DE102018119849A1 - locking system - Google Patents

Abstract

The invention relates to a locking system with a locking device (1), which has a locking element (2), a locking housing (3) receiving the locking element (2), an electric drive (8) for moving the locking element (2) back and forth between one Has locking position (V) and an unlocking position (E) and a control device (20) controlling the electric drive (8), the closure (1) being designed as a locking module (100) and at least one further system module (200) being provided, which can be connected to the locking module (100).

Description

The present invention relates to a locking system with a lock, which has a locking element, a locking housing receiving the locking element and an electric drive for moving the locking element back and forth between a locking position and an unlocking position.

Such locking systems have long been used in many areas of technology, for example for closing flaps, doors, hatches or similar elements, with electrically operated locking systems having become increasingly important in recent years.

Such electrically operated locking systems comprise a lock which usually has a locking element which can be moved back and forth between a locking position and an unlocking position. This locking element is movably received within a locking housing of the closure, in which, in addition to the locking element, the electrical drive that is used to move the locking element is usually also accommodated.

With such locking systems, it has proven to be disadvantageous that they are often only suitable for a specific application.

If, in a specific application, for example, the locking system is to be used to control access via fingerprint recognition, a locking system must be used in which a fingerprint reader is provided. However, such a closure cannot be used in other applications, such as access control using NFC-readable access cards or the like Label smartphone or similar. In this respect, there are a large number of use cases, some of which differ considerably from one another, and it can be assumed that this will even grow in the future.

The problem arises, therefore, that a wide variety of locking systems must always be developed for a wide variety of applications, which is associated with some effort in practice.

The object of the present invention is therefore to provide a closure system which can be adapted to different requirements with less effort.

In a locking system of the type mentioned at the outset, it is proposed to solve this problem that the lock is designed as a locking module and at least one further system module is provided which can be connected to the locking module.

Thanks to the modular design of the locking system, it can be adapted to different requirements with less effort. Because the lock, designed as a locking module, can easily be used in practice for several applications. The respective requirement-specific system components of the locking system can be accommodated in the system module. The requirement-specific system module can be modularly connected to the locking module, so that very different locking systems can be constructed with one and the same locking module. For this, it is not necessary to develop a completely new locking system, but only a correspondingly adapted system module, to store, etc.

The system module advantageously interacts functionally with the drive and / or a control device of the drive, as a result of which the locking system can be adapted to a large number of different applications.

A further advantage is an embodiment in which the system module is a storage module for providing electrical energy for operating the closure and / or a reading and / or receiving module, in particular a fingerprint reader, an NFC transmitter, an NFC receiver, a Bluetooth Transmitter, a Bluetooth receiver and / or a card reader. The locking system can be supplied with energy independently of the power grid by means of a storage module. A reading and / or receiving module can enable a desired form of access control in a simple manner.

In an advantageous embodiment, the system module designed as a storage module has at least one storage element, in particular a capacitor, an accumulator or a battery, for supplying the drive and / or the control device with electrical energy. A plurality of interconnected memory elements are preferably provided.

Preferably, at least two system modules interacting with the latch module can optionally be connected to one another and / or to the latch module in the manner of a modular system. The one to be connected to the latch module System module can be selected from the at least two system modules according to existing requirements. Alternatively or additionally, several system modules can be connected in series and / or in parallel with the latch module and / or with one another, which means that even more applications can be covered with fewer types of different system modules. The individual system modules to be connected can be selected from a large number of different system modules designed to meet various requirements in the manner of a prefabricated modular system for common applications. For example, a system module with a battery can be connected to another system module with a fingerprint reader and both can be connected together with the latch module.

In a constructive embodiment it is proposed that the system module can be connected on the edge side to the latch housing of the latch module. A structurally flat locking system can be achieved by connecting the system module to the transom housing at the edge. In particular by an end connection of the system module to the latch housing, i. H. With a short edge surface, a structurally narrow locking system can also be achieved. The locking module and the system module can be designed and connected to one another in such a way that there is a continuous contour of the locking system.

In an advantageous embodiment, the system module has a connection area and the latch module has a correspondingly designed connection area, via which the system module can be mechanically and / or electrically connected to the latch module. The two connection areas can act as mechanical and / or electrical interfaces, via which the modules can be combined in a simple manner to form a functional overall system.

An embodiment that is advantageous in terms of connection technology provides that the connection areas have at least one locking element and at least one counter-locking structure, via which the system module can be connected to the locking module in a form-fitting manner.

In this context, it is further proposed that the locking element is designed in the manner of a plug connector and / or snap connector. In this way, the connection can be made in a few simple steps and without additional connecting elements or tools.

A variant that is advantageous in terms of production engineering provides that the counter-locking structure is formed by a housing connecting element. The housing of the modules can be constructed in several parts, in particular in two parts with an upper and a lower shell, and the individual parts can be connected to one another via housing connecting elements. The use of such a housing connecting element as a counter-locking structure brings with it design and manufacturing advantages, since no separate counter-locking structure has to be provided. The structure is simple.

In this context, it is also advantageous if the housing connecting element is designed according to a threaded bush. The threaded bushing can have a cylindrical geometry and cooperate with the locking element on the outer circumference. A screw bolt for connecting the housing parts can be screwed into the inside of the threaded bushing in a conventional manner.

Two counter-locking structures are advantageously provided, which include a connection opening into which two locking elements can be inserted and / or latched. This results in a reliable locking in the manner of a two-point locking.

It can also be provided that the counter-locking structure is formed by an insertion opening.

In a further development of the invention, it is further proposed that the connection areas each have at least one electrical plug element and at least one electrical socket, via which the system module can be electrically connected to the locking module. In this way, energy can be transferred between the two modules and / or control signals can be transmitted. Alternatively, the transmission of energy and / or control signals can also take place without an electrical plug element in the connection area. The system module can be connected to the locking module via a connecting conductor, such as a cable, a cable harness or a flexible printed circuit board. The connecting conductor can extend from the interior of the locking module into the interior of the system module. In particular, the connecting conductor can be connected to a board of the system module, a board of the system module and / or the control device.

With regard to a reliable mechanical connection, it is also advantageous if the electrical plug element and the electrical socket can be connected to one another in a form-fitting manner. This positive connection can be the only one mechanical connection or an additional connection between the modules.

A particularly advantageous embodiment of the invention provides that the locking element is arranged such that it can be repositioned between at least two locking orientations in the locking housing. In this way, the latch module can also be adapted to different requirements. The repositionable arrangement of the locking element in the locking housing makes it possible to change the locking orientation of the locking element in accordance with the requirements of the desired application.

It is advantageous if the bolt orientations differ by the bolt positions and / or the bolt directions of the bolt element. As a result, a large number of different latch orientations can be achieved in one and the same latch module, which can hereby be used for a large number of mechanically different applications. In the case of hook and snap locks in particular, the functionality of the lock can be adapted to the respective application by changing the locking position. For example, it can be determined in which direction the snap effect should occur with a snap lock.

In this context, it has proven to be advantageous if the locking element can be repositioned between two locking layers while maintaining a locking direction. The locking element can be repositioned between the two locking layers by turning. In the case of a snap lock, the one locking position can be used, for example, for an inward opening door and the other locking position for an outward opening door. A change in the bolt direction is not necessary for this.

It is further advantageous if two locking directions are aligned essentially transversely to one another. By means of two locking directions aligned transversely to one another, the locking module can be used for optional locking via two sides of the locking housing arranged transversely to one another. With the same housing orientation, the closure can therefore be used for locking along two transverse locking directions.

It is also advantageous if each bolt direction is assigned an optionally usable bolt opening in the bolt housing. Through the bolt opening, the bolt element can be transferred from the bolt housing into the locking position along the bolt direction. A bolt opening that is not used in the desired bolt orientation can be closed by a cover element to protect the interior of the bolt housing from contamination. A separate bolt opening can be assigned to each bolt direction. The separate latch openings can be arranged on different side faces, in particular edge side faces, of the latch housing. Alternatively, the bolt opening can also correspond to part of a larger bolt opening, the part used in a specific bolt direction being open and the remaining parts of the larger bolt opening being closable by a cover element. In this case, the bolt opening can extend over a plurality of side surfaces, in particular edge side surfaces, of the bolt housing, in particular over two side surfaces.

In an advantageous manner, the locking element can be moved axially back and forth between the locking position and the unlocking position or can be pivoted back and forth about an axis.

According to a constructive embodiment, it is proposed that the latch housing be designed in such a way that it can optionally be mounted on two opposite mounting sides. The locking module, which can be mounted on two opposing mounting sides, can be turned over at the desired mounting position depending on the application. This allows further locking directions to be covered without the locking element having to be repositioned within the locking housing for this purpose. For a lock with a locking element that can be repositioned between two locking directions in the locking housing, for example, three locking directions relative to the door leaf can optionally be adopted.

The locking element is advantageously designed in the manner of a latch, in particular a spring-loaded latch. The trap can be designed in the manner of an inclined trap with a beveled end face for use in a snap lock. The trap can alternatively also be designed as a hook trap, lever trap and / or rotary trap which can be pivoted back and forth about an axis. The spring-loaded latch can be biased towards the locking position. By pretensioning, the latch can be designed to be self-locking and, in particular, snap-in in a simple manner.

In a further constructive embodiment, the locking element has at least one drive element for connecting the locking element to at least one drive. The connection can be designed in the manner of a coupling. Preferably, several, in particular two or three, alternatively usable drives for moving the locking element can be connected to the drive element his. A first drive can be designed in the manner of a main drive, while the other drives can be designed in the manner of emergency and / or auxiliary drives, which can be used, for example, to unlock the lock during a power failure or a dangerous situation. To connect the locking element to the at least one drive, the drive element can have a cam which engages in a correspondingly shaped recess in the locking element. The drive element can be rotatably mounted and connected to the locking element in such a way that a rotational movement of the drive element is converted into an axial movement of the locking element.

In this context, it has proven to be advantageous if the at least one drive element forms a repositionable locking unit with the locking element. A locking unit consisting of locking element and a drive element can enable a particularly simple repositioning between different locking orientations in the locking housing.

According to one embodiment of the invention, the locking element is a locking slide and the drive element is a cam, the cam of which rests on the locking slide. The cam resting on the locking slide can move the locking slide in a simple manner when the cam disk is rotated. The locking slide preferably has an elongated hole-shaped passage through which the axis of the cam disk runs from one side of the locking element to the other side of the locking element. The passage can allow the bolt slide to move even when the cam is stationary. For this purpose, the passage can be dimensioned in such a way that a locking slide designed in the manner of a snap catch does not collide with the axis of the cam disk when it is snapped shut.

A drive element is preferably arranged on both sides of the locking element. The drive elements can each have at least one, preferably at least two coupling elements for coupling to the drive. The coupling element can be designed in the manner of an engagement recess and / or an elongated hole. Each bolt orientation, in particular each bolt direction and / or each bolt position, can be assigned its own coupling element. The two drive elements can be designed as identical parts. The two drive elements arranged on opposite sides of the locking element can be part of the locking unit.

The drive element is advantageously coupled to a drive via an axially movable coupling member. The coupling element can be coupled to the drive element, in particular to at least one coupling element of the drive element. The coupling member can be moved axially to move the locking element by several drives, in particular two drives. Depending on the respective bolt orientation, the coupling element can be coupled to a coupling element of the drive element. The coupling between the coupling member and the drive element can be done releasably, which enables a simple repositioning of the locking unit. For connection to the drives, the coupling member can have a plurality of coupling sections, in particular axially and / or transversely offset from one another.

In this context, it has proven to be advantageous if the coupling member can be moved with a control cam via a control cam element. Via the control curve of the control curve element, the coupling element can be moved in a reproducible manner and following a predetermined movement sequence. The control cam element can be designed to save space in the manner of a control screw.

The locking element can advantageously be moved back and forth between the locking position and the unlocking position by means of at least two drives, in particular three drives. Reliable operation of the lock with redundant drives can be ensured by the at least two drives. Alternatively, the drives can be drives using different drive mechanisms. Safe operation of the closure, for example during a power failure or a fire, can be ensured, in particular, by manually operated drives in the manner of emergency and / or auxiliary drives. The drives can be designed for local and / or remote operation of the locking element.

In this context, it has proven to be advantageous if the drives comprise an electric drive with an electric motor, a drive with an axially movable pulling element and / or a drive with an attachable manual actuation device. The electric drive can be designed in the manner of a main drive. In addition to the electric motor, the electric drive can have a cam element driven by the electric motor. The electric motor can be coupled to the control cam element via a transmission. The axially movable tension element can be designed to be spring-loaded via a prestressing section. For actuation by a flexible pulling device in the manner of a Bowden cable, the pulling element can have an actuating claw. The manual actuator can be in the manner of a Key, in particular a polygonal key, interact with a coupling element. The coupling element can be arranged coaxially on a drive element and / or be accessible from both sides of the bolt from the outside of the transom housing. The accessibility of the coupling element can be realized through passage openings of the bolt housing.

In a further embodiment of the invention, the closure has a drive sensor for determining the position of a drive and / or a locking sensor for determining the position of the locking element. The sensors can each be an optical sensor or one that can be physically actuated in the manner of a position switch. The sensors can be designed in the manner of position sensors, in particular with two detectable end positions. The bolt sensor can be used to determine whether the bolt element is in the locking and / or unlocking position.

It is further advantageous if at least one drive and / or the locking element has a position transmitter. A position transmitter is preferably assigned to each end position, in particular the locking position and the unlocking position of the locking element. The position transmitter can be designed in the manner of a projection of the locking element, the motor and / or the control cam element. On the locking element, the position transmitter can extend transversely to the direction of movement of the locking element, in particular transversely to at least one locking direction. A position transmitter can preferably be arranged on both sides of the locking element.

The latch housing particularly preferably has at least two sensor receptacles for, in particular, optionally receiving the latch sensor. Each sensor receptacle can be assigned a bolt orientation, in particular a bolt direction. When repositioning the bolt element, the bolt sensor can be repositioned in the sensor receptacle assigned to the respective bolt orientation. The repositioning of the bolt sensor can be carried out separately from the repositioning of the bolt element.

According to a structural embodiment, it is proposed that the closure have a control device for controlling the electric drive. The control device can comprise microelectronics, an actuator, an access authorization control, a receiver and / or a transmitter, in particular for RFID and / or NFC signals. The access authorization control can limit the function of the locking element in terms of time and / or person-related. The access authorization control can interact with the actuator of the electric motor and / or the microelectronics. The control device is preferably accommodated by the latch housing.

• 1 a) bis (e) einen über eine erste Montageseite montierten, als Riegelmodul ausgebildeten Verschluss mit einem Riegelelement in vier Riegelorientierungen sowie einen über eine zweite Montageseite montierten Verschluss,
• 2(a) bis (h) eine weitere Ausführungsform des Verschlusses mit unterschiedlichen Riegelelementen in mehreren Riegelorientierungen,
• 3(a) bis (d) weitere Verschlüsse mit unterschiedlichen Riegelelementen in einer Entriegelungsstellung und einer Verriegelungsstellung,
• 4 eine Explosionsdarstellung einer ersten Ausführungsform des Verschlusses,
• 5 eine Explosionsdarstellung einer zweiten Ausführungsform des Verschlusses mit unterschiedlichen Riegelelementen,
• 6(a) und (b) einen Verschluss mit einem in unterschiedlichen Sensoraufnahmen angeordneten Riegelsensor,
• 7(a) bis (d) einen Verschluss in unterschiedlichen Betätigungsstellungen ohne einen Teil des Riegelgehäuses,
• 8(a) bis (c) Schnittdarstellungen des Verschlusses aus 7 in dessen Entriegelungsstellung und dessen Verriegelungsstellung,
• 9(a) bis (c) ein modulares Verschlusssystem mit unterschiedlich ausgestalteten Riegelmodulen,
• 10(a) bis (c) ein Riegelmodul und ein Systemmodul mit unterschiedlichen Verriegelungselementen,
• 11 eine teildemontierte Darstellung des Riegelmoduls und des Systemmoduls gemäß 10(c),
• 12 eine Explosionsdarstellung des Systemmoduls aus 11 und
• 13 eine Darstellung ähnlich der Darstellung in 6(a) für ein Riegelmodul und ein Systemmodul.

Further details and advantages of a closure system according to the invention will be explained below using the exemplary embodiments of the invention shown schematically in the figures. In it show:

• 1 a) to (e) a closure mounted as a locking module and having a locking element in four locking orientations mounted over a first mounting side and a locking mechanism mounted over a second mounting side,
• 2 (a) to (h) a further embodiment of the closure with different locking elements in several locking orientations,
• 3 (a) to (d) further closures with different locking elements in an unlocking position and a locking position,
• 4 an exploded view of a first embodiment of the closure,
• 5 an exploded view of a second embodiment of the closure with different locking elements,
• 6 (a) and (b) a closure with a locking sensor arranged in different sensor receptacles,
• 7 (a) to (d) a closure in different actuation positions without part of the latch housing,
• 8 (a) to (c) sectional views of the closure 7 in its unlocked position and its locked position,
• 9 (a) to (c) a modular locking system with differently designed locking modules,
• 10 (a) to (c) a latch module and a system module with different locking elements,
• 11 a partially disassembled representation of the latch module and the system module according 10 (c) .
• 12 an exploded view of the system module 11 and
• 13 a representation similar to the representation in 6 (a) for a latch module and a system module.

Below is first a closure 1 and then went into a modular locking system in which such a closure 1 as a latch module 100 together with at least one other system module 200 is used.

In 1 is a closure 1 shown, which can be used in many areas of technology for closing doors, flaps, cupboards, etc.

The closure 1 demonstrates a in the embodiment 1 Locking element designed in the manner of a spring-loaded snap catch 2 on which is inside a box-shaped latch housing 3 to provide or to release a lock between a locked position V and an unlocked position e is arranged to move back and forth.

In the 1 (a) to 1 (e) is the locking element 2 in the locked position V in different bolt orientations within one and the same bolt housing 3 shown.

The locking element 2 takes in the locked position V one position each in the bolt housing 3 one in which it is with its latch section 2.1 from the bolt housing 3 protrudes. In this locked position V can the locking element 2 with the latch section 2.1 rest against a correspondingly designed counterpart, such as a lock holder, a groove, a bolt, a striking plate, a striker or a similar element and thereby provide the desired locking. The locking element can be used for unlocking 2 from the in 1 locking position shown V in an unlocked position e be transferred in which the bolt section 2.1 withdrawn inside the transom housing 3 located.

Depending on the application in which the closure 1 Different latch orientations of the latch element are to be used 2 relative to the bolt housing 3 possible. For example, if a door is to be locked on the left side, it is necessary that the locking element 2 over a left margin 3.7 from the bolt housing 3 can leak. If the locking is to take place over the upper edge of the closing element, the locking element must be 2 accordingly via an upper end face 3.8 from the bolt housing 3 can emerge or in a itself on this end face 3.8 extended locking position V let move.

In 1 is a series of different bolt orientations R1 . R2 . L1 . L2 shown as an example. The individual transom orientations differ in the transom positions L1 . L2 of the locking element 2 , like this in the 1 (a) and 1 (b) is shown. When transferring between these two bar layers L1 . L2 becomes the locking element 2 rotated about its longitudinal axis. At the in 1 shown and designed as an inclined latch element 2 these two tie layers differed L1 . L2 functional in that a snap of the closure designed as a snap closure 1 in 1 (a) and 1 (b) takes place along opposite directions of movement of the closing element. In the two bolt positions L1 . L2 is the same part of the transom housing 3 each have a different side of the locking element 2 facing.

Also in 1 (c) and 1 (d) is the locking element 3 in the two latch positions L1 . L2 shown. Compared to the bolt orientations in 1 (a) respectively. 1 (b) However, these bolt orientations differ in their bolt directions R1 . R2 ,

Along these bolt directions R1 . R2 can the locking element 2 opposite the bolt housing 3 between the unlocked position e and the locking position V be moved back and forth. The two bolt directions R1 . R2 are essentially transverse to each other.

The locking element 2 occurs in its locked position V along the bolt direction R1 from the edge 3.7 of the latch housing 3 out. Along the bolt direction R2 , which is essentially parallel to the longitudinal axis of the housing LA runs, the latch section occurs 2.1 of the locking element 2 from the front 3.8 of the latch housing 3 out. This way you can use the clasp 1 four bolt orientations relative to the bolt housing 3 can be achieved in which the locking element 2 in the latch position L1 along the bolt direction R1 , in the latch position L2 along the bolt direction R1 , in the latch position L1 along the bolt direction R2 or in the latch position L2 along the bolt direction R2 is oriented.

To this adaptability of the closure 1 The bolt housing shows how to further increase the number of different applications 3 two opposite mounting sides 3.3 . 3.4 on. About these assembly pages 3.3 . 3.4 can the clasp 1 can be installed optionally. This allows the locking element 2 a third latch direction R3 which is the bolt direction R1 is opposite. Different from the two bolt directions R1 . R2 becomes the locking element 2 however, this does not apply to the bolt housing 3 repositioned. Rather, the entire closure 1 for positioning along this third bolt direction R3 relative to the mounting position at which the closure 1 is mounted around its longitudinal axis LA rotates. This in 1 (e) shown third latch direction R3 is therefore by turning the closure 1 with a locking element 2 achieved, which is in the 1 (a) bolt orientation shown R1 . L1 relative to the bolt housing 3 located. During the in 1 (a) shown closure 1 on the mounting side 3.4 is mounted at the assembly position, the in 1 (e) shown closure 1 with along the bolt direction R3 aligned locking element 2 over the opposite mounting side 3.3 at the mounting position.

In the in 1 illustrated embodiment is each of the two locking directions R1 . R2 an optional bolt opening 4 . 5 assigned. Through these bolt openings 4 . 5 can the locking element 2 from the bolt housing 3 protrude. The bolt opening not used 4 . 5 is covered by a cover 21 locked. Penetration of dirt and contamination into the interior of the transom housing 3 is avoided.

In 2 are further closures 1 according to another design of the bolt housing 3 with differently designed locking elements 2 shown in several bolt orientations. The locking element 2 of in 2 (a) to 2 (c) The embodiment shown essentially corresponds to the locking element 2 of in 1 shown embodiment and is designed in the manner of a beveled inclined trap. The design difference to the transom housing 3 according to 1 is that the latch openings 4 . 5 Are part of a larger opening extending around a corner and by repositioning the substantially L-shaped cover element 21 the unused parts of the larger opening can be covered.

In 2 (d) to 2 (f) is a locking element which is also designed as an inclined latch 2 shown. In this case, the bevel runs in the direction of a short side of the locking element 2 , During the snap effect of the snap trap in 2 (a) to (c) by essentially transverse to the mounting sides 3.3 . 3.4 the closing element occurs, the locking element is suitable 2 the 2 (d) to (f) for snapping at substantially parallel to the mounting sides 3.3 . 3.4 closing movements.

In 2 (g) and 2 (h) is the locking element 2 designed like a sliding bar without a snap function.

3 shows two more closures 1 with the in 2 bolt housing shown 3 however other locking elements 2 , The locking element 2 in 3 (a) and 3 (b) is like a lever trap and in 3 (c) and 3 (d) trained like a hook trap. Unlike the locking elements described above 2 are the in 3 bolt elements shown 2 not between the locked position V and the unlocked position e moved axially back and forth, but around an axis A between the locked position V and the unlocked position e pivoted back and forth. This axial pivoting is due to the bolt openings which are connected throughout 4 . 5 allows. The cover element 21 is not used here. Also in 3 bolt elements shown 2 can in different transom orientations, especially in different transom positions L1 . L2 , in the latch housing 3 to be ordered. These closures can also be used 1 also on the opposite assembly side 3.3 . 3.4 assemble.

4 shows an exploded view of the in 1 shown closure 1 , based on which the internal structure of the closure 1 is explained in more detail.

It can be seen that the bolt housing 3 from two housing parts 01.03 . 3.2 is composed. Each of the housing parts 01.03 . 3.2 has part of the two latch openings 4 . 5 on.

The locking element 2 with that from the latch housing 3 bolt section movable out 2.1 is designed in the manner of a spring-loaded latch slide. That the latch section 2.1 opposite end of the locking element 2 has two recesses 2.4 on. In one of these recesses 2.4 becomes a biasing element designed as a spring 23 optional and depending on the bolt position L1 . L2 held. About its the locking element 2 the biasing element is supported on the opposite side 23 towards the inside of the transom housing 3 from. Through this pretensioning element 23 becomes the locking element 2 towards its locking position V biased.

A passage designed like an elongated hole 2.3 of the locking element 2 enables a shaft configured in the embodiment in the manner of a square 22 transverse to the direction of movement of the locking element 2 to step through it. The wave 22 connects two on both sides of the locking element 2 arranged drive elements 6 . 7 together. These drive elements 6 . 7 are each in the manner of a cam disc with a cam 6.3 . 7.3 educated. The cams 6.3 . 7.3 reach for the drive of the locking element 2 each in a recess 2.2 of the locking element 2 on. For actuating the locking element designed as a locking slide 2 the cams work 6.3 . 7.3 each with a drive surface 2.5 of the locking element 2 together. This is related below 8th described in more detail.

The passage designed like an elongated hole 2.3 allows the locking element 2 also without actuating one of the drive elements 6 . 7 to be moved when a door is closed and then driven by the force of the pretensioning element 23 snap in the closed position. When the door is closed, the beveled surface of the latch section 2.1 a force on the locking element 2 exercised which this against the biasing element 23 from the locked position V in the unlocked position e transferred. Because of the passage 2.3 can the locking element 2 towards the wave 22 be moved without the shaft 22 this movement interferes. The preload element 23 is tensioned in one direction and automatically relaxed in the other direction after the door has been closed. By relaxing the biasing element 23 becomes the locking element 2 automatically in the locking position V transferred. This will cause the closure to snap shut 1 in the manner of a snap lock.

The locking element 2 and the two drive elements 6 . 7 form together with the wave 22 a latch unit 11 which for repositioning the locking element 2 between different bolt orientations R1 . R2 . L1 . L2 can be repositioned as an assembly and functional unit. The latch unit 11 can be taken out of the latch housing as a whole 3 be removed and reinserted in a different latch orientation. Will the bolt direction R1 . R2 the latch unit 11 changed when repositioning, so is the biasing element 23 between different positions within the transom housing 3 repositioned to also in the new bolt orientation R1 . R2 . L1 . L2 the latch unit 11 a biasing force on the locking element 2 to be able to exercise. Will only the latch position L1 . L2 of the locking element 2 changed, so is a repositioning of the biasing element 23 not mandatory. In this case, the biasing element engages 23 only in the other, previously unused recess 2.4 of the locking element 2 one which is the biasing element 23 in the new latch position L1 . L2 holds.

The drive elements designed in the manner of an eccentric disc 6 . 7 serve to drive the locking element 2 and connect the locking element 2 in the illustrated embodiment, operatively coupled with a total of three drives 8th . 9 . 10 ,

The drive 10 has an attachable manual actuator 16 on, which in the manner of a polygonal key on an axially on the drive elements 6 . 7 arranged coupling element 17 can be plugged on. This coupling element 17 is from the outside of the housing through access openings 3.9 of the latch housing 3 accessible. A rotary motion of the actuator 16 through the access opening 3.9 on the coupling element 17 is plugged in, is transmitted via the coupling element 17 directly to the respective drive element 6 . 7 and from this over the cam 6.3 . 7.3 on the locking element 2 , This is done coaxially on the drive elements 6 . 7 arranged coupling element 17 also serves as an axial bearing for the shaft 22 interconnected drive elements 6 . 7 in the access openings 3.9 of the two housing parts 01.03 . 3.2 ,

For coupling to the two other drives 8th . 9 point the two drive elements 6 . 7 two coupling elements each 6.1 . 6.2 . 7.1 . 7.2 on. These coupling elements 6.1 . 6.2 . 7.1 . 7.2 are essentially offset by 90 degrees to each other on the respective drive element 6 . 7 arranged. This enables a coupling link 12 for coupling with the drives 8th . 9 in both bolt directions R1 . R2 via a coupling element 6.1 . 6.2 . 7.1 . 7.2 on one of the drive elements 6 . 7 to dock. Depending on the bolt position L1 . L2 the latch unit 11 follows the coupling of the coupling element 12 either via the drive element 6 or the drive element 7 , In this case, an engagement projection takes effect 12.1 of the coupling link 12 in one of the coupling elements designed as elongated holes 6.1 . 6.2 . 7.1 . 7.2 on.

The coupling link 12 is axially movable in the latch housing in the manner of a coupling rod 3 stored. At its engaging tab 12.1 the coupling member has opposite end region 12 two coupling sections 12.2 . 12.3 on. These coupling sections 12.2 . 12.3 are along and across the longitudinal axis of the coupling link 12 offset against each other. This gives the coupling link 12 essentially an L shape. The two coupling sections 12.2 . 12.3 couple the two drives 8th . 9 with the drive elements 6 . 7 and the locking element 2 , For actuating the locking element 2 becomes the coupling link 12 by one of the two drives 8th . 9 moved axially. The axial movement of the coupling link 12 is transferred via one of the coupling elements 6.1 . 6.2 . 7.1 . 7.2 engaging engagement tab 12.1 on the drive elements 6 . 7 and causes it to rotate about the axis A ,

Over the coupling section 12.3 is the drive 9 with the coupling link 12 coupled. This drive 9 has an axially movable tension element 15 on which by the biasing element 24 opposite the bolt housing 3 is spring loaded. For this is the biasing element 24 one-sided on a prestressing section 15.1 of the tension element 15 arranged. In this way, the tension element 15 towards the coupling link 12 biased. By an axial movement of the tension element 15 contrary to that of the biasing element 24 The pre-tensioning force is exerted via a coupling section 15.2 with the coupling section 12.3 of the coupling link 12 coupled tension element 15 a tensile force on the coupling link 12 out. Because of this axial movement of the tension element 15 becomes the locking element 2 via the coupling link 12 and one of the drive elements 6 . 7 in the unlocked position e transferred. The tension element 15 also has an operating claw 15.3 on which it is operated by a flexible pulling device in the manner of a Bowden cable. As long as the Bowden cable has an actuating force on the tension element 15 of the drive 9 exercises, remains on the drive elements 6 . 7 and the coupling link 12 with the drive 9 connected locking element 2 in its unlocked position e , Once the Bowden cable has no force on the tension element 15 exercises, the tension element 15 through the biasing element 24 moved back to its original position, so that the prestressed locking element 2 again its locking position V can take, the drive elements 6 . 7 and the coupling link 12 be moved back.

The coupling link 12 is over its coupling section 12.3 and the coupling section 15.2 so with the tension element 15 connected that only tensile forces from the tension element 15 on the coupling link 12 be transmitted. In contrast, thrust forces are not exerted by the tension element 15 on the coupling link 12 or the other way around. The coupling link 12 can be moved axially in this way without the pulling element 15 is moved axially, for example when the closure is actuated 1 via one of the other drives 8th . 10 he follows.

The closure 1 also has an electric drive 8th with an electric motor 13 on. The electric motor is controlled 13 via a control device 20 , which is designed in the manner of microelectronics and can include information about temporal and / or personal access restrictions and access authorization control.

Via a transmission 39 is the electric motor 13 with a cam element 14 connected. The gear 39 allows the electric motor to be stepped up or down 13 and in this way one of the speed of the electric motor 13 different speed of the cam element 14 , The control element 14 has a control curve 14.1 like a control screw. The control curve 14.1 couples via a coupling section 12.2 to the coupling link 12 on. By turning the cam element 14 practices the control curve 14.1 a thrust on the coupling section 12.2 out. This causes the coupling member to move axially 12 , whereby the locking element 2 from the locked position V in the unlocked position e can be transferred. Here, a rotary movement of the electric motor 13 about the transmission 39 on the cam element 14 transfer. This rotary movement of the cam element 14 is about the control curve 14.1 in an axial movement of the coupling member 12 changed, which in turn via the engagement projection 12.1 and a coupling element 6.1 . 6.2 . 7.1 . 7.2 a rotary motion of the over the shaft 22 interconnected drive elements 6 . 7 causes. About the cams 6.3 . 7.3 of the drive elements 6 . 7 this rotary movement becomes an axial movement of the locking element 2 converted, which in this way against the biasing force of the biasing element 23 from the locked position V in the unlocked position e is transferred.

On the cam element 14 are two position sensors designed in the manner of projections 36 . 37 below the control curve 14.1 arranged. This position encoder 36 . 37 can with a drive sensor designed as an optical sensor 18 interact. In those rotational positions of the cam element 14 which the position transmitter 36 . 37 are assigned, the respective position sensor intervenes 36 . 37 such in the drive sensor 18 that this is operated. The drive sensor 18 works with the position sensors 36 . 37 together like a limit switch. The first position encoder 36 is that rotational position of the cam element 14 assigned in which the control curve 14.1 no force on the coupling link 12 exercises so that the locking element 2 its locking position V can take unless it is by another drive 9 . 10 is operated. The second position encoder 37 is that rotational position of the cam element 14 assigned in which the coupling link 12 over the control curve 14.1 is moved axially the most, so that the locking element 2 about the drive 9 in the unlocked position e is transferable.

In 5 is an exploded view of the closure 1 with the in 2 and 3 latch housing shown 3 shown. The functionality of the components shown largely corresponds to the above in connection with 4 described components. The same reference numerals are therefore used for components having the same effect. Only the differences of this embodiment will be discussed below.

In 5 are several alternative locking elements that can be used 2 shown how to use the in 2 and 3 locking elements shown 2 correspond. The actuation of the locking elements 2a . 2 B . 2c takes place analogously to that in connection with 4 described locking element 2 , in which the locking element 2 along an axis between the locked position V and the unlocked position e , in which the locking element 2 in the bolt housing 3 moved in, is moved. The actuation of the locking element designed as a hook latch 2d and the locking element designed as a lever latch 2e takes place, however, by turning the locking element 2 around the axis A , The recesses are for this purpose 2.2 the locking elements 2e . 2d essentially complementary to the cams 6.3 . 7.3 of the drive elements 6 . 7 educated. A rotary movement of the drive elements 6 . 7 is translated into a rotary movement of the locking element in this way 2d . 2e around the axis A ,

As in 5 the bolt openings can be seen 4 . 5 continuously connected with each other and run between one end face 3.8 and an edge side 3.7 of the two housing parts 01.03 . 3.2 , The L-shaped cover element can be seen 21 , with which one of the latch openings is optionally available 4 . 5 concealable and the other bolt opening 4 . 5 can be released. For this purpose, the cover element 21 from the housing parts 01.03 . 3.2 in which it is inserted, detached and reinserted in a different orientation.

In this embodiment of the closure 1 is the coupling link 12 by a spring-like biasing element 25 towards the locking element 2 biased.

The locking element 2 facing end 3.8 of the latch housing 3 has a connection opening 29 on which by the insertable cover 28 can be locked. Through this connection opening 29 can electrical lines 27 to supply the motor 13 and / or the control device 20 on the cover element 28 past from inside the latch housing 3 be led out. On the engine 13 and the control device 20 opposite end of these lines 27 is a connector 26 provided over which the electrical lines 27 can be connected to other electrical devices and in particular a power supply.

In addition to the drive sensor 18 shows this version of the closure 1 a bolt sensor 19 on which with the control device 20 connected is. About this bolt sensor 19 can the position of the locking element 2 be determined. This is the bolt sensor 19 also designed as an optical sensor. Together with the locking element on both sides 2 arranged position sensors 38 the bolt sensor works 19 as a position sensor. The position transmitter 38 are in the manner of a projection of the locking element 2 trained and the locking position V of the locking element 2 assigned. Alternatively, the position transmitter 38 also the unlocked position e be assigned or the locking element 2 several position sensors 38 have which pairs of the unlocked position e and the locking position V assigned. In the locked position V becomes the bolt sensor 19 by one of the position transmitters 38 actuated. In this way, it can be determined by sensor whether the locking element 2 in the locked position V located or not.

Due to the locking element on both sides 2 arranged position transmitter 38 can be regardless of the bolt position L1 . L2 of the locking element 2 a position determination using the bolt sensor 19 respectively. In every latch position L1 . L2 is one of the position indicators 38 from the bolt sensor 19 detectable. To also determine the position of the locking element 2 by means of the bolt sensor 19 also for different bolt directions R1 . R2 the latch sensor can enable 19 at two different positions within the transom housing 3 be arranged as in 6 shown. In 6 (a) is the locking element 2 along the bolt direction R1 arranged. The bolt sensor 19 is in the sensor holder 3.6 of the latch housing 3 arranged. Will the locking element 2 repositioned so that it is along the bolt direction R2 is aligned, so is the bolt sensor 19 from the sensor mount 3.6 in the sensor holder 3.5 repositioned as in 6 (b) shown. Each of the sensor mounts 3.5 . 3.6 is therefore a bolt direction R1 . R2 assigned.

In 6 can also be seen that the biasing element 23 , together with the locking element 2 , is repositioned so that the locking element 2 in every bolt orientation R1 . R2 towards its locking position V is biased.

In 7 are the different actuation options of the locking element 2 shown as an example.

7 (a) shows the locking element 2 in its locked position V , where it is partly from the transom housing 3 protrudes. In 7 (b) is the actuator 16 of the drive 10 in the coupling element 17 inserted and rotated clockwise. The drive elements 6 . 7 were through the actuator 16 rotated so that over the cams 6.3 . 7.3 the locking element 2 against the biasing element 23 in the unlocked position e was transferred. By turning the drive device 6 which with the coupling link 12 is coupled, the coupling link 12 by rotating the drive element 6 moved axially. This axial movement of the coupling member 12 however, it does not affect the other drives 8th . 9 out. With the drive 10 it is an emergency drive, which is used in particular in the event of a power failure or in similar situations to open the lock 1 is used.

7 (c) shows the actuation of the locking element via the drive 9 , Here the tension element 15 partially axially from the bolt housing 3 pulled out. This is done via a in the actuating claw 15.3 engaging Bowden cable, not shown here. Over the coupling section 15.2 and the coupling section encompassing it 12.3 the axial movement on the coupling link 12 transfer. The axial movement of the coupling link 12 transfers further to the drive element coupled to it 6 as well as the one with the drive element 6 over the wave 22 connected drive element 7 , Both drive elements 6 . 7 are rotated clockwise, what about the cams 6.3 . 7.3 for an axial movement of the locking element 2 from the locked position V towards the unlock position e leads. The axial movement of the locking element 2 takes place essentially transversely to the axial movement of the tension element 15 , The coupling link 12 and the drive elements 6 . 7 act here in the manner of a deflection gear for transmitting motion from the tension element 15 on the locking element 2 , Even with the drive 10 it is an emergency drive. In contrast to the drive 10 can the drive 9 due to the Bowden cable but also be operated from positions that are further from the closure 1 are removed.

In 7 (d) is the actuation of the locking element 2 by means of the electric drive 8th shown. The drive 10 forms the main drive of the closure 1 , via which this is usually operated. The rotation of the engine 13 is transmitted via the transmission 39 on the cam element 14 , The coupling section 12.2 of the coupling link 12 glides over the control curve 14.1 of the cam element rotated 14 , with the control curve 14.1 a thrust on the coupling section 12.2 exercises. The rotary movement of the cam element 14 is transmitted through the worm-like control curve 14.1 in an axial movement of the coupling member 12 , As previously described, this axial movement causes the locking element to be transferred 2 from the locked position V in the unlocked position e ,

Will the locking element 2 by none of the drives 8th . 9 . 10 more in the unlocked position e held, ie when the actuator 16 removed or turned back, no more pulling force on the pulling element 15 exercised and / or the cam element 14 through the electric motor 13 in the in 7 (a) position shown is turned back, so the biasing element 23 release the energy stored in it and the locking element 2 from the unlocked position e in the locked position V move.

In 8th is the coupling between the drive element 6 and the locking element 2 recognizable on the basis of various schematic sectional plane representations.

In 8 (a) is a section along one through the drive member 6 shown levels. The two coupling elements can be seen 6.1 . 6.2 , which are essentially offset by 90 degrees. In the coupling element 6.1 engages the lead 12.1 of the coupling link 12 on. The essentially L-shaped shape of the coupling element can be seen 12 with the coupling area 12.3 , which is to the side of the rest of the coupling link 12 protrudes. In the hook-shaped coupling area 12.3 grasps the tension element 15 with its coupling section 15.2 on.

A section along one through the locking element 2 trending level is in 8 (b) shown. From the locking element 2 is the latch section on the left side of the figure 2.1 and on the right side of the figure that of the recess 2.2 facing drive surface 2.5 to recognize. In the recess 2.2 grabs the cam 6.3 of the drive element 6 on. The locking element 2 is in the locked position V so that the locking element 2 with the drive surface 2.5 on the axis of the drive element 6 but not from the cam 6.3 from the locked position V is moved out. Axial to the drive element 6 is the wave with a substantially square cross section 22 arranged.

Starting from 8 (b) is by operating the electric motor 13 the cam element 14 rotated about its longitudinal axis such that the control curve 14.1 the coupling section 12.2 of the coupling link 12 from the locking element 2 axially moved away like this in 8 (c) is shown. As already described above, the tension element 15 by the movement of the coupling link 12 does not move and remains in its rest position. By the movement of the coupling link 12 pulls it into the coupling element 6.1 engaging engagement tab 12.1 this towards the electric motor 13 , As a result, the drive element 6 rotated so that the cam 6.3 a force on the drive surface 2.5 exercises and the locking element 2 against the bolt direction R1 from the locked position V in the unlocked position e transferred. By designing the coupling element 6.1 in the manner of an elongated hole is the engagement projection 12.1 a radial play in the coupling element 6.1 allows. This allows the axial movement of the coupling member to be transmitted 12 in a rotational movement of the drive element 6 without a force acting transversely to its axial movement on the coupling member 12 is exercised as would be the case if the engaging projection 12.1 on all sides in the coupling element 6.1 would intervene.

In the following, we will now use the 9 to 13 Embodiments of the modular locking system are discussed, in which the closure 1 as a latch module 100 is trained.

In 9 (a) is first a perspective view of an embodiment of a modular locking system with a locking module 100 shown, which of one of the closures described above 1 is formed. Part of the latch module 100 is a locking element 2 , a the locking element 2 receiving bolt housing 3 and an electric drive 8th to move the locking element back and forth 2 between the locked position V and the unlocked position e , The latch module 100 can, as above in connection with the reorientation of the locking element 2 explained in detail, used for a large number of different applications and, in the case of special requirements, with a system module having the requirement-specific system components 200 can be connected both mechanically and electrically via appropriate interfaces.

In 9 (b) and 9 (c) are further configurations of a locking system with different locking modules 100 shown. This in 9 (b) latch module shown 100 reaches into a striker in the manner of a rotary latch 30 on. On the opposite side of the latch module 100 this is with the system module 200 connected.

In 9 (c) a further embodiment of the modular locking system is shown, the locking module 100 for use with a locking element designed in particular as a hook latch or lever latch 2 suitable is. This latch module 100 has an area with a reduced width, on which a system module is located on the end face 200 is arranged and which on the edge side 3.7 a socket 113 having.

The system modules 200 can be used with all of the latch modules shown 100 or the closures designed as latch modules in all the figures 1 get connected. The system module 200 can be used in different ways with the latch module 100 interact, especially with the electric drive 8th and / or the control device 20 of the drive, cf. also 5 , It can take on various functions, e.g. B. serve as a reading and / or receiving module, as a fingerprint reader, a card reader or as an adaptable memory module, which the closure 1 supplied with electrical energy. Several system modules can also be connected in series, for example via the in 9 (c) shown socket 113 of the system module 200 ,

In this way, the modular locking system can be adapted to different needs and requirements in the manner of a modular system. The connection between the latch module 100 and the system module 200 takes place on the edge side, ie over one of the edge sides 3.7 or one of the end faces 3.8 of the latch housing 3 , In particular, an end connection between the locking module 100 and the system module interacting with it 200 has proven to be advantageous, since this enables a flat and narrow design, as shown for example in 9 is shown.

How the representations in the 10 (a) to 10 (c) the system module points out 200 a connection area 210 and the latch module 100 a correspondingly designed connection area 110 on. About the connection areas 110 . 210 is the system module 200 mechanically and / or electrically with the latch module 100 connected. The two connection areas 110 . 210 In this respect act as an interface over which the modules are located 100 . 200 can be easily combined into a functional overall system.

The connection area 110 of the latch module 100 is in accordance with the designs 10 (b) and 10 (c) executed identically. In the connection area 110 are counter-locking structures 111 arranged, which are formed by two dome-like housing connecting elements. These housing connecting elements serve to connect the two shell-shaped housing parts 01.03 . 3.2 of the latch housing 3 and take a screw serving as a second housing connecting element 35 on. The counter-locking structures 111 are of cylindrical geometry and in the corners of the transom housing 3 arranged. Between the counter-locking structures 111 there is a connection opening 29 ,

The connection area 110 of the latch module 100 can with the connection area 210 of the system module 200 be positively connected, for which the system module 200 about in the executions 10 (b) and 10 (c) differently designed locking elements 211 features. The locking elements 211 can each on the counter-locking structures 111 be locked.

In the embodiment according to FIG. 10 (b), the locking elements are concerned 211 around snap connectors. These can resemble hooks in the direction of the longitudinal axis LA of the latch housing 3 into the connection opening 29 be inserted. When viewed in the direction of insertion, they have a chamfer so that when they are in contact with the cylindrical one Against locking structures 111 Dodge inwards and then snap back via the material's own spring, which locks it against the counter-locking structure 111 lock.

In contrast, the locking elements 211 according to the execution in 10 (c) around locking elements designed in the manner of plug connectors 211 , These will be like this in 10 (c) can be seen, not axially in the direction of the housing axis LA , but transversely to it from above into the area of the connection opening 29 inserted. The locking elements designed as connectors 211 are of somewhat semicircular or crescent-shaped contours and form a positive fit on the circumference of the counter-locking structures 111 of the latch module 100 on. After fastening the housing part 01.03 on the housing part 3.2 is the system module 200 form-fitting with the latch module 100 connected.

A completely different design of the connection area 210 of the system module 200 as well as the connection area 110 of the latch module 100 shows the design according to 10 (a) ,

This is just a locking element 212 in the manner of a snap connector in the connection area 210 and only a counter lock structure 112 in the form of an insertion opening in the connection area 110 intended. In addition to these mechanical locking elements 112 . 212 is in 10 (a) also an electrical plug-in element 213 provided which in a correspondingly designed electrical socket 113 of the latch module 100 is insertable. When plugging in, there is not only an electrical connection between the locking module 100 and the system module 200 , a mechanical connection is also created immediately.

While the design in the 10 (a) to 10 (c) is chosen such that the locking elements 211 . 212 on the system module 200 and the counter locking structures 111 . 112 on the latch module 100 are arranged, it goes without saying that the corresponding elements can also be arranged upside down.

As in 11 shown, for example, the electrical lines 27 and a connector 26 which with the electric motor 13 and the control device 20 are connected during assembly in the system module 200 are attached and / or with components of the system module 200 get connected.

This in 11 and 12 shown system module 200 is designed in the manner of a memory module which has two memory elements 220 to supply the electric drive 8th and / or the control device 20 with energy.

These storage elements are held on one side 220 through a recording 230 , To remove the storage elements 220 can the recording 230 from the rest of the system module 200 solved and spaced so that the storage elements 220 be made accessible. The recording 230 acts to establish an electrical connection with the connection element 250 together. Both elements 230 . 250 each have a biasing element 232 . 252 on whichever one of the storage elements 220 for establishing an electrical connection in the direction of the other element 250 . 230 biases. The preload element 232 is made by a contact element 231 worn, which is an electrically conductive connection between the two memory elements 220 manufactures.

In the assembled state of the two housing parts 201 . 202 having system module 200 the 11 form partition elements similar to partitions 205 of the housing part 202 , together with holding elements 242 one in the system module 200 used functional elements 240 , for each storage element 220 a tunnel-like insertion area, which is on both sides of the connection element 250 or the recording 230 is completed. The housing parts designed as an upper and lower shell 201 . 202 of the system module 200 are via dome-like housing fasteners 204 and screw-type housing fasteners 203 connected with each other.

The connection element 250 also has connection points 251 to which the electrical lines used for power supply 27 of the latch module 100 can be connected. The remaining electrical lines 27 as well as the connector 26 are in the system module 200 through a connector receptacle 241 held in a defined position. This allows, in the assembled state of the locking system, consisting of a locking module 100 and a system module 200 , a plug for connection to the locking module 100 into that of the latch module 100 facing end of the system module 200 insert. The connector receptacle 241 is in one piece with the functional element 240 educated.

In 13 is one for 6 (a) analog representation with a sensor 19 and that in the system module 200 arranged and from the connector receptacle 241 worn connector 26 shown. On the latch module 100 became the tension element 15 before installing the system module 200 away. In this way, the actuating claw protrudes on the one hand 15.3 no longer from the front 3.8 which otherwise the assembly of the system module 200 would hinder. In addition, the tension element 15 as well as the comprehensive drive 9 no longer required because the system module designed as a memory module 200 the locking element 100 independent of an external power supply. An emergency drive via the drive 9 with which the closure 1 can also be operated in the event of a power failure, since such a power failure occurs due to the self-sufficient energy supply by the memory module 200 no longer on the clasp 1 effect.

Using the closure described above 1 , the modular locking system and the method for assembling the modular locking system can be a lock 1 can be used for arrangement in different mounting positions for locking and the system can be adapted to a wide variety of requirements.

LIST OF REFERENCE NUMBERS

1

shutter

2

locking element

2.1

locking portion

2.2

recess

2.3

passage

2.4

recess

2.5

drive surface

3

bolt housing

3.1

housing part

3.2

housing part

3.3

mounting side

3.4

mounting side

3.5

sensor recording

3.6

sensor recording

3.7

edge side

3.8

front

3.9

Through opening

4

bolt opening

5

bolt opening

6

driving element

6.1

coupling element

6.2

coupling element

6.3

cam

7

driving element

7.1

coupling element

7.2

coupling element

7.3

cam

8th

drive

9

drive

10

drive

11

locking unit

12

coupling member

12.1

engaging projection

12.2

coupling section

12.3

coupling section

13

electric motor

14

Cam member

14.1

cam

15

tension element

15.1

biasing portion

15.2

coupling section

15.3

actuating tab

16

actuator

17

coupling element

18

drive sensor

19

bar sensor

20

driving device

21

cover

22

wave

23

biasing member

24

biasing member

25

biasing member

26

Connectors

27

electrical line

28

cover

29

connecting opening

30

striker

31

connecting portion

32

locking portion

35

screw

36

locator

37

locator

38

locator

39

transmission

100

latch module

110

connecting area

111

Against locking structure

112

Against locking structure

113

Rifle

200

system module

201

housing part

202

housing part

203

System housing connecting element

204

System housing connecting element

205

retaining element

210

connecting area

211

locking element

212

locking element

213

plug-in element

220

storage element

230

admission

231

contact element

232

biasing member

240

functional element

241

connector receptacle

242

retaining element

250

connecting element

251

junction

252

biasing member

A

axis

e

unlocking

G

Einlegrichtung

V

locking position

R1

tie sense

R2

tie sense

R3

tie sense

L1

locked position

L2

locked position

LA

housing longitudinal axis

Claims (16)

Locking system with a lock (1) which has a locking element (2), a locking housing (3) receiving the locking element (2) and an electric drive (8) for moving the locking element (2) back and forth between a locking position (V) and has an unlocking position (E), characterized in that the closure (1) is designed as a locking module (100) and at least one further system module (200) is provided which can be connected to the locking module (100). Locking system after Claim 1 , characterized in that the system module (200) interacts functionally with the drive (8) and / or a control device (20) of the drive (8). Locking system after Claim 2 , characterized in that the system module (200) is a storage module for providing electrical energy for operating the closure (1) and / or a reading and / or receiving module, in particular a fingerprint reader, an NFC transmitter, an NFC receiver Bluetooth transmitter, a Bluetooth receiver and / or a card reader. Locking system after Claim 3 , characterized in that the system module (200) in the form of a storage module has at least one storage element (220), in particular a capacitor, an accumulator or a battery, for supplying the drive (8) and / or the control device (20) with electrical energy. Locking system according to one of the preceding claims, characterized in that at least two system modules (200) interacting with the locking module (100) can optionally be connected to one another and / or to the locking module (100) in the manner of a modular system. Locking system according to one of the preceding claims, characterized in that the system module (200) can be connected at the edge to the latch housing (3) of the latch module (100). Locking system according to one of the preceding claims, characterized in that the system module (200) has a connection area (210) and the locking module (100) has a correspondingly designed connection area (110) via which the system module (200) mechanically and / or electrically with the Bolt module (100) can be connected. Locking system after Claim 7 , characterized in that the connection areas (110, 210) have at least one locking element (211, 212) and at least one counter-locking structure (111, 112), via which the system module (200) can be positively connected to the locking module (100). Locking system after Claim 8 , characterized in that the locking element (211, 212) is designed in the manner of a plug connector and / or snap connector. Locking system after Claim 8 or Claim 9 , characterized in that the counter-locking structure (111) is formed by a housing connecting element. Locking system after Claim 10 , characterized in that the housing connecting element is formed after a threaded bush. Locking system according to one of the Claims 8 to 11 , characterized in that two counter-locking structures (111) are provided which include a connection opening (29) into which two locking elements (211, 212) can be inserted and / or latched. Locking system after Claim 8 or 9 , characterized in that the counter-locking structure (111) is formed by an insertion opening. Locking system according to one of the Claims 7 to 13 , characterized in that the connection areas (110, 210) each have at least one electrical plug element (213) and at least one electrical socket (113), via which the system module (200) can be electrically connected to the locking module (100). Locking system after Claim 14 , characterized in that the electrical plug element (213) and the electrical socket (113) can be positively connected to one another. Locking system according to one of the preceding claims, characterized in that the locking element (2) is arranged repositionable in the locking housing (3) between at least two locking orientations (R1, R2, L1, L2).

Images