EP2213818A2 - Lock, in particular slideable dead bolt lock, with improved protection - Google Patents

Abstract

The push bolt lock (1), for a door and the like, has a barrier component (6) as a security lock on the gearing (5) movement. The interaction between the transmission unit (4,4') and the gearing at least allows release of the barrier component for a free gearing movement to move the bolt (3) from the closed into the open position.

Description

The present invention relates to a lock for a door or the like, which is designed in particular as a sliding bolt lock with a lock housing in which at least one locking mechanism is received with a latch. Locks of the present type are mainly used for doors, gates or windows, for example.

The bolt is movable into a closed position in which this protrudes from the lock housing for closing the door and thereby engages, for example, in a fixed strike plate, the so-called. Lock counterpart, and wherein the bolt is movable to an open position in which the bolt to Opening the door can be moved back into the lock housing.

The locking mechanism further comprises at least one transmission element which is rotatably received within the lock housing and which is designed to interact with a transmission element, can be moved by the interaction of the latch between the closed position and the open position.

From the DE 10 2008 009 511.7-15 is a generic castle with an improved locking mechanism already known. Here, the transmission element for interaction between the bolt and the transmission element is received linearly movable in the lock housing and executed in the form of a rack with a rear driving geometry. The bolt moves linearly between the open position and the closed position, and thus passes through an opening from the forend of the lock housing. Due to the opening required to carry out the bolt through the forend of the lock housing, there is the disadvantage of insufficient resistance to manual burglary attempts.

The reason for the insufficient resistance results in such locks by a lack of tumbler. As tumbler is basically that element or those elements which prevent a movement of a bolt positively in an open position and / or in a closed position. In locks of the present type, a locking of the bolt is merely effected by the actuation of the locking mechanism is held non-positively in the respective closing and / or opening position. Another, resistance-enhancing arrangement of a tumbler to form a security lock the movement of the bolt is not provided in such locks.

It is therefore the object of the present invention to carry out a lock of the present type with an increased protective effect.

This object is achieved on the basis of a lock according to the preamble of claim 1 in conjunction with the characterizing features. Advantageous developments of the invention are specified in the dependent claims.

The invention includes the technical teaching that at least one locking member for locking the movement of the transmission element is provided and arranged such that by the interaction between the transmission element and the transmission element at least one release of the locking member is allowed to release the movement of the transmission element create, by which the bolt can be transferred from the closed position to the open position.

The invention is based on the idea to provide a locking member acting as a tumbler, which can act on the movement of the transmission element such that a positive tumbler is enabled. Core of the invention is the unlocking of the locking member exclusively by the interaction between the transmission element and the transmission element.

If the bolt would be forcibly transferred from its closed position to its open position, no interaction takes place between the transmission element and the transmission element, since there is only a force flow from the latch to the transmission element. However, the unlocking of the locking member presupposes the interaction of the transmission element on the transmission element, so that the locking member remains even with violent force application to the bolt in the direction of the open position in the locking position. As a result, a particular designed as a sliding bolt lock lock is created, which has an increased resistance, since the locking of the bolt is not done only by a single non-positive tumbler.

It is of particular advantage that the locking member is received in the transmission element and is movable between a locking position and a release position. By the movement of the transmission element, the locking member is moved accordingly, wherein the locking member can be moved relative to the transmission element in both the locking position and in the release position. Since both the transmission element and the transmission element perform a movement and the arrangement of the locking member acts on the interaction between the transmission element and the transmission element, the recording of the locking member in the transmission element itself forms a particularly advantageous embodiment.

Advantageously, the transmission element has a driver which, upon rotation of the transmission element, interacts with the transmission element in such a way that the blocking member can be transferred from the blocking position into the release position. The transmission element is disc-shaped and forms a rotatable part of the locking mechanism. On a plane surface of the transmission element of the driver is formed in a pin-shaped, so that upon rotation of the transmission element, a movement of the driver along a circular path is generated. Consequently, upon rotation of the transmission element, the driver moves towards the still stationary transmission element. In this case, a movement of the driver takes place in the direction of the transmission element along the circular path, so that a component of motion perpendicular to the transmission element and another component of movement perpendicular to the first component of movement, in which at the same time the transmission element is moved to move the bolt.

At least a part of the locking mechanism has a receiving unit in which at least the transmission element and the transmission element are accommodated. Since the locking member is received in the transmission element, this is also integrated in the receiving unit. The transmission element is rotatably received in a rotary receptacle of the receiving unit and the transmission element is received linearly movable in a linear recording of the receiving unit, wherein the mobility of the transmission element is present in particular relative to the bolt.

The linear recording is introduced in the receiving unit and has a guide groove within the body of the receiving unit. The linear guide designed as a guide groove has at least one groove wall, wherein the locking geometry is designed as a latching groove in an edge of the groove wall and over a length has a freewheel which is determined such that the locking member at least over a part the path of the transmission element can be moved in the locking groove. If the driver moves along the circular path toward the transmission element, the movement component of the carrier in the direction of the transmission element pushes the blocking member from the blocking position into the release position. The movement component of the driver in the direction of movement of the transmission element causes a simultaneous start of the movement of the transmission element with movement of the locking member from the locking position to the release position. Consequently, the locking member moves over a freewheeling length within the locking groove, but to take the release position or at least a release area before the end of the locking groove, so that the transmission element can be moved beyond the detent position.

According to a further advantageous embodiment, the transmission element has a pocket-like locking member receptacle for receiving the locking member, wherein the interaction of the transmission element with the transmission element comprises an engagement of the driver in the locking member receiving. Upon movement of the driver by the rotational movement of the transmission element of this immersed to entrain the transmission element in the locking member recording, such that with immersion of the driver in the locking member receiving the locking member can be transferred by the driver from the locking position to the release position. Consequently, the locking member is linearly guided in the locking member receptacle, wherein the guide direction is aligned perpendicular to the direction of movement of the transmission element.

It is also advantageous that a spring element is provided which biases the locking member in the locking position, so that the transfer of the locking member from the locking position to the release position can be carried out by the driver against the spring force of the spring element. If there is no engagement of the driver in the locking member receiving, the locking member is always in the direction of locking in the locking groove biased. As soon as the transmission element reaches a linear position in which the locking member covers the locking groove, this springs into the locking position by the spring tension.

For engagement of the locking member in the locking groove, the locking member has a locking projection, wherein the receiving unit comprises a flat surface on which the locking member can slide with at least one body side surface. Consequently, the locking member may be guided between the flat surface of the receiving unit and the transmission element, wherein the locking member may be without bearing on the flat surface, for example via a guide groove within the transmission element, performed.

Furthermore, it has been found to be advantageous that the operative connection between the latch and the transmission element may comprise a lever element, wherein the transmission of the linear movement of the transmission element is effected on the lever element with a toothing, and wherein the lock is designed in particular as a sliding bolt lock and the movement of the bolt is linear. The transmission element may have a centrally arranged transmission geometry into which the driver part of a lock cylinder can engage. Consequently, with rotation of the lock cylinder, the rotation of the transmission element is caused.

In order to reverse the dependence of the direction of rotation of the lock cylinder on the direction of movement of the bolt between the open position and the closed position, a pinion can be arranged between the transmission element and the lever element. Of course, the locking mechanism is not limited to said components, so that the locking mechanism may comprise all other, known from the prior art transmission elements for moving a bolt. In particular, there may be a connection to a handle which has a nut is taken, so that upon rotation of the nut by the handle, a lever member can be pivoted, with which the bolt can also be moved between the open position and the closed position. Such a handle is also referred to as Daumendreheinheit and used to move a bolt from the inside of a door of a building or a room alternatively to an operation of the lock by the lock cylinder with a key.

In addition to the execution of the lock as a sliding bolt lock, this can also be designed as a pivot bolt lock, which also has a part of a locking mechanism, which is the present design of the receiving unit with the recorded transmission element and with the transmission element.

It is also advantageous that a toothed rack section and the lever element, a toothed segment is arranged to form the toothing on the transmission element, wherein the linear support in the receiving unit preferably at a helix angle of 10 ° to 80 ° relative to the direction of movement of the bolt, to the transmission element obliquely respectively. In addition to an advantageous space savings to reduce the dimensions of such a sliding bolt lock an arrangement of the linear recording with a helix angle of 10 ° to 80 ° relative to the direction of movement of the bolt also advantageous because at obliquely moved transmission element accessibility is further complicated by an intrusion tool acting from outside , If the transmission element moved parallel to the bolt, a manipulation of the position of the locking member and in particular a transfer of the locking member is facilitated in the release position. However, a manipulation of the locking member in position is almost impossible, provided that the transmission element is inclined in the linear recording, and thus direct access from the opening of the Stulpes is prevented in the linear recording.

According to a further advantageous embodiment, a driving pin is arranged on the lever element, wherein the bolt may comprise a guide slot, in which the driving pin is guided. The leadership of the driving pin within the guide slot can be made such that during a pivotal movement of the lever member about a pivot axis movement of the bolt is made possible from the closed position to the open position.

Further, the receiving unit may be formed in two parts, wherein the arrangement formed from the transmission element and / or the transmission element may be sandwiched between a first part and a complementary to this executed second part of the receiving unit. The transmission element may be present twice within the receiving unit, wherein each of the two transmission elements has its own driver, which are positioned angularly offset between the two transmission elements. Consequently, upon rotation of the lock cylinder and coincident rotation of the transmission member, the position of engagement of the first follower may differ from the rotational position of the lock cylinder upon engagement of the second follower with the transmission member. This results in the advantage that when deducting a key from the lock cylinder, neither of the two drivers can cooperate with the transmission element. Consequently, an interaction with the transmission element can not take place by the introduction of force into the latch and a linear movement of the gear unit that can be generated with it.

A further improvement in the interaction between the driver and the locking member results from a driver geometry within the locking member, which is arranged in the direction of the driver of the transmission element. The driver can engage in the driver geometry, such that the movement of the transmission element by force from the driver to the driver geometry and force transmission takes place on the locking member recording. As a result, the driver comes into contact only with the driver geometry within the locking member, wherein the driver geometry can be adapted to the geometry of the driver.

Figur 1

ein Ausführungsbeispiel eines als Schubriegelschloss ausgeführtes Schloss mit einer Schließmechanik und einem Sperrglied zur Sicherheitssperrung der Bewegung der Schließmechanik,

Figur 2a

eine perspektivische Ansicht eines Ausführungsbeispiels einer Aufnahmeeinheit mit einem Übertragungselement und einem Getriebeelement, in dem ein Sperrglied aufgenommen ist und eine Sperrposition einnimmt,

Figur 2b

eine perspektivische Ansicht der Aufnahmeeinheit mit dem Sperrglied, das in einer Rastnut eingerastet gezeigt ist,

Figur 2c

eine perspektivische Ansicht der Aufnahmeeinheit mit einem Übertragungselement und einem Getriebeelement, wobei ein Sperrglied in einer Freigabestellung zur Freigabe des Getriebeelementes gezeigt ist,

Figur 3

eine perspektivische Ansicht des Sperrgliedes mit einem Sperrvorsprung sowie einer Mitnehmergeometrie,

Figur 4

eine weitere perspektivische Ansicht einer Aufnahmeeinheit sowie eines Sperrgliedes, das über einen Sperrvorsprung in einer Rastnut eingerastet gezeigt ist und

Figur 5

eine perspektivische Ansicht eines Schlosses mit einem ersten Teil einer Aufnahmeeinheit sowie mit einem zweiten Teil einer Aufnahmeeinheit in einem demontierten Zustand.

Further, measures improving the invention will be described in more detail below together with the description of a preferred embodiment of the invention with reference to FIGS. It shows:

FIG. 1

An embodiment of designed as a sliding bolt lock lock with a locking mechanism and a locking member for locking the security of the movement of the locking mechanism,

FIG. 2a

a perspective view of an embodiment of a receiving unit with a transmission element and a transmission element in which a locking member is received and assumes a locking position,

FIG. 2b

a perspective view of the receiving unit with the locking member which is shown engaged in a locking groove,

Figure 2c

a perspective view of the receiving unit with a transmission element and a transmission element, wherein a locking member is shown in a release position for releasing the transmission element,

FIG. 3

a perspective view of the locking member with a locking projection and a driver geometry,

FIG. 4

a further perspective view of a receiving unit and a locking member which is shown engaged via a locking projection in a locking groove and

FIG. 5

a perspective view of a lock with a first part of a receiving unit and with a second part of a receiving unit in a disassembled state.

This in FIG. 1 Lock 1 shown forms an embodiment of a lock 1 according to the present invention and is designed as a sliding bolt lock 1. The lock 1 has a lock housing 2, wherein an upper-side cover is removed to represent the locking mechanism. This comprises a bolt 3, which is shown in a protruding from the lock housing 2 position, whereby the closed position of the bolt 3 is reproduced.

The locking mechanism has a plurality of received within the lock housing 2 components, with some of the components are received separately by a receiving unit 8 'to form an individually manageable and compact subunit of the locking mechanism. The receiving unit is formed by two parts, wherein the receiving unit is shown in a disassembled state, so that only a second, lower part 8 'can be seen.

Within the receiving unit 8 ', a transmission element 4, 4' is shown, which is also made of several parts, in the present view, both parts are shown. The transmission element 4, 4 'has a centrally existing transmission geometry 20, which forms a cross, and serves to receive a driver part of a lock cylinder, which can engage in the transfer geometry 20. If the lock cylinder is rotated by an inserted key in rotary motion, this rotational movement is caused by the driver part of Locking cylinder transmitted by the transfer geometry 20 on the transmission element 4, 4 ', so that this also performs a rotational movement within the receiving unit 8'.

According to the embodiment of the lock 1 takes place an interaction between the transmission element 4, 4 'and a transmission element 5, which is linearly guided within the receiving unit 8' is added. The direction of movement of the transmission element 5 takes place relative to the direction of movement of the bolt 3 at a helix angle, whereby the advantage is achieved that the accessibility of the interaction region between the transmission element 4, 4 'and the transmission element 5 through the opening 21 through which the bolt 3 through the lock housing 2 passes, is difficult.

In the interaction region between the transmission element 4, 4 'and the transmission element 5, a locking member 6 is arranged. The locking member 6 serves to lock the security of the movement of the transmission element 5, wherein the arrangement of the locking member 6 according to the invention is provided such that only by the interaction between the transmission element 4, 4 'and the transmission element 5 at least one release of the locking member 6 is enabled to a To provide release of the movement of the transmission element 5, by which the latch 3 can be transferred from the closed position to the open position. A more detailed representation of the interaction between the transmission element 4, 4 'and the transmission element 5 is in the Figures 2a, 2b and 2c shown in more detail.

FIG. 2a shows a first part of the receiving unit 8, in which a part of the transmission element 4 is shown, wherein further the transmission element 5 is shown, which is guided in a linear support 5a in the form of a guide groove 5a within the receiving unit 8. The interaction between the transmission element 4 and the transmission element 5 takes place via a driver 7, which is not directly in the situation shown with the transmission element 5 in interaction.

Within the transmission element 5, the locking member 6 is movably received, wherein the movement guidance of the locking member 6 is made possible within the transmission element 5 by a locking member receptacle 10. The direction of movement of the locking member 6 is perpendicular to the direction of movement of the transmission element 5, which is predetermined by the guide groove 5a. If the transmission element 4 is rotated in the counterclockwise direction, the driver 7 runs along a circular path. In this case, the driver 7 dips into the locking member receptacle 10 of the transmission element 5, and comes into contact with the locking member 6. In the position shown, the locking member 6 is in a blocking position, wherein only by pushing the driver 7 in the direction of the guidance of the locking member receiving 10 for guiding the locking member 6, a release of the locking member 6 takes place. The blocking of the locking member 6 to prevent the movement of the transmission element 5 within the guide groove 5a is based FIG. 2b described in more detail below.

FIG. 2b shows a further perspective view of the first part of the receiving unit 8, in which the transmission element 4 is rotatably received. Further, the locking member 6 is shown, wherein the blocking effect of the locking member 6 by interaction with a locking geometry 9 within the receiving unit 8 is clear by the transmission element 5, not shown. The locking groove 9 forms a blocking geometry into which a partial region of the locking member 6 protrudes. The locking groove 9 has a finite length, which is referred to below as the freewheeling length. By rotation of the transmission element 4, the driver 7 is set in motion and pushes the locking member 6 in a direction perpendicular to the course of the locking groove 9. This causes the locking member 6 out of the locking groove 9 and can be moved over the entire length of the guide groove 5a. However, if the locking member 6 in the locking groove 9 - as shown - engaged, is also limits the movement of the transmission element 5 on the freewheeling length of the locking groove 9. As a result, by the limited movement of the transmission element 5, the bolt 3 can not be transferred from the closed position to the open position.

In Figure 2c the release position II of the locking member 6 is shown, so that the transmission element 5 can move completely within the guide groove 5a of the receiving unit 8. The arranged on the transmission element 4 driver 7 presses the locking member 6 in the locking member receptacle 10 down, at the same time the transmission element 5 is moved. A continuation of the rotational movement of the transmission element 4 in the counterclockwise direction causes the driver 7 partially back in the locking member receptacle 10, but the locking member 6 remains in the release position II. If the transmission element 4 is rotated back in the clockwise direction, the above-described mode of operation of the transfer of the locking member 6 from the locking position I to the release position II is carried out in reverse order. Consequently, the locking member is lifted out of the locking groove 9 by the driver.

FIG. 3 shows a perspective view of the locking member 6. This has a driver geometry 19, in which the driver 7 can engage. If the blocking member 6 is guided within the locking member receptacle 10, the catch 7 only comes into contact with the catch geometry 19. A power transmission between the driver 7 and the transmission element 5 thus takes place only via the locking member 6 itself. Further, the locking member 6 has a locking projection 12 for locking in the locking groove. 9

FIG. 4 shows a further perspective view of the first part of the receiving unit 8, in which the transmission element 4 is received, wherein further the locking member 6 is shown, and wherein the locking projection 12 of the locking member 6 is shown locked in the locking groove 9. In order to hold the locking member 6 in the locked position, a spring element 11 is provided, which biases the locking member 6. If a rotational movement of the transmission element 4 takes place within the rotary receptacle 4 according to the rotary arrow shown, then the driver 7 presses the blocking member 6 against the bias of the spring element 11 into the locking member receptacle 10 of the transmission element 5. In this case, the locking projection 12 is lifted out of the locking groove 9 with simultaneous longitudinal movement of the locking member 6 along the guide groove 5a. The locking groove 9 is inserted in the groove wall 5b of the guide groove 5 and forms a step-like step to the plane surface 8a, on which the locking member 6 can slide with a body side surface.

FIG. 5 shows a view of a lock 1 with a locking mechanism, wherein both a first part 8 and a second part 8 'of the receiving unit is shown in a disassembled state. As shown, the transmission element 4 'is received in the second part of the receiving unit 8'. Further, the transmission element 5 is located with the captured in this locking member 6 on the second part 8 'of the receiving unit. The first part 8 of the receiving unit has the plane surface 8a, the guide groove 5a and the locking groove 9 introduced between the plane surface 8a and the guide groove 5a.

Furthermore, the rotary receptacle 4a for receiving the transmission element 4 'is shown. If the transmission element 4 'is set in rotary motion, the transmission element 5 executes a linear movement at a helix angle. The gear member 5 has a rack portion 14 which is meshingly engaged with a sector gear 15, the sector gear 15 being mounted on a lever member 13. By the engagement of the rack portion 14 in the sector gear 15, the lever member 13 is pivoted about a pivot axis 18, wherein at a lever arm end a driving pin 16 is attached. This leads due to the pivotal movement of the lever member 13 from a rotational movement about the pivot axis 18. The driving pin 16 is guided in a guide slot 17, which is introduced into the bolt 3. Due to the pivoting movement of the driving pin 16, the bolt 3 is moved linearly between the opening position and the closing position. Consequently, by a simple rotational movement of the transmission element 4 ', a linear movement of the bolt 3 can be caused, which is lockable by the locking member 6.

The invention is not limited in its execution to the above-mentioned preferred embodiment. Rather, a number of variants is conceivable, which makes use of the illustrated solution even with fundamentally different types of use. All of the claims, description or drawings resulting features and / or advantages including design details, spatial arrangements and method steps may be essential to the invention both in itself and in a variety of combinations.

LIST OF REFERENCE NUMBERS

1

lock

2

lock housing

3

bars

4

transmission element

4 '

transmission element

4a

rotary support

5

gear element

5a

Linear recording / guide groove

5b

groove wall

6

locking member

7

takeaway

8th

Recording unit, first part

8th'

Recording unit, second part

8a

plane surface

9

Locking geometry / locking groove

10

Detent receiving

11

spring element

12

locking projection

13

lever member

14

Rack section

15

toothed segment

16

driving pins

17

guide link

18

swivel axis

19

Mitnehmergeometrie

20

transmission geometry

21

opening

I

lock position

II

release position

Claims (15)

Lock (1) for a door or the like, in particular sliding bolt lock (1), with a lock housing (2) in which at least one locking mechanism with a bolt (3) is received, wherein the bolt (3) is movable to a closed position, in the latch (3) protruding from the lock housing (2) to close the door, and wherein the latch (3) is movable to an open position in which the latch (3) is moved back into the lock housing (2) to open the door in that the locking mechanism further comprises at least one transmission element (4, 4 ') rotatably received within the lock housing (2) and adapted to interact with a transmission element (5), the interlocking effecting the locking (3) between Closed position and the opening position is movable,
characterized in that
at least one locking member (6) for locking the movement of the transmission element (5) is provided and arranged such that by the interaction between the transmission element (4, 4 ') and the transmission element (5) at least one unlocking of the locking member (6) is made possible to provide a release of the movement of the transmission element (5), by which the latch (3) from the closed position to the open position and vice versa can be transferred. Lock (1) according to claim 1, characterized in that the locking member (6) in the transmission element (5) is received and between a locking position (I) and a release position (II) is movable. Lock (1) according to claim 1 or 2, characterized in that the transmission element (4, 4 ') has a driver (7) which, upon rotation of the transmission element (4, 4'), interacts with the transmission element (5) in that the blocking member (6) can be transferred from the blocking position (I) into the release position (II). Lock (1) according to one of claims 1 to 3, characterized in that a receiving unit (8, 8 ') for receiving at least the transmission element (4, 4') and the transmission element (5) is provided, wherein the transmission element (4, 4 ') is rotatably received in a rotary receptacle (4a) of the receiving unit (8, 8') and the gear element (5) linearly movable in a linear receptacle (5a) of the receiving unit (8, 8 '), wherein the mobility of the transmission element (5 ) is present in particular relative to the bolt (3). Lock (1) according to claim 4, characterized in that the linear receiving means (5a) has a blocking geometry (9) with which the blocking member (6) cooperates in the blocking position (I) in a blocking manner. Lock (1) according to claim 5, characterized in that the linear support (5a) as a guide groove (5a) in the receiving unit (8, 8 ') with at least one groove wall (5b) is executed, wherein the locking geometry (9) as a locking groove (9) in an edge of the groove wall (5b) is executed and over a length has a freewheel which is determined such that the locking member (6) at least over a part of the path of the transmission element (5) in the locking groove (9) can. Lock (1) according to one of the preceding claims, characterized in that the gear element (5) has a pocket-like locking member receptacle (10) for receiving the locking member (6), wherein the interaction of the transmission element (4, 4 ') with the transmission element (5 ) comprises an engagement of the driver (7) in the locking member receptacle (10). Lock (1) according to claim 7, characterized in that the driver (7) upon rotation of the transmission element (4, 4 ') for entrainment of the transmission element (5) in the locking member receptacle (10) is immersed, such that with immersion of the driver ( 7) in the locking member receptacle (10) the locking member (6) by the driver (7) from the locking position (I) in the release position (II) can be transferred. Lock (1) according to claim 7 or 8, characterized in that a spring element (11) is provided which biases the blocking member (6) in the blocking position (I) so that the transfer of the locking member (6) from the locking position (I) in the release position (II) by the driver (7) against the spring force of the spring element (11). Lock (1) according to one of the preceding claims, characterized in that the locking member (6) has a locking projection (12) which extends into the locking groove (9), wherein the receiving unit (8, 8 ') has a plane surface (8a ) on which the locking member (6) slides with at least one body side surface. Lock (1) according to any one of the preceding claims, characterized in that the operative connection between the bolt (3) and the transmission element (5) comprises a lever member (13), wherein the transmission of the linear movement of the transmission element (5) on the lever member (13 ) comprises a toothing, and wherein the lock (1) is designed in particular as a sliding bolt lock (1) and the movement of the bolt (3) is linear. Lock (1) according to claim 11, characterized in that in order to form the toothing on the gear element (5) a toothed rack section (14) and on the lever element (13) a toothed segment (15) is arranged, wherein the linear receiving means (5a) in the receiving unit (5a). 8, 8 ') preferably at a helix angle of 10 ° to 80 ° relative to the direction of movement of the bolt (3) extends to guide the transmission element (5) obliquely. Lock (1) according to claim 11 or 12, characterized in that the lever element (13) a driving pin (16) is arranged and wherein the bolt (3) comprises a guide slot (17) in which the driving pin (16) is guided, such that during a pivoting movement of the lever element (13) about a pivot axis (18) a movement of the bolt (3) from the closed position to the open position is made possible. Lock (1) according to one of claims 4 to 13, characterized in that the receiving unit (8, 8 ') is formed in two parts and the arrangement of the transmission element (4, 4') and / or the transmission element (5) sandwiched between a first part (8) and a second part (8 ') of the receiving unit (8, 8') is received. Lock (1) according to any one of the preceding claims, characterized in that the locking member (6) facing one towards the entrainment means (7) Mitnehmergeometrie (19) into which the entrainment means (7) engages in such a way that the movement of the transmission element (5) by introduction of force from the driver (7) on the driver geometry (19) and force transmission to the locking member receptacle (10).

Images