WO2021018350A1 - Locking device - Google Patents

Abstract

The invention relates to a locking device (10) for a closing element (20), in particular a door, having a locking element (3) which is rotatable back and forth about an actuating axis (B) between a locking position and an unlocking position, wherein the locking element (3) can swivel about an emergency unlocking axis (N) for emergency unlocking from the locking position to an emergency unlocking position, the emergency unlocking axis (N) and the actuating axis (B) being arranged at an angle to each other. The invention additionally relates to a closing element (20) having such a locking device (10) and to a method for emergency unlocking of a locking device (10).

Description

Locking device

The invention betn ^'fft a locking device for a closing element, in particular a door, with a back to an operating axis between a locking position and an unlocking and forth drehba ren locking element.

Such locking devices are used in very different Be rich and can be used for all possible locking elements, such as for doors, windows or hatches. Appropriate locking elements can be used, for example, to open certain areas such as engine rooms, wind turbines, bank rooms, Locking off walk-in closets, safes or server rooms and protecting them against unauthorized access.

For this purpose, the closing elements can be moved back and forth between a closed position and an open position, access to the corresponding areas being enabled in the open position and prevented in the closed position.

In order to lock the closing elements in the closed position so that they cannot be opened, the closing elements mostly have one or more locking devices. These Ver locking devices usually have a locking element which is rotatable to and fro about an actuating axis between a locking position and an unlocking position. In the locking position, the locking elements engage behind or in a fixed frame of the locking element, for example in the manner of a sash tongue, and thus fix the locking element with respect to the immovable frame. In the case of a door, the locking elements engage, for example, behind or in a door frame.

Such locking devices have proven themselves in the past, but in some cases it is not possible to easily rotate the locking element from the locking position back into the unlocking position. Because often, for example, Arretiervorrich lines are provided in the form of locks that must first be unlocked in order to move the locking element accordingly.

Problems can arise in particular if these locks can only be reached from the outside of the locking element, but not from the inside. For example, if a person is unintentionally locked in a room and the locking element can then no longer rotate around the actuation axis from the locking position to the unlocking position, this person can no longer leave the room without help, but is then dependent on help from outside. It can even endanger life and limb if the person does not receive appropriate help.

Proceeding from this, the invention aims to provide a locking device with which such a risk is reduced.

This object is achieved by a locking device which has the features defined in claim 1. Advantageous further training can be found in the dependent claims.

The configuration that the locking element for emergency unlocking can be pivoted about an emergency unlocking axis from the locking position into an emergency unlocking position and the emergency unlocking axis and the actuating axis are arranged at an angle to one another results in the advantage that the locking element, even if a rotary movement about the actuating axis is not possible is, can be pivoted by a movement around the emergency unlocking axis into a position in which the locking element can be opened. The angled arrangement offers the advantage that the locking element can be automatically transferred into the emergency unlocking position by applying a force, in particular a pressure force, to the closing element. It is therefore not necessary to actively pivot the locking element into the emergency unlocking position, but rather the locking element can be opened intuitively, for example in an emergency situation.

With regard to the angular arrangement, it has been found to be advantageous if the emergency release axis and the actuation axis have one Angle between 45 and 135 degrees, preferably between 70 and 110 degrees, particularly preferably between 80 and 100 degrees, very particularly preferably between 85 and 105 and in particular of 90 degrees. The closer the angle is to 90 degrees, the easier it is to transfer the locking element into the emergency unlocking position, in which the closing element can be opened. If the actuation axis and the Notentrie gelungsachse are perpendicular to each other, the locking element can thus be most easily transferred to the emergency unlocking position. The actuation axis and the emergency unlocking axis can intersect, but they can also be arranged skewed to one another. Even if these are arranged skewed to one another, the angles given above can be defined. What is meant is the cutting angle when the axes are shifted in parallel.

With regard to the actuation of the locking element, it has been found to be advantageous if the locking element is rotatable about the actuating axis via a actuating element. Through the actuating element, the locking element can be moved back and forth between the locking position and the unlocking position in a simple manner and in particular by hand. The actuating element can be arranged on the outside of the closing element and designed, for example, as a lever, latch or knob. The actuating element can be rotatably coupled to the locking element. This enables a rotational movement of the actuating element to lead to a corresponding rotational movement of the locking element. As a rule, the locking element must be swiveled 90 degrees out of the locked position until it reaches the unlocked position. With a corresponding direct rotary coupling, the actuating element must therefore also be moved in the same angular range. In contrast, other Winkelbe areas are also possible. Furthermore, it has been found to be advantageous if the locking device has an emergency actuation element. This can be coupled to the locking element in an actuating position in such a way that the locking element can be rotated back and forth between the locking position and the unlocking position via the emergency actuation element about the actuation axis. The emergency actuation element can be arranged on the side of the closing element opposite the actuation element. In particular, the emergency actuation element is arranged on the inside of the closing element. The emergency actuation element can have a handling area which can be configured, for example, as a lever, latch or knob and via which the emergency actuation element can be moved manually. If rotation of the locking element about the actuation axis is not prevented, the locking element can be rotated via the Notbe actuating element in a very analogous manner to actuation by the actuating element. In the actuating position with the locking element, the not actuating element can in particular also be coupled to the actuating element. When the actuating element or the emergency actuating element is rotated about the actuating axis, the corresponding other element can also rotate around the actuating axis. If a movement of the locking element around the actuation axis is prevented, a movement of the emergency actuation element and the actuation element around the actuation axis is also prevented.

It has also been found to be advantageous if the Notbetäti supply element in the actuating position is coupled to the locking element such that it cannot be moved relative to the Notbetäti supply element. In particular, the elements are coupled in such a way that the emergency actuation element blocks a movement of the locking element about the emergency unlocking axis from the locking position into the emergency unlocking position. The possibility of emergency release The closing element can be opened in a dangerous situation. However, this option should not be misused for normal opening of the closing element, since otherwise it cannot be guaranteed that the closing element can be securely locked and protected against unauthorized opening. If the emergency actuation element is in the actuation position, the closing element can therefore only be opened when the locking element has been in the unlocked position. Since the emergency actuation element can advantageously only be reached and actuated from the inside of the locking element, it is therefore not possible to remove the coupling of the emergency actuation element and locking element from the outside in order to pivot the locking element about the emergency unlocking axis and to open the locking element.

In order to be able to open the closing element, in particular in an emergency situation, the emergency actuation element can be transferred into a release position in which the locking element can be moved relative to the emergency actuation element. In the release position, the coupling between the emergency actuation element and the locking element can be lifted such that the locking element can be pivoted about the emergency release axis. In terms of construction, the Notbetäti supply element can be pivoted about an Notbetäti in the release position and the Notbetäti can be arranged parallel to the Notbetiegelungsachse. The emergency actuation element can thus have a double function. In the actuating position for normal unlocking of the locking element, it can rotate it about the actuating axis and in the release position it can ensure that the locking element can move into an emergency unlocking position. It has been found to be advantageous if the Notbetäti supply element is coupled to the locking element in the actuating position and is not coupled to the locking element in the release position. In the release position, the locking element can be moved freely and independently with respect to the emergency operating element.

In order to achieve the most intuitive opening of the closing element, the emergency actuation element can be pushed from the actuation position into the release position. By applying a corresponding compressive force to the emergency actuation element, this can first be moved into the release position and then the closing element can be opened in one go by a further compressive force. The pressure force that continues to act after the release ensures that the locking element is swiveled out into the emergency unlocking position through the movement of the closing element.

Furthermore, it has been found to be advantageous if the locking element can only be pivoted about the emergency unlocking axis from the locking position into an emergency unlocking position when the emergency actuating element is in the release position. If the emergency operating element is in the operating position, a corresponding movement of the locking element is prevented. From a structural point of view, it has also been found to be advantageous if the emergency actuation element has a locking contour for locking the movement of the locking element about the emergency unlocking axis from the locking position to the emergency unlocking position. The Notbetäti supply element can interact with the locking element via the locking contour and prevent it from moving. The Notbetäti supply element can wippenfömig with regard to the Notbetätiachse be designed. The locking contour can be arranged on one rocker side and a handling area for manually moving the emergency actuation element can be provided on the other rocker side. It is also advantageous if the locking contour has a stop surface and a sliding surface. The stop surface can be in the actuation position in the path of movement of the locking element and the sliding surface can act as a guide for the locking element in the release position when moving about the emergency unlocking axis. The stop surface can be located in the release position in the pivoting path of the locking element, so that the stop surface prevents movement of the locking element. The stop surface can thus function like a ratchet. If the emergency actuation element is moved into the release position, the stop surface moves out of the path of movement of the locking element and thus allows the locking element to move into the emergency unlocking position. During this movement, a part of the locking element, in particular a locking tooth, slides on the sliding surface of the locking element. The sliding surface can thus act as a guide for the movement of the locking element, which prevents the locking element from tilting and ensures reliable emergency opening of the closing element. The sliding surface can be designed as a circular path. The center of the circular path can coincide in the release position with the emergency release axis. The sliding surface can have one or two side walls, which can provide for lateral guidance of the locking element.

Furthermore, it has turned out to be advantageous from a structural point of view if the locking contour is designed in the shape of a fork. The locking contour can in particular be designed in the manner of a two-pronged fork, which leads to an even distribution of force. The locking contour can thus each comprise two stop surfaces and two sliding surfaces. With regard to the locking element, it has been found to be advantageous if this has a locking contour with at least one locking tooth for interaction with the emergency actuation element. The locking contour can be configured to correspond to the locking contour of the emergency actuation element, so that the locking element is reliably locked and released. The Verriege treatment contour can also be configured fork-shaped, in particular in the manner of a two-pronged fork. Thus, two locking teeth can also be provided corresponding to the two stop surfaces.

If the emergency actuation element is pivoted into the release position, the locking teeth slide on the sliding surfaces of the locking contour. The locking element can furthermore have a locking tongue with which it can engage behind or in a frame of the locking element in order to fix this relative to the frame.

Furthermore, it has been found to be advantageous if the Notbetäti supply element and the locking element are pivotally connected to a bearing element. The bearing element can thus ensure a connection between the emergency actuation element and the locking element, so that a rotational movement of the emergency actuation element about the actuation axis leads to a corresponding rotational movement of the locking element. The Notentriegelungsachse and the Notbet finishingach se can both extend through the bearing element. The bearing element can each have a bore to accommodate bearing bolts which can act as pivot axes for the emergency actuating element and the locking element. The bores can each be arranged at one end of the bearing element.

The locking contour of the emergency actuation element and the locking contour of the locking element can be on different sides of the load be arranged gerelements and encompass the respective ends of the bearing element. The design of the locking contour and the locking contour as two-pronged forks thus have the advantage that one prong is arranged on one side and the other prong on the other side of the bearing element, which enables even force distribution. Furthermore, the bearing element can have a stop, in particular a stop pin, which can interact with the locking element in such a way that a movement of the locking element, especially in the direction of the locking position, is limited. This enables the locking element to be positioned as precisely as possible.

It is also advantageous if the bearing element is rotatably coupled to the actuating element via a connecting element. This enables the locking element to be easily rotated between the locked and unlocked positions via the actuating element. The connection element can be designed as a profiled rod, in particular as a square rod, and the bearing element can have a correspondingly shaped bore in which the connection element is received. Due to the profiled and therefore non-circular configuration, the actuating element and the bearing element can thus be rotatably coupled to one another in a simple manner in a form-fitting manner. The connecting element can extend through the closing element and thus connect the actuating element arranged on the outside to the elements arranged on the other side of the closing element. The actuation axis can in particular extend centrally through the connecting element and thus also through the bearing element. With regard to the actuation axis, the emergency actuation element and the locking element and / or the Notbe actuation axis and the emergency release axis can be arranged on opposite sides of the bearing element. To support the connecting element in the closing element, a bearing block can be provided which can be received in the closing element so that it cannot rotate. The bearing block can have a non-round contour for this. The bearing block can have a cylindrical bearing bore in which the connecting element can rotate about the actuation axis.

Furthermore, it has been found to be advantageous if the Notbetäti supply element is pretensioned via a spring element in the actuating position. The emergency actuation element can be held in the actuation position by the bias, which leads to a reliable Verriege development of the closing element. The spring element can bias the Notbetäti supply element relative to the bearing element. The bearing element can, for example, have a bearing train on which the spring element can be supported. The corresponding spring element can be designed as a helical compression spring.

Furthermore, it has been found to be advantageous if the locking element is biased by a spring element. The spring element can preload the locking element in the direction of the locking position. This spring element ensures that the locking element is securely held in the locking position. When the emergency actuation element has been moved into the release position, the locking element must be moved against the force of the spring to open the closing element. This force must therefore also be applied to the emergency actuation element or directly to the closing element by the person. The spring element can be supported against the bearing element. The spring element can be designed as a torsion spring.

Alternatively, it is also possible for the corresponding spring element to bias the locking element in the direction of the emergency unlocking position. In this case, the locking element automatically snaps into the tentriegelungsstellung when the emergency actuation element is moved into the release position and the closing element can be opened.

In order to secure the locking element in the locked position against unauthorized opening, it has been found to be advantageous if the actuation element can be locked via a locking device. The locking device can prevent rotational movement of the actuating element about the actuation axis. Since the actuating element is rotatably coupled to the bearing element and also to the emergency actuating element and the locking element, the locking element can accordingly no longer be rotated about the actuating axis. In this position, the closing element is therefore reliably locked. It is only possible to open the closing element when the actuating element is locked if the emergency actuating element is then transferred into the release position and the locking element into the emergency unlocking position. The Arretiervor direction can be designed as a lock, in particular as a padlock. The actuating element can be fixed with respect to the closing element via the locking device, so that the latter cannot be rotated relative to the closing element.

The terms used with regard to the locking device with regard to the inside and the outside of the closing element or the door are to be understood as examples. The invention can be used in an analogous manner vice versa. Thus, the actuating element can also be arranged on the inside and the bearing element, the locking element and the emergency actuation element can also be arranged on the outside of the closing element.

Furthermore, with regard to the object mentioned at the beginning, a closing element, in particular a door, is proposed which has a locking device of the type described above. The result is advantages described above with regard to the locking device.

With regard to the arrangement of the elements, it has been shown to be advantageous if the actuating axis extends perpendicularly through the closing element. In the case of a door, this corresponds to the normal direction of the door leaf. The emergency release axis and the emergency actuation axis can run parallel to the locking element or the door leaf.

The invention also provides the task of specifying a corresponding method for emergency unlocking of a locking device.

This object is achieved by a method with the features of claim 15, according to which the locking device has a locking element rotatable back and forth about an actuating axis between a locking position and an unlocking position, the locking element for emergency unlocking about an emergency unlocking axis from the Locking position is pivoted into an emergency unlocking position, the emergency unlocking axis and the actuating axis being arranged at an angle to one another. If the locking element is pivoted about the emergency unlocking axis, it can also be unlocked and the locking element opened if a normal unlocking movement, i.e. a rotary movement about the actuating axis, is not possible.

It when the locking device is designed in the above be written manner is advantageous. The advantages described with regard to the locking device result. Further advantages and developments of the invention are to be described below using an exemplary embodiment. Show in it:

Fig. 1 shows the locking device in a perspective Seitenan;

FIG. 2 shows the locking device according to FIG. 1 in a rear view;

3 shows a simplified exploded view of the locking device; Fig. 4 is a plan view of a locking device arranged on a door;

FIG. 5 shows a plan view according to FIG. 4 without a door.

The locking device 10 shown in the figures can be used for locking a door 20 Ver. In Fig. 1, the locked state of the locking device 10 is shown. This can be seen from the position of the locking element 3, which will also be explained below with a view to FIG. 4. In the position shown, the door 20 is set against the fixed frame 21 of the door 20 Festge so that the door 20 can not be opened.

To open the door 20, the locking element 3 must first be transferred from the locking position shown into an unlocking position. For this purpose, the actuating element 4 arranged on the outside of the door 20 is rotated about the actuating axis B. The actuating element 4 is rotatably coupled to the locking element 3, so that the locking element 3 then also rotates accordingly about the actuating axis B. In the illustrated embodiment, it is necessary to rotate the actuating element 4 by approximately 90 degrees until the locking element 3 has been rotated so far that it no longer engages behind the door frame 21 and the door 20 can be opened. In order to move the locking element 3 in the same way from the inside of the door 20, an emergency actuation element 1 is provided on the inside of the door 20, which basically functions in the same way as the actuation element 4. The emergency actuation element 1 is also connected to the locking element 3 coupled, so that a rotary movement of the Notbe actuating element 1 about the actuating axis B results in the locking element 3 being moved accordingly. The emergency actuation element 1 is not only coupled with the locking element 3, but also with the actuation element 4 via a connecting element 9, which can be seen in FIG. 3 and is designed as a square pin. When rotating around the actuation axis B, they move both the emergency actuation element 1 and the actuation element 4 and the locking element 3 equally. So that the door 20 can be reliably secured against unauthorized opening, a locking device 5 designed as a padlock is provided on the outside. This locking device 5 prevents the actuating element 4 from being moved with respect to the door 20 or from being able to be rotated about the actuating axis B. Because via the locking device 5, the actuating element 4 is fixed positively sig with respect to the bearing fitting 2.2. The bearing fitting 2.2 is non-rotatably connected to a bearing block 2.1, as can also be seen in the exploded view of FIG. Due to its non-circular outer contour, the bearing block 2.1 is received in the door 20 so that it cannot rotate, so that the actuating element 4 is then also fixed with respect to the door 20 by the locking device 5.

In order to open the door 20 via the actuating element 4 and to pivot the locking element 3 into the unlocking position, the locking device 5 must first be removed or moved into a position in which a rotary movement of the actuating element 4 is possible. Since the locking device 5 can only be removed from the outside of the door 20 or transferred into a corresponding position, it is no longer possible to open the door 20 from the inside by rotating the emergency actuation element 1.

In order to still be able to open the door 20, even if rotation of the locking element 3 about the actuating axis B by the Arretiervorrich device 5 is prevented, an emergency release mechanism is provided, which can be operated from the inside of the door 20. For this purpose, the emergency actuation element 1 can be pressed in the direction of the door 20, that is to say pivoted about an emergency actuation axis E which is perpendicular to the actuation axis B. This movement releases the locking element 3 and allows it to move about an emergency release axis N which is perpendicular to the actuation axis B and parallel to the emergency actuation axis E. With reference to FIG. 3, the more precise structure or the cooperation between the emergency actuation element 1 and the locking element 3 will now be described in more detail, before the movement of the elements will be discussed in greater detail with reference to FIGS. 4 and 5. As can be seen in FIG. 3, both the Notbet finishingele element 1 and the locking element 3 are mounted on a common La gerelement 8. As can also be seen, both the emergency actuation axis E, the emergency unlocking axis N and also the actuation axis B run through the bearing element 8. When the locking element 3 is actuated via the actuation element 4, this is through the door 20 and through the bearing block 2.1 connecting element 9 extending therethrough is rotated accordingly. The connecting element 9 is rotatably coupled to the bearing element 8 due to the square seat, so that the bearing element 8 rotates accordingly when the actuating element 4 is rotated. Left and right next to the receptacle for the connecting element 9 is rotated by 90 degrees on each side of the bearing element a bore vorgese hen, which allows a pivotable connection of the bearing element 8 with the emergency actuation element 1 and the locking element 3.

In Fig. 1 and also in Figs. 4 and 5 position shown, the United locking element 3 is initially not pivotable about the emergency locking axis N, since the emergency operating element 1 has a corresponding

Swivel movement prevented. 4 it can be seen that the emergency actuation element 1 has a locking contour 6 with a stop surface 6.1, which is arranged in the corresponding movement path of the locking element 3 and therefore prevents a pivoting movement about the Notentriege treatment axis N. The locking element 3 has a correspondingly designed locking contour 7 with a locking tooth 7.1, which rests against the stop surface 6.1 in the position shown. In this position, the emergency actuation element 1 is coupled to the locking element 3 and the locking element 3 can be pivoted about the actuation axis B via the Notbe actuation element 1, provided that the locking device 5 does not prevent a corresponding movement, but not around the emergency unlocking axis N.

But in order to now pivot the locking element 3 about the emergency unlocking axis N, the stop surface 6.1 must first be pivoted out of the movement path of the locking element 3. The corresponding movements in the event of an emergency actuation are indicated in FIG. By exerting a compressive force on the Notbetieterele element 1, this is rotated about the emergency actuation axis E into a release position, whereby the stop surface 6.1 is then pivoted out of the movement path of the locking element 3. Since then the stop surface 6.1 no longer in the movement path of the locking element 3 or the Locking tooth 7.1 is arranged, the locking element 3 can be pivoted from the locking position about the emergency unlocking axis N into an unlocking position.

In FIGS. 4 and 5 it can also be seen that the locking contour 6 also has a curved contour in plan view. This is a sliding surface 6.2 whose precise design can best be seen in FIG. 3. The sliding surface 6.2 serves in the release position of the Notentriegelungselements 1 as a guide for the locking element 3 or for the locking tooth 7.1 and thus ensures a guided movement of the locking element 3 when moving about the Notentriege management axis N.

As can be seen in Fig. 4, the door 20 can be opened to the outside ge. During the emergency release, ie initially when transferring the emergency release element 1 from the actuation position to the release position, a compressive force is applied to the emergency actuation element 1. Since this compressive force is directed in the same direction as the force that is required to open the door 20, the corresponding force only needs to be applied further to the door 20 or to the unlocking element 1 to open the door 20. With a corresponding movement, the locking element 3 or the locking tongue 3.1 of the locking element 3 is then pressed against the stationary door frame 21. Since a movement of the locking element 3 around the emergency unlocking axis N is then possible, further movement of the door 20 accordingly results in the locking element 3 being pivoted around the emergency unlocking axis N and not preventing the door 20 from opening, regardless of whether the actuator 4 is locked by the locking device 5 or not. As can be seen from FIG. 3, both the Notbetäti supply element 1 and the locking element 3 are each biased by a spring element. The emergency actuation element 1 is biased into the actuation position via the compression spring 1 .1, so that the force of the compression spring 1 .1 must be overcome in the event of an emergency release. The locking element 3 is biased by a torsion spring 3.2 in the direction of the locking position Ver. However, it is also possible that the torsion spring 3.2 biases the locking element 3 in the direction of the emergency release position. In this case, the locking element 3 jumps automatically into the emergency unlocking position as soon as the emergency actuation element 1 is moved into the release position and the stop surface 6.1 has been pivoted out of the path of movement of the locking element 3.

As can also be seen in FIG. 3, both the locking contour 6 and the locking contour 7 are designed in the manner of a two-pronged fork, so that in the event of an emergency unlocking, one of the prongs on one side of the bearing element 8 and the other Prongs on the other side of the bearing element 8 moved. As can also be seen in FIG. 3, two sliding surfaces 6.2, two stop surfaces 6.1 and two locking teeth 7.1 are also provided, each on opposite sides of the bearing element 8.

Reference number:

1 emergency actuation element

1.1 compression spring

2.1 bearing block

2.2 Bearing hardware

3 locking element

3.1 Lock tongue

3.2 torsion spring

4 actuator

5 locking device

6 locking contour

6.1 Stop surface

6.2 sliding surface

7 locking contour

7.1 locking tooth

8 bearing element

9 connecting element

10 locking device

20 door

21 door frame

B actuation axis

E emergency actuation axis

N emergency release axis

Claims

Patent claims:

1. Locking device for a locking element, in particular a door (20), with a locking element (3) that can be rotated to and fro about an actuating axis (B) between a locking position and an unlocking position,

characterized ,

that the locking element (3) can be pivoted for emergency unlocking around a no unlocking axis (N) from the locking position into a no unlocking position, the emergency unlocking axis (N) and the actuating axis (B) being arranged at an angle to one another.

2. Device according to claim 1,

characterized in that the emergency release axis (N) and the actuation axis (B) form an angle between 45 and 135 degrees, preferably between 70 and 110 degrees, particularly preferably between 80 and 100 degrees, very particularly preferably between 85 and 105 and in particular of 90 Degree includes.

3. Device according to one of the preceding claims,

characterized in that the locking element (3) can be rotated about the actuating axis (B) via an actuating element (4).

4. Device according to one of the preceding claims,

characterized by an emergency actuation element (1) which is coupled to the locking element (3) in an actuating position in such a way that the locking element (3) about the actuation axis (B) between the locking element via the emergency actuation element (1) Gelungsstellung and the unlocking position is rotatable back and forth.

5. Device according to one of the preceding claims,

characterized in that the emergency actuation element (1) in the actuation position is coupled to the locking element (3) in such a way that the locking element (3) cannot be moved relative to the emergency actuation element (1).

6. Apparatus according to claim 5,

characterized in that the emergency actuation element (1) can be transferred into a release position in which the locking element (3) can be moved relative to the emergency actuation element (1).

7. Device according to one of the preceding claims,

characterized in that the emergency actuation element (1) is coupled to the locking element (3) in the actuating position and is not coupled to the locking element (3) in the release position.

8. Device according to one of the preceding claims,

characterized in that the emergency actuation element (1) has a locking contour (6) for locking the movement of the locking element (3) about the unlocking axis (N) from the locking position to the unlocking position.

9. Apparatus according to claim 8,

characterized in that the locking contour (6) has a stop surface (6.1) and a sliding surface (6.2), the stop surface (6.1) in the actuating position in the movement path of the Locking element (3) is located and the sliding surface (6.2) in the release position acts as a guide for the locking element (3) when moving about the emergency release axis (N).

10. Device according to one of the preceding claims,

characterized in that the locking element (3) has a locking contour (7) with at least one locking tooth (7.1) for interacting with the emergency actuation element (1).

11. The device according to claim 4 to 10,

characterized in that the emergency actuation element (1) and the locking element (3) are pivotably connected to a bearing element (8).

12. Device according to one of the preceding claims,

characterized in that the emergency actuation element (1) is biased into the actuation position via a spring element (1.1).

13. Device according to one of the preceding claims,

characterized in that the locking element (3) is biased via a spring element (3.2) which biases the locking element in the direction of the emergency unlocking position.

14. Device according to one of the preceding claims,

characterized in that the actuating element (4) can be locked via a locking device (5).

15. Closing element, in particular door, with a locking device (10) according to one of the preceding claims.

16. A method for emergency unlocking a locking element (20), in particular a door, with a locking device (10), the locking device having a locking element (3) which can be rotated to and fro about an actuating axis (B) between a locking position and an unlocking position , where the

The locking element (3) for emergency unlocking is pivoted around an emergency unlocking axis (N) from the locking position into an emergency unlocking position, the emergency unlocking axis (N) and the actuating axis (B) being arranged at an angle to one another.