EP3243980A1 - Locking system - Google Patents

Abstract

A locking system (10), in particular locking system of a door opener or lock, comprises a housing (12), a lock (14), in particular pivotably or displaceably mounted in the housing (12) cooperating with a latch or the like, an actuator (16) and between the Locking (14) and the actuator (16) arranged force transmission elements (18) which are displaceably mounted in the housing (12) between a locking position in which they lock the lock (14) and a release position in which they the lock (14 ). In this case, at least two running as rolling elements, successive rolling force transmission elements (18) are provided, wherein one (18 0) of these force-transmitting elements (18) by a respective application by the activated actuator (16) for transferring the power transmission elements (18) in the Locking position relative to the at least one immediately adjacent further force transmission element (18 1 or 18 1, 18 2) is positioned offset, so that in the direction of movement of the actuator (16) extending force component is generated and by the actuator (16) acted upon force transmission element (18 0) with activated actuator (16) for releasing the lock (14) at least substantially in the direction of movement of the actuator (16) can escape.

Description

The present invention relates to a locking system, in particular locking system of a door opener or lock, with a housing, a cooperating with a latch or the like, in particular pivotally mounted in the housing lock, an actuator and between the lock and the actuator arranged force transmission elements in the housing between a Locking position in which they lock the lock, and are mounted displaceably in a release position in which they release the lock.

Such locking systems, which are provided in particular for door openers or locks, often tend to jam at higher loads. In addition, the usual locking systems are relatively large in view of the applied high forces and the required stability.

The invention has for its object to provide a locking system of the type mentioned, with which the aforementioned disadvantages are eliminated. In this case, the locking system with a simpler and more compact design in particular to ensure greater reliability and have a longer life.

According to the invention the object is achieved by a locking system with the features of claim 1. Preferred embodiments will become apparent from the dependent claims, the present description and the drawings.

The locking system according to the invention, in particular locking system of a door opener or lock, comprising a housing, a cooperating with a latch or the like, in particular pivotally mounted in the housing lock, an actuator and arranged between the lock and the actuator power transmission elements in the housing between a Locking position in which they lock the lock, and are mounted displaceably in a release position in which they release the lock. In this case, as force transmission elements at least two running as rolling elements, rolling-rolling force transmission elements are provided, wherein one of these force transmission elements is offset by a respective actuation by the activated actuator for transferring the force transmission elements in the locking position relative to the at least one immediately adjacent further force transmission element, so that an extending in the direction of movement of the actuator force component is generated and can be acted upon by the actuator load-transmitting element with deactivated actuator to release the lock at least substantially in the direction of movement of the actuator.

Due to this design results in a relatively simple, compact and correspondingly inexpensive construction. In addition, the locking system according to the invention not only ensures a higher reliability, it also has a longer life. The applied forces are easy to calculate and therefore manageable. As rolling elements wear-resistant standard parts can be used, which increases the life of the locking system accordingly. With the higher accuracy and surface quality of such normal parts results in accordance with again higher reliability. There are a total of relatively few components required. This results in lower overall manufacturing tolerances. In addition, the cost-producible locking system according to the invention is universally applicable.

The locking system is also relatively low friction, since the mechanical interaction of the rolling elements on rolling movements and occurs almost exclusively rolling friction forces.

According to an advantageous practical embodiment of the locking system according to the invention, this has only two force transmission elements designed in each case as rolling bodies rolling against one another. By the accordingly small number of components not only increase the reliability and durability, the locking system is also cheaper to produce accordingly.

In this case, the one to the loadable by the actuator force transmission element immediately adjacent further force transmission element is preferably arranged between the acted upon by the actuator force transmission element and the lock.

According to an alternative advantageous embodiment, the locking system has only three power transmission elements each designed as rolling elements rolling against each other. Thus, the functional reliability is increased accordingly in still relatively limited number of components and correspondingly inexpensive construction.

In this case, the force transmission element which can be acted upon by the actuator is preferably arranged between the two directly adjoining further force transmission elements.

Conveniently, one of the two directly adjacent to the acted upon by the actuator force transmission element power transmission elements between the acted upon by the actuator force transmission element and the latch is arranged.

According to a preferred practical embodiment of the locking system according to the invention, the power transmission elements are each designed as a particular hardened steel rollers. With such hardened steel rollers wear-resistant standard parts can be used for the power transmission elements, which results in a higher reliability and lower manufacturing tolerances due to the accuracy and surface quality of such standard parts.

The actuator preferably comprises an electromagnet. Alternatively or additionally, however, the actuator may also include, for example, an electromechanical actuator, an electric motor, a hydraulic actuator, a pneumatic actuator, and / or the like.

In particular, the lock may comprise a lever mounted pivotably on the housing about an axis, a linearly guided slide or the like.

According to an expedient practical embodiment of the locking system according to the invention, the locking device comprises a door-opener trap cooperating in particular with a lock latch.

In addition, it is advantageous if the pivotally mounted about an axis in the housing latch is provided with an eccentric to the pivot axis approach by which the immediately adjacent power transmission element is pressed with a respective pivoting of the lock in its release position against the acted upon by the actuator force transmission element, so in that the force transmission element which is acted upon by the actuator and displaced relative to the force transmission element which can be acted upon by the locking is forced out of its locking position, at least substantially in the direction of movement of the actuator, when the actuator is deactivated. In contrast, the lock is activated by the actuators held in its locking position from being pivoted from its locking position to its release position, since the acted upon by the activated actuator force transmission element can not escape in the direction of movement of the actuator and corresponding to the locking adjacent force transmission element the lock is blocked by its eccentric approach.

In this case, the immediately adjacent to the locking force transmission element is disabled actuator with a respective pivoting of the lock pressed in the release position by the eccentric approach preferably at least substantially transversely to the direction of movement of the actuator against the acted upon by the actuator force transmission element.

In addition to or instead of the actuator may be provided as overload protection spring unit or the like, through which the force transmission element is resiliently held in its locking position.

It is also advantageous if the acted upon by the actuator force transmission element is supported at their locking position engaging force transmission elements on a shoulder of the housing and thereby positioned relative to the at least one immediately adjacent further force transmission element.

Fig. 1

eine schematische, teilweise geschnittene Seitenansicht einer beispielhaften Ausführungsform eines erfindungsgemäßen Verriegelungssystems mit zwei jeweils als Wälzkörper ausgeführten, aufeinander abrollenden Kraftübertragungselementen, wobei die Kraftübertragungselemente durch das aktivierte Stellglied in deren Verriegelungsposition gehalten sind,

Fig. 2

eine schematische, teilweise geschnittene Seitenansicht des Verriegelungssystems gemäß Fig. 1, wobei die Kraftübertragungselemente bei deaktiviertem Stellglied deren Freigabeposition einnehmen,

Fig. 3

eine schematische, teilweise geschnittene Seitenansicht des Verriegelungssystems gemäß Fig. 1 mit einer als Überlastsicherung dienenden Federeinheit,

Fig. 4

eine schematische, teilweise geschnittene Seitenansicht einer weiteren beispielhaften Ausführungsform eines erfindungsgemäßen Verriegelungssystems mit drei jeweils als Wälzkörper ausgeführten, aufeinander abrollenden Kraftübertragungselementen, wobei die Kraftübertragungselemente durch das aktivierte Stellglied in deren Verriegelungsposition gehalten sind, und

Fig. 5

eine schematische, teilweise geschnittene Seitenansicht des Verriegelungssystems gemäß Fig. 4, wobei die Kraftübertragungselemente bei deaktiviertem Stellglied deren Freigabeposition einnehmen.

The invention will be explained below with reference to exemplary embodiments with reference to the drawing. In this show:

Fig. 1

a schematic, partially sectioned side view of an exemplary embodiment of a locking system according to the invention with two each executed as rolling elements, rolling rolling force transmission elements, wherein the force transmission elements are held by the activated actuator in its locking position,

Fig. 2

a schematic, partially sectioned side view of the locking system according to Fig. 1 , wherein the force transmission elements occupy the release position when the actuator is deactivated,

Fig. 3

a schematic, partially sectioned side view of the locking system according to Fig. 1 with a spring unit serving as an overload protection,

Fig. 4

a schematic, partially sectioned side view of another exemplary embodiment of a locking system according to the invention with three each executed as a rolling, successive rolling force transmission elements, wherein the force transmission elements are held by the activated actuator in its locking position, and

Fig. 5

a schematic, partially sectioned side view of the locking system according to Fig. 4 , The power transmission elements occupy the release position with deactivated actuator.

The Fig. 1 to 5 show exemplary embodiments of a locking system 10, which may be, for example, a locking system of a door opener or lock.

In this case, the locking system 10 comprises a housing 12, a cooperating with a latch or the like, in the housing 12 in particular pivotally or slidably mounted locking latch 14, an actuator 16 and arranged between the latch 14 and the actuator 16 power transmission elements 18 which in the housing 12 between a locking position in which they lock the locking latch 14 (see Fig. 1 and 4 ) and a release position are displaceably mounted, in which they release the locking latch 14 (see Fig. 2 and 5 ).

In each case, at least two designed as rolling elements, successive rolling force transmission elements 18 are provided, one of which, namely in each case the force transmission element 18 ₀ , by a respective application by the activated actuator 16 for transferring the force transmission elements 18 in the locking position relative to the at least one immediately adjacent further force transmission element 18 ₁ (see Fig. 1 and 2 ) or 18 ₁ and 18 ₂ (see the 4 and 5 ) is positioned so that an extending in the direction of movement of the actuator 16 force component is generated and acted upon by the actuator 16 force transmission element 18 ₀ at deactivated actuator 16 to release the locking latch 14 at least substantially in the direction of movement of the actuator 16 can escape.

This points in the Fig. 1 to 3 illustrated locking system 10 only two each as rolling rolling elements running on each other executed power transmission elements 18 ₀ , 18 ₁ . In this case, the one to be acted upon by the actuator 16 force transmission element 18 ₀ immediately adjacent further power transmission element 18 ₁ between the acted upon by the actuator 16 power transmission element 18 ₀ and the locking latch 14 is arranged.

In contrast, this has in the 4 and 5 illustrated, another embodiment representing locking system 10 three each designed as rolling rolling elements rolling force transmission elements 18 ₀ , 18 ₁ , 18 ₂ on.

In this case, the force can be acted upon by the actuator 16 power transmission element 18 ₀ between the two immediately adjacent further power transmission elements 18 ₁ , 18 ₂ arranged.

Like that 4 and 5 can also be found, is one, namely the power transmission element 18 ₁ , the two immediately adjacent to the acted upon by the actuator force transmission element 18 ₀ adjacent power transmission elements 18 ₁ , 18 ₂ disposed between the acted upon by the actuator 16 power transmission element 18 ₀ and the locking latch 14.

The power transmission elements 18 of the various embodiments of the locking system can each be designed as a particular hardened steel rollers.

The respective actuator 16 may in particular comprise an electromagnet. However, in principle, any other actuators are conceivable. Thus, the actuator 16 may alternatively or additionally include, for example, an electromagnetic actuator, an electric motor, a hydraulic actuator, a pneumatic actuator and / or the like.

The respective locking latch 14 may, for example, comprise a lever pivotably mounted on the housing 12 about an axis 20.

The respective locking latch 14 may comprise, for example, a door opener latch cooperating in particular with a latch or the like.

Like that Figures 1-5 can also be removed, the pivotal about an axis 20 mounted on the housing 12 locking latch 14 may be provided with an eccentric to the pivot axis 20 approach 22, through which the immediately adjacent force transmission element 18 ₁ with a respective pivoting of the locking latch 14 in its release position against the the actuator 16 is acted upon force transmission element 18 _{0 is} pressed so that the acted upon by the actuator 16, relative to the acted upon by the locking latch 14 force transmission element 18 ₁ offset force transmission element 18 _{0 is} at least substantially expelled in the direction of movement of the actuator 16 from its locked position with deactivated actuator , In contrast, the locking latch 14 is prevented with activated actuator 16 by the held in its locking position power transmission elements 18 to be pivoted from its locking position to its release position, since the acted upon by the actuator 16 force transmission element 18 ₀ can no longer dodge in the direction of movement of the actuator and accordingly that to the latch 14th adjacent power transmission element 16 ₁ blocks the locking latch 14 via the eccentric approach 22.

In this case, in the present cases, the immediately adjacent to the locking latch 14 power transmission element 18 ₁ with deactivated actuator 16 with a respective pivoting of the locking latch 14 in its release position by the eccentric projection 22 each at least substantially transverse to the direction of movement of the actuator 16 against the by the actuator 16 acted upon power transmission element 18 ₀ pressed.

Like in the Fig. 3 illustrated, a respective locking system 10 may include as overload protection also a spring unit 24, through which the power transmission member 18 _{0 is} resiliently held in its locking position.

As can be seen from the various representations, can be acted upon by the actuator 16 force transmission element 18 _{0 supported} at their locking position force transmitting elements 18 on a shoulder 26 of the housing 12 and thereby positioned relative to the at least one immediately adjacent further force transmission element 18 ₁ , 18 ₂ offset become.

Fig. 1 shows an exemplary embodiment of the locking system 10 according to the invention with two each running as a rolling body, rolling rolling force transmission elements 18 in a phase in which the power transmission elements 18 are held by the activated actuator 16 in its locking position. By the offset of the rollers or force transmission elements 18, the force is not transmitted via the ball vertex, but experiences a transverse force in the direction of movement of the actuator 16th

Fig. 2 shows the locking system 10 according to Fig. 1 in a phase in which the power transmission elements 18 occupy their release position when the actuator 16 is deactivated.

Fig. 3 shows an exemplary embodiment of a locking system 10 according to the invention with an intended as an overload protection spring unit 24th

Fig. 4 shows an exemplary embodiment of the locking system 10 according to the invention with three each executed as rolling, successive rolling force transmission elements 18 in a phase in which the power transmission elements are held by the activated actuator 16 in its locking position. A particular advantage of this arrangement is the high quality and hardness of the rear contact surface of the central power transmission element 18 ₀ .

Fig. 5 shows the locking system 10 according to Fig. 4 in a phase in which the power transmission elements 18 occupy their release position when the actuator 16 is deactivated.

The FIGS. 6 and 7 show an exemplary embodiment of the locking system 10 according to the invention, in which the locking latch 14 is designed to be linearly displaceable.

The respective locking system according to the invention is characterized both by a compact design and high reliability. The applied forces are easy to calculate and thus manageable. Wear-resistant standard parts can be used with the hardened steel rollers as power transmission elements. The accuracy and surface quality of such standard parts results in a relatively high reliability. In addition, the locking system 10 according to the invention is characterized by a small number of components, with which the system is in particular less expensive to produce. In addition, lower manufacturing tolerances result. Finally, the lockable system 10 according to the invention that can be produced relatively inexpensively can be used universally.

LIST OF REFERENCE NUMBERS

10

locking system

12

casing

14

locking case

16

actuator

18

Power transmission element

18 ₀

Actuatable by actuator force transmission element

18 ₁

another power transmission element

18 ₂

another power transmission element

20

axis

22

eccentric approach

24

spring unit

26

paragraph

Claims (15)

Locking system (10), in particular locking system of a door opener or lock, with a housing (12), a lock (14), in particular a cooperating with a latch or the like, in the housing (12) in particular pivotably or displaceably mounted, an actuator (16) and between the lock (14) and the actuator arranged force transmission elements (18) which are displaceably mounted in the housing (12) between a locking position in which they lock the locking latch (14) and a release position in which they the lock (14 ), wherein as force transmission elements at least two each designed as rolling elements, rolling force transmission elements (18) provided and one (18 ₀ ) of these power transmission elements (18) by a respective actuation by the activated actuator (16) for transferring the force transmission elements (18) in their locking position relative to the at least one immediately adjacent further force transmission element (18 ₁ or 18 ₁ , 18 ₂ ) is positioned offset, so that in the direction of movement of the actuator (16) extending force component is generated and by the actuator (16) acted upon force transmission element (18 ₀ ) when the actuator (16) is deactivated to release the lock (14) at least substantially in the direction of movement of the actuator (16) can escape. Locking system according to claim 1,
characterized in that it has only two in each case as rolling rolling elements rolling against each other executed power transmission elements (18 ₀ , 18 ₁ ). Locking system according to claim 2,
characterized in that the one to the by the actuator (16) acted upon power transmission element (18 ₀ ) immediately adjacent further force transmission element (18 ₁ ) between the actuatable by the actuator (16) force transmission element (18 ₀ ) and the lock (14) is arranged , Locking system according to claim 1,
characterized in that it has only three in each case as rolling rolling elements rolling against each other executed power transmission elements (18 ₀ , 18 ₁ , 18 ₂ ). Locking system according to claim 4,
characterized in that the by the actuator (16) acted upon power transmission element (18 ₀ ) between the two immediately adjacent further power transmission elements (18 ₁ , 18 ₂ ) is arranged. Locking system according to claim 5,
characterized in that one (18 ₁ ) of the two force transmission elements (18 ₁ , 18 ₂ ) directly adjoining the force transmission element (18 ₀ ) which can be acted upon by the actuator is interposed between the force transmission element (18 ₀ ) which can be acted upon by the actuator (16) and the locking mechanism (18). 14) is arranged. Locking system according to at least one of the preceding claims,
characterized in that the force transmission elements (18) are each designed as particular hardened steel rollers. Locking system according to at least one of the preceding claims,
characterized in that the actuator (16) comprises an electromagnet. Locking system according to at least one of the preceding claims,
characterized in that the actuator (16) comprises an electromechanical actuator, an electric motor, a hydraulic actuator, a pneumatic actuator, and / or the like. Locking system according to at least one of the preceding claims,
characterized in that the lock (14) comprises a pivotable about an axis (20) in the housing (12) mounted lever or a linearly guided slide. Locking system according to at least one of the preceding claims,
characterized in that the lock (14) comprises a particular cooperating with a latch case door latch. Locking system according to at least one of the preceding claims,
characterized in that the about an axis (20) pivotally mounted in the housing (12) locking (14) with a pivot axis (20) eccentric approach (22) is provided by the immediately adjacent force transmission element (18 ₁ ) with a respective Pivoting the lock (14) in its release position against the by the actuator (16) baufschlagbare power transmission element (18 ₀ ) is pressed, so that by the actuator (16) acted upon, relative to the acted upon by the lock (14) force transmission element (18 ₁ ) offset positioned force transmission element (18 ₀ ) at deactivated actuator (16) at least substantially in the direction of movement of the actuator (16) is pushed out of its locking position. Locking system according to claim 12,
characterized in that the force transmission element (18 ₁ ) directly adjoining the lock (14) is pivoted or displaced in its release position by its eccentric projection (22) at least substantially transversely to the direction of movement of the actuator (16). is pressed against the by the actuator (16) baufschlagbare power transmission element (18 ₀ ). Locking system according to at least one of the preceding claims,
characterized in that serving as an overload safety spring unit (24) is provided, by which the force transmission element (18 ₀ ) is resiliently held in its locking position. Locking system according to at least one of the preceding claims,
characterized in that the force transmission element (18 ₀ ), which can be acted upon by the actuator (16), is supported on a shoulder (26) of the housing (12) at its locking position engaging force and thereby relatively to the at least one immediately adjacent further power transmission element (18). 18 ₁ , 18 ₂ ) can be positioned offset.

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