least in the friction area. This is particularly advantageous for a round or rod-shaped lever.

It has also proven to be advantageous if a lever is connected to the pivot pin in a rotationally fixed manner and a lever is not rotationally fixed. In particular, the second lever can be non-rotatably connected to the pivot pin and the first lever can be non-rotatably connected. The pivot bolt can be connected to the first lever in one piece, for example.

Furthermore, it has proven to be advantageous if the joint securing device is connected in a rotationally fixed manner to one of the two levers, in particular to the second lever.

It is advantageous if a lever is connected in an axially fixed manner to the pivot bolt, so that it cannot be moved onto the pivot bolt in the axial direction. The other lever can be fixed in the axial direction relative to the first lever by the joint securing means, so that both levers are then secured against axial movement.

With regard to the configuration of the levers, it has proven to be advantageous if one lever is configured as a drive lever and one lever as a rod that can be moved via the drive lever. The drive lever can be connected to a drive, such as a door handle, an actuator or an electric drive. A movement of the drive lever can then be transmitted to the other lever or to the rod via the pivot pin. The drive lever can be designed in the form of a plate and have an oval shape. The rod can be designed as a push rod and transmit pressure forces in the longitudinal direction of the rod. In the case of long rods in particular, axial forces can occur due to the buckling problem explained at the outset, which can ensure that the rod can slip off the hinge pin if there is no hinge securing device.

With regard to the drive lever, it has proven to be advantageous if it can be rotated about a drive axis that is arranged parallel to the hinge axis. The joint axis can thus move on a circular path around the drive axis, and the second lever can move in the manner of a connecting rod.

With regard to the connection of the joint safety device, it has proven to be advantageous if this is connected in a rotationally fixed manner to one of the levers, in particular to the rod. The joint securing device can thus move relative to the drive lever together with the rod when the drive lever is moved.

Furthermore, the shutter drive can also have a further lever. This can be connected to the second lever. The connection can be configured in exactly the same way as that between the first lever and the second lever. Furthermore, the connection of the second Lever and this third lever be secured by a joint lock of the type described above. If the first lever is designed as a drive lever, the third lever can be driven by the drive lever via the second lever. The third lever can be configured in the same way as the first lever and can move parallel to it. Furthermore, a closure, in particular a door lock, with a

Proposed shutter drive, wherein the shutter drive is configured in the manner described above.

The closure can be designed, for example, as a cam lock or as a bar lock, and the closure drive can be used, for example, to drive a corresponding cam or a lock bar.

With regard to the connection of the joint safety device to the locking drive or to the levers, the joint safety device can first be pushed onto the levers at a certain angle until the bolt receptacles of the two bracket legs lie on the joint bolt. The joint securing device can then be rotated about the joint axis and the connecting section can be connected to one of the two levers in the manner of a clip connection. In the connected position, the two bracket legs of the joint securing device encompass the two levers and thus prevent the two levers from moving axially relative to one another. In order to release the joint lock again, it is necessary to first unclip the connecting section from the second lever.

Fig. 1

einen Verschlussantrieb für einen Türverschluss mit einer aus dem Stand der Technik bekannten Gelenksicherung;

Fig. 2a, 2b

eine Gelenksicherung gemäß der Erfindung in zwei verschiedenen perspektivischen Seitenansichten;

Fig. 3

die Gelenksicherung in fünf verschiedenen Projektionsansichten;

Fig. 4

einen Verschlussantrieb gemäß Fig. 1 mit einer Gelenksicherung gemäß der Erfindung in einer perspektivischen Seitenansicht;

Fig. 5

den Verschlussantrieb gemäß Fig. 4 in verschiedenen Seitenansichten.

Further details and advantages of the joint securing device according to the invention will be explained in more detail below with reference to the drawings of an exemplary embodiment of the invention, also in comparison to a solution known from the prior art. Show in it:

1

a lock drive for a door lock with a joint safety device known from the prior art;

Figures 2a, 2b

a joint safety device according to the invention in two different perspective side views;

3

the joint lock in five different projection views;

4

according to a shutter drive 1 with a joint safety device according to the invention in a perspective side view;

figure 5

according to the shutter drive 4 in different side views.

In the representation of 1 1 shows a shutter drive 10 of a shutter with a hinged safety device, as is known from the prior art. Other components of the closure, such as a closure tongue and an actuating element for actuating the latch tongue, are not shown in the illustration.

The shutter drive 10 consists essentially of the two levers 2 and 3 that can be rotated about a joint axis G, the lever 2 being designed as a drive lever 2 and the lever 3 as a lever rod 3 . The drive lever 2 is connected to a pawl, which is not shown in the figure and can be actuated manually, and is mounted so that it can rotate about the drive axis A. When the drive lever 2 is actuated accordingly, it is rotated about the drive axis A. This leads to an actuation also the pivot pin 7 arranged on the drive lever 2, which connects the two levers 2, 3 to one another, is also pivoted about the drive axis A on a circular path. The lever rod 3 is pivotably mounted on the hinge pin 7 and also moves as a result of the rotary movement of the drive lever 2 .

As this also in the 1 as can be seen, the lever rod 3 is connected at the upper end to a further lever 2, which in the exemplary embodiment is designed in exactly the same way as the lower lever 2 and therefore also bears the same reference number. Due to the rod connection between the lower lever 2 and the upper lever 2, which is also mounted to pivot about an axis parallel to the drive axis A, the upper lever 2 moves about this axis when the lower lever 2 is actuated. The rod connection via the lever rod 2 therefore basically causes the two levers 2 to move in the same direction. The upper lever 2 is indirectly connected to a cam not shown in the figures. This cam can thus be moved by actuating the lower lever 2 .

Due to the power transmission of the lever rod 3, this is subjected to pressure. This leads to the lever rod 3 being deflected perpendicular to the rod axis or being deformed perpendicular to the rod axis. This deformation leads to axial forces which act on the lever rod 3 in the direction of the joint axis G. It can therefore happen that the lever rod 3 detaches itself from the lever 2 due to an axial movement. In order to prevent a corresponding axial movement, a joint safety device is provided which on the one hand prevents an axial movement of the lever rod 2 on the hinge pin 7 but still allows a rotary movement of the lever rod 3 relative to the lever 2.

According to the configuration known from the prior art 1 a joint lock designed as a locking ring is provided for this purpose. The retaining ring can be placed on the hinge pin 7 and positively engage in a groove arranged on the hinge pin 7 . The locking ring thus forms an axial lock for the lever rod 3, so that it can no longer slip off the hinge pin 7 even if it is deformed or if there are axial forces.

Both the upper connection between the lever rod 3 and the upper lever 2 and the lower connection between the lever rod 3 and the lower lever 2 are secured by a corresponding locking ring. In the figure 1 the upper locking ring is already shown in a mounted position and the lower locking ring is shown in a kind of exploded view for the sake of clarity.

In the further Figures 4 and 5 is the shutter drive 10 as shown in FIG 1 shown, but no locking ring is provided to secure the levers 2, 3, but a joint lock according to the invention 1.

Based on Figures 2 to 5 the more precise configuration of the joint safety device 1 as well as the assembly and functioning of the joint safety device 1 will now be explained in more detail. The joint fuse 1 has as shown in the Figures 2a, 2b a bracket section 4 with two bracket legs 4.1, 4.2 extending parallel to one another, which form a receiving space 6 in which the two levers 2, 3 to be connected or secured can be accommodated. At one end, the bracket section 4 or the two bracket legs 4.1, 4.2 are each connected to a connecting section 5 designed as a latching section 5, so that the joint securing device 1 has a U-shaped cross section.

The latching section 5 serves to connect the joint securing device 1 to the lever rod 3 . For this purpose, the latching section 5 is designed in the manner of a hollow cylinder segment and has a segment angle of approximately 270 degrees, so that the profile of the latching section is open in a range of approximately 90 degrees. To connect the joint securing device 1 to the lever rod 3, the open area of the latching section 5 can be placed on the lever rod and then clipped onto the lever rod 3 by hand. Due to the rod-shaped lever 3, the latching section 5 initially widens when it is pressed onto the lever rod 3. When crossing the widest point of the lever rod 3, the internal stress in the material then leads to the latching section 5 automatically connecting to the lever rod 3. In order to connect the joint safety device 1 or the latching section 5 to the lever rod 3, no tools are required, but the force to be applied both for assembly and for disassembly of the joint safety device 1 with the lever rod 3 can be applied purely manually by hand. In the connected position, in which the joint securing device 1 is clipped onto the lever rod 3, the two elements are then securely connected to one another. This connected position is, for example, in the 4 can be seen when the lever rod 3 is connected to the upper lever 2.

To prevent an axial movement of the lever rod 3 relative to the lever 2 , the two bracket legs 4 . 1 , 4 . This is the case, for example, in the middle illustration figure 5 to recognize. Since the lever 2 cannot move axially and is connected to a door, for example, the lever rod 3 is also fixed in the axial direction relative to the lever 2 by the joint securing device 1 , so that it cannot slip off the joint pin 7 .

The first bracket leg 4.1 has a bolt receptacle 4.11 at the lower end, which is designed in the manner of a semicircular bore. In the mounted state, the part of the hinge pin 7 that protrudes laterally relative to the drive lever 3 lies in this pin receptacle 4.11. The part of the hinge pin 7 that protrudes laterally in relation to the lever rod 3 lies in a corresponding pin receptacle 4.21, which is arranged at a free end of the second bracket arm 4.2. The two bolt receptacles 4.11, 4.21 of the joint retainer 1 are aligned with one another, so that the pivot pin 7 is received in both bolt receptacles 4.11, 4.21 or the joint retainer 1 is in a defined position relative to the pivot pin.

Since the joint safety device 1 is connected to the lever rod 3 via the latching section 5 , the joint safety device 1 moves accordingly when the lever rod 3 moves in relation to the lever 2 . The first bracket leg 4.1 therefore slides on the drive lever 2 with a sliding surface 4.12 facing the second bracket leg 4.2. When the lever rod 3 moves axially, the sliding surface 4.12 then comes into contact with the lever 2 or is pressed more strongly against it. A further axial movement of the lever rod 3 is then blocked due to the first bracket leg 4.1 or due to the sliding surface 4.11.

In addition to the bolt receptacle 4.21, the second bracket arm 4.2 also has a lever receptacle 4.22 for receiving the lever rod 3. The lever mount 4.22 is adapted to the contour of the lever rod 3 and designed as a concave receiving shell. When the joint lock 1 is connected to the lever rod 3, the lever rod 3 lies in the lever mount 4.22. The lever receptacle 4.22 is directly adjacent to the latching section 5.

As also in the figures, in particular in the Figure 2b it can be seen that the bolt receptacle 4.21 of the first bracket arm 4.1 protrudes in the direction of the receptacle space 6 at least in relation to the lever receptacle 4.22. This configuration of the second bracket leg 4.2 is precisely adapted to the contour of the lever rod 3. In the lower area, in which it is connected to the hinge pin 7 , this has a flattened area, so that the second bracket leg 4 .

To connect the joint lock 1 to the levers 2, 3, the joint lock 1 is first pushed at a certain angle onto the two levers 2, 3 connected via the corresponding joint bolt 7 until the joint bolt 7 is in the two bolt receptacles 4.11, 4.21 of the two bracket legs 4.1 , 4.2 lies. In this position, the two bracket legs 4.1, 4.2 already encompass the two levers 2, 3 to be connected and thus prevent an axial movement of the levers 2, 3 relative to one another. The joint securing device 1 is then rotated about the joint axis G until the latching section 5 is in contact with the lever rod 3 . In this position, the latching section 5 and thus the joint securing device 1 can be clipped onto the lever rod 3 by pressing on the latching section 5 . In the mounted position, the joint lock 1 is securely connected to the lever rod 3 and prevents the levers 2, 3 from moving axially.

References:

1

joint lock

2

lever, drive lever

3

lever, lever rod

4

ironing section

4.1

hanger legs

4.11

bolt mount

4.12

sliding surface

4.2

hanger legs

4.21

bolt mount

4.22

lever mount

5

Connection section, latching section

6

recording room

7

pivot pin

10

shutter drive

A

drive axle

G

joint axis

Claims (12)

1. Joint securing means for securing two levers (2, 3) which are rotatable relative to one another about a joint axis (G) and which are connected via a joint pin (7), comprising a bow portion (4) for axially fixing the two levers (2, 3) on the joint pin (7) and comprising a connecting portion (5) for connecting to one of the two levers (2, 3), wherein the connecting portion (5) is configured as a latching portion (5) for latching connection with one of the two levers (2, 3),
   characterized
   in that the bow portion (4) has two bow legs (4.1, 4.2), wherein the two bow legs (4.1, 4.2) are situated opposite one another, and a receiving space (6) for receiving the two legs (2, 3) is provided between the two bow legs (4.1, 4.2).
2. Joint securing means according to Claim 1,
   characterized in that the two bow legs (4.1, 4.2) are each connected at one end to the connecting portion (5) and have a free end at the respective opposite end.
3. Joint securing means according to either of Claims 1 and 2, characterized in that the first bow leg (4.1) has, at a free end, an in particular semicircular pin receptacle (4.11) for receiving the joint pin (7).
4. Joint securing means according to one of Claims 1 to 3,
   characterized in that the first bow leg (4.1) has a sliding surface (4.12) for sliding on the first lever (2).
5. Joint securing means according to one of Claims 1 to 4,
   characterized in that the first bow leg (4.1) is in the form of a plate.
6. Joint securing means according to one of Claims 1 to 5,
   characterized in that the second bow leg (4.2) has, at the free end, a pin receptacle (4.21) for receiving the joint pin (7).
7. Joint securing means according to one of Claims 1 to 5,
   characterized in that the second bow leg (4.2) has a lever receptacle (4.22) for receiving one of the levers (2, 3), in particular the second lever (3).
8. Closure drive for a closure, in particular a door closure, comprising two levers (2, 3) which are rotatable relative to one another about a joint axis (G) and which are connected via a joint pin (7) and comprising a joint securing means (1) according to one of the preceding claims.
9. Closure drive according to Claim 8,
   characterized in that the joint pin (7) extends through the two levers (2,3).
10. Closure drive according to either of Claims 8 and 9,
    characterized in that the joint securing means (1) is fixedly connected to one of the two levers (2, 3).
11. Closure drive according to one of Claims 8 to 10,
    characterized in that one lever (2) is configured as a drive lever and one lever (3) is configured as a lever rod which is movable via the drive lever.
12. Closure having a closure drive (10) according to one of Claims 8 to 11.

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