EP2703584B1 - Passive wing locking device with a motorised actuation device - Google Patents

Description

The invention relates to a passive wing lock device for a door, a window or the like. The door or the window has a stationary mountable frame with at least one active wing and at least one passive wing mounted in the frame. It is therefore an at least double-leaf door or corresponding window. The passive wing is referred to below as the passive wing and the active wing below as the active wing.

The passive wing lock device can be mounted in and / or on the passive wing. It has a lock mechanism and an actuating device. It is essential that this passive wing lock device has an upper and / or a lower locking bar that can be extended and retracted. In this respect, the lock mechanism has an upper locking bar connecting device of a locking bar guided in and / or on the passive wing, which can be extended upwards for locking and for unlocking is retractable downwards. Additionally or alternatively, the lock mechanism has a lower locking bar connecting device of a lower locking bar guided in and / or on the passive wing, which can be extended downwards for locking and upwards for unlocking. Such lock devices for double-leaf doors with an active lock device with latch and bolt and a passive lock device with lifting device for latch and bolt are known from practice and are described, for example, in EP 0 849 425 B1 ,

Such passive wing lock devices are known. They each have a manual actuating device for actuating the locking bars, e.g. designed as a panic push rod, on. In the known passive wing lock devices, a latch lifting device and / or a latch lifting device is actuated via the panic push rod. These lifting devices serve to retract a latch or bolt of an associated active lock device, which is mounted in the active wing, from its extended locking position, in which the latch or bolt engages in the passive wing lock device.

A motorized lifting device for a lock latch is known for single-leaf doors. There, a special electric door opener is used in the stationary door frame of the door, which has an electric motor-driven lifter instead of a conventional door opener latch. Such a special door opener is eg in the WO 2008/083826 described and is marketed by the applicant as a product with the product name "eff eff Mediator".

From the EP 2 166 180 B3 a single-leaf door with a self-locking lock is known. There is an electromotive actuation device on the door wing that serves to unlock the lock. The electromotive actuation device guides the bolt from its locking position into its unlocking position.

From the EP 2 236 714 A2 a locking device for a door having an active wing and a passive wing is known. A locking bar lock arranged on the passive wing has locking bars arranged on both sides. There is a power drive attached to the locking bar lock of the passive wing, which acts on the locking bars. From the WO 97/17519 A2 a locking device for a door having an active wing and a passive wing is known. It is envisaged that the lower locking bar of the passive wing has an electric drive.

The invention has for its object to provide a passive lock device of the type mentioned, which opens up new fields of application. Another object is to create a passive lock device of the type mentioned in the introduction, in which a motor-driven lifting of a latch and / or a bolt of an associated active wing lock device is realized, which is comparable to the mediator technology with single-leaf doors.

The invention solves these problems with the subject matter of claim 1.

An essential measure here is that the lock actuation device has a motor drive device, the output of the motor drive device with the latch Lifting device and the bar lifting device and the upper locking bar connecting device and the lower locking bar connecting device can be coupled or coupled directly or via a gear. The motor drive device is preferably an externally powered motor device, preferably an electromotive device.

It is envisaged that the lock mechanism has a gear with a gear slide, which can be coupled or coupled to the output of the motor drive device directly or via a gear, it being provided that the gear slide is connected to the lower locking bar connecting device and to the upper locking bar Connection device is connected and is connected to the latch lifting device and is connected to the latch lifting device.

It can be provided that the lower locking bar connection device is coupled or can be coupled to the gear slide in a fixed manner for movement in the same direction of movement, and the upper locking bar connecting device can be coupled or coupled to the gear slide via a gear reversing the direction of motion, for example lever gear or toothed gear. Alternatively, it can be provided that the upper locking bar connection device with the gear slide is coupled or can be coupled for movement in the same direction of movement and the lower locking bar connection device with the gear slide via a gear reversing the direction of movement, for. B. lever gear or gear transmission is coupled or can be coupled.

In preferred embodiments, it can be provided that the output of the motor drive device is designed as a linear output, which can be coupled or coupled to the gear slide directly or via another gear.

In preferred embodiments, it can be provided that the lock mechanism is mounted in a lock case and the motor device is arranged in a separate housing at one end of the lock case.

In preferred embodiments, it can be provided that the passive wing lock device has a sensor device in order to detect whether a trap of an active wing lock device mounted in or on the active wing engages or does not engage in a predetermined space of the passive wing lock device, the sensor device being designed in such a way that that it outputs electrical signals to an electrical signal processing device depending on the result of this detection. Additionally or alternatively, it can be provided that the passive wing lock device has a sensor device to detect whether or not a bolt of an active lock device mounted in or on the active wing engages in a predetermined space of the passive wing device, wherein the sensor device is designed so that it outputs electrical signals to an electrical signal processing device depending on the result of this detection.

In preferred embodiments, it can be provided that the passive wing lock device has a sensor device in order to detect whether or not the output of the motor drive device, which drives at least one of the locking bars and / or at least one of the lifting devices, has reached a predetermined position the sensor device is designed such that it outputs electrical signals to an electrical signal processing device depending on the result of this detection.

In preferred embodiments, it can be provided that the passive wing lock device has a sensor device in order to detect whether or not a lock nut of the lock mechanism has reached a predetermined position, the sensor device being designed such that it is dependent on outputs electrical signals to an electrical signal processing device based on the result of this detection.

In preferred embodiments, it can be provided that the passive wing lock device has a sensor device to detect whether or not a gear slide of the gear mechanism of the lock mechanism has reached a predetermined position, the sensor device being designed such that it is electrical depending on the result of this detection Outputs signals to an electrical signal processing device.

In preferred embodiments, it can be provided that the lock nut has a section which actuates a sensor of the sensor device when the lock nut is moved. Additionally or alternatively, it can be provided that the gear slide has a section which actuates a sensor of the sensor device when the gear slide is moved.

In preferred embodiments, it can be provided that the sensor device has a sensor and a button that interacts directly or indirectly with the sensor, which is movably mounted in the lock case and interacts with the component to be detected. The button advantageously has a section which actuates the sensor when the button is moved.

In preferred embodiments it can be provided that the electrical signal processing device with an electrical control device of the motor drive device of the lock actuation device and / or with an electrically switchable on / off device for the latches Lifting device and / or the bar lifting device and / or a central monitoring device is connected.

The invention is further directed to a lock device for a door, a window or the like, with a stationary mountable frame with at least one active wing mounted on or in the frame - hereinafter referred to as active wing - and at least one passive wing - hereinafter referred to as passive wing designated. Here, the lock device comprises a passive wing lock device which can be mounted in or on the passive wing, and an active wing lock device which can be mounted in or on the active wing. It is provided that the active wing lock device has a lock mechanism with a latch and / or a bolt, and that the passive wing lock device is designed according to one of the preceding claims. In particularly preferred embodiments, the passive wing lock device is designed as a mortise lock and preferably the active wing lock device is also designed as a mortise lock.

The invention is also directed to a door or window with a fixedly mountable frame with at least one active wing mounted on or in the frame - hereinafter referred to as active wing - and at least one passive wing - hereinafter referred to as passive wing, with a locking device, which comprises an active wing lock device and a passive wing lock device. Here, the active wing lock device is mounted in or on the active wing and the passive wing lock device is mounted in or on the passive wing. It is envisaged that the active wing lock device has a lock mechanism with a latch and / or has a bolt and that the passive wing lock device is designed according to one of claims 1 to 13.

The actuating device can be designed as a motor device with a rotary drive but also with a linear drive. In the case of a motorized actuating device with a rotary drive, this can preferably be coupled to the lock nut of the lock gear. In the case of a linear output, the linear output can preferably be coupled to a gear slide of the lock mechanism. In this context, versions are advantageous in which it is provided that the lock mechanism has a gear slide which is connected to the lower locking bar connecting device and to the upper locking bar connecting device and is displaceable in a first direction and for unlocking the lower locking bar and the upper locking bar Locking the lower locking bar and the upper locking bar is displaceable in a second direction.

The opposite movement of the upper locking bar to the lower locking bar can be achieved by designing the lock gear accordingly. The lock gear mechanism can be designed in such a way that one locking bar connection device is coupled to the lock gear mechanism for movement in the same direction and the other locking bar connection device is coupled for movement in opposite directions. The coupling for opposite movement can take place via a gear reversing the direction of movement. This can preferably be done e.g. B. be designed as a gear transmission or as a lever gear.

According to the invention, a lock mechanism with a lock gear with a gear slide is provided. The lower locking bar connection device can be coupled to the gear slide in a fixed manner for movement in the same direction of movement and the upper locking bar connection device can be connected to the gear slide via the gear reversing the direction of movement, e.g. Lever gear or gear transmission be coupled. The reverse case is also possible, in which it is provided that the upper locking bar connecting device is coupled to the gear slide for movement in the same direction of movement and the lower locking bar connecting device is coupled to the gear slide via the gear reversing the direction of movement, e.g. Lever gear or gear transmission is coupled.

The lock mechanism of the passive wing lock device has a bolt lifting device for unlocking and / or retracting a bolt of an assigned active wing lock device. In addition, the lock mechanism has a latch lifting device. The latch can be used as a lock latch or as a self-locking latch, i.e. be designed as a so-called latchbolt. The latch lifting device and the latch lifting device are coupled to the motorized actuating device, the output of which can be coupled or coupled with the upper locking bar connecting device and the lower locking bar connecting device directly or via a gear.

In a preferred further development, these designs can provide that the latch lifting device has a latch actuating slide, which is mounted in a linear guide device that can be firmly mounted with the passive wing is guided, which is oriented horizontally in the assembled position of the passive wing lock device. The latch lifting device can have a latch actuating slide which is guided in a linear guide device which is fixedly mounted with the passive wing and which is horizontally directed in the assembled position of the passive wing lock device.

Particular advantages result from designs which have a sensor device for the lifting device. It can be provided that the latch lifting device has a sensor device in order to detect whether the latch of the active wing lock device engages or does not intervene in a predetermined space of the passive wing lock device, the sensor device depending on the result of this detection, electrical signals to an electrical signal processing device emits. The latch lifting device can have a sensor device in order to detect whether or not the latch of the active wing lock device engages or does not engage in a predetermined space of the passive wing lock device, the sensor device emitting electrical signals to an electrical signal processing device depending on the result of this detection. With the sensor device, an advantageous control and monitoring of the lifting devices of the bolt and latch is possible. Monitoring of the closed and locked position of the door is also possible with the sensor device.

Figuren 1a bis 1c

ein erstes Ausführungsbeispiel;

Figuren 2a und 2b

ein zweites Ausführungsbeispiel;

Figuren 3a bis 3c

ein drittes Ausführungsbeispiel;

Figuren 4a bis 4c

ein viertes Ausführungsbeispiel;

Figuren 5a bis 5d

ein fünftes Ausführungsbeispiel;

Figuren 6a und 6b

ein sechstes Ausführungsbeispiel;

Figuren 7a bis 7f

ein siebtes Ausführungsbeispiel;

Figuren 8a und 8b

ein achtes Ausführungsbeispiel;

Figuren 9a und 9b

ein neuntes Ausführungsbeispiel;

Figuren 10a bis 10c

ein zehntes Ausführungsbeispiel;

Figur 11

ein elftes Ausführungsbeispiel,

Figur 12

ein zwölftes Ausführungsbeispiel,

Figur 13

ein dreizehntes Ausführungsbeispiel,

Figur 14

ein vierzehntes Ausführungsbeispiel.

In the figures, concrete exemplary embodiments are shown as examples. Show:

Figures 1a to 1c

a first embodiment;

Figures 2a and 2b

a second embodiment;

Figures 3a to 3c

a third embodiment;

Figures 4a to 4c

a fourth embodiment;

Figures 5a to 5d

a fifth embodiment;

Figures 6a and 6b

a sixth embodiment;

Figures 7a to 7f

a seventh embodiment;

Figures 8a and 8b

an eighth embodiment;

Figures 9a and 9b

a ninth embodiment;

Figures 10a to 10c

a tenth embodiment;

Figure 11

an eleventh embodiment,

Figure 12

a twelfth embodiment,

Figure 13

a thirteenth embodiment,

Figure 14

a fourteenth embodiment.

The structure and functions of the passive wing lock device

The exemplary embodiments shown in the figures are different exemplary embodiments of passive leaf lock devices 30, which are each mounted in a passive leaf 110 of a two-leaf door. These passive-wing lock devices 30 are each intended to interact with an active-wing lock device, which are to be mounted correspondingly assigned in an active wing of the double-leaf door.

An embodiment of an active wing lock device 1 mounted in an active wing 10 of a two-leaf door is in the Figures 1a to 1c shown and that in your interaction with an associated passive wing lock device, which is mounted in the passive wing 110.

The passive wing lock device 30 of the Figures 1a , 1b and 1c has a lock mechanism, which is mounted in a lock case 30a. The lock case 30a is in a receiving pocket in the passive wing 110 mounted plugged in. The lock mechanism comprises a lock gear with a gear slide 36, which is coupled in terms of gear with a lock nut 37 rotatably mounted in the lock case 30a. The gear slide 36 of the lock gear can be driven via an actuating handle, not shown, which can be coupled into the lock nut 37 by insertion. The gear slide 36 is guided vertically up and down in the lock case.

The passive wing lock device 30 comprises an upper and a lower locking bar 380o, 380u and lifting devices 31 and 32 in order to lift the latch 11 and the latch 12 of an associated active wing lock device which engage in the passive wing lock device in the locked position. The lock gear with the gear slide 36 serves to drive the upper locking bar 380o and the lower locking bar 380u and to drive the lifting devices 31 and 32. The structure and function of the lifting devices 31 and 32 are explained in detail below in conjunction with the figures.

As in the Figures 1a . 1b and 1c can be seen, the upper locking bar 380o is coupled to an upper locking bar connection device 38o mounted in the upper section of the lock case 30a. This upper connection device 38o is connected to the gear slide 36 via a reversing gear 36g. In the case shown in the figures, the reversing gear 36g is a gear transmission. For this purpose, the upper end piece of the gear slide 36 is designed as a toothed rack and the upper locking bar connecting piece 380 also has a toothed rack. A gearwheel device is rotatably mounted between the two racks in a pivot bearing fixed to the lock housing. The gear device meshes with those in vertical Direction in the lock housing linearly guided racks of gear slide 36 and locking bars connecting device 38o. The two racks face each other in parallel with an interposed gear mechanism, so that the two racks move in opposite directions in the vertical direction. This means that when the gear slide 36 is moved upward, the upper locking bar connecting device 38o is moved downward and the locking bar connecting device 38o is moved upward by moving the gear slide 36 downward.

The lower locking bar 380u is coupled to a lower locking bar connection device 38u mounted in the lower section of the lock case 30a. This lower locking bar connection device 38u is coupled in the same way to the gear slide 36, so that when the gear slide 36 is moved upwards, the lower locking bar connection device moves upward and when the gear slide 36 moves downward, the locking bar connection device 38u moves downward.

The locking bars 380o and 380u, which are driven in this way, are mounted on the passive wing 110 in a vertically directed manner and can be displaced in a linear manner, in each case in a corresponding vertical linear guide, preferably concealed in the frame of the passive wing. The locking bars 380o and 380u can be moved vertically up and down in opposite directions by their movement-fixed coupling to their associated connection device 38o or 38u by actuating the gear slide 36.

The upper end of the upper locking bar 380o cooperates with a locking receiving recess which is formed in the upper spar of the fixed frame of the door. The lower end of the lower locking bar 380u interacts with a locking receiving recess formed in the bottom. In the extended position of the upper locking bar 380o, the free upper end of the locking bar engages in the upper lock receiving recess. In the extended position of the lower locking bar 380u, the free lower end of the locking bar engages in the lower locking receiving recess.

By actuating the lock gear, in which the gear slide 36 is displaced vertically as described, not only the upper locking bar 380o and the lower locking bar 380u are extended and retracted, but also the devices cooperating with the latch 11 and the latch 22 of the active wing lock device 31 and 32 actuated.

As already mentioned, the latch lifting device 31 serves to interact with the lock latch 11 of the active leaf lock device 1. The interaction consists in the latch lifting device 31 returning the latch latch 11 into the lock case 1a of the active leaf lock device 1, in which the latch lifting device 31 the latch latch 11 pressurized and thereby pushes back until the lock latch 11 is fully inserted into the lock case 1a of the active wing lock device 1. For this purpose the latch lifting device 31 has a latch actuating slide 31a which is driven by the gear slide 36 via a lever device 31h. When the gear slide 36 is pushed upward, the lever device 31h is pivoted out, so that the latch actuating slide 31a extends. If the gear slide 36 after is pushed down, the lever device 31h is pivoted in, so that the latch actuating slide 31a is retracted again.

The latch lifting device 32 is used to unlock and retract the latch 22 of the active lock device 1. The latch lifting device 32 has, in a corresponding manner, a latch actuating slide 32a which is drive-connected to the gear slide 36 via a lever mechanism 32h. When the lever device 32h is pivoted out by actuating the gear slide 36, the latch actuating slide 32a is extended. Then, under the action of the bolt actuating slide 32a, the bolt 22 engaging in the extended locking position in the lock case 30a is unlocked and then moved back into the lock case 1a of the active lock device. Unlocking takes place by pressurizing the release pin 22a projecting beyond the end face of the latch 32. After the bolt 22 is unlocked, it is moved back into the lock case 1a of the active wing lock device by further pressurization, which acts on the bolt 22 on the end face. When the lever mechanism 32h is pivoted back, the bolt actuating slide 32a is then retracted. This is done by moving the gear slide 36 downwards in the vertical direction.

As in the Figures 1a . 1b and 1c recognizable, a linear guide device 32b of the bolt actuating slide 32a is provided in the lock case 30a. The linear guide device 32b is directed horizontally in the lock case 30, so that the bolt actuating slide 32a can be moved in and out in a horizontally guided manner. A correspondingly linear guide device can also be used for the actuating slide 31 a of the lever device 31 be formed in the lock case 30a, as z. Tie Figures 6a and 6b is shown for the embodiment shown there.

The bolt lifting device 32 is also referred to as a bolt unlocking and or retracting device. It can be designed both for unlocking and for retracting the bolt, as in that in the Figures 1a . 1b and 1c illustrated case. In other exemplary embodiments, the bolt lifting device 32 can also be designed merely as a bolt retraction device. For the unlocking, a separate device or at least one separate unlocking mechanism can be provided, which can optionally also be driven as a time delay by the gear slide 36 via the same lever device 32h or another separate lever device or via another gear. This applies in particular if the latch 22 is not provided with a release pin mounted in the latch, ie if another release element, e.g. B. separately from the latch 22, z. B. a separate auxiliary latch on the active wing 10 or on the lock case 1a is provided.
In modified exemplary embodiments, the bolt lifting device 32 can also be designed merely as an unlocking device, that is to say the bolt actuating slide 32a can then switch off the locking device by correspondingly pressurizing the release mechanism. The retraction of the bolt can optionally by another mechanism such. B. with an appropriate spring loading of the bolt. The spring device in question can be supported on the lock case 1a of the active wing lock device but also on the passive wing lap case 1a.

The latch lifting device 31 is also referred to as a latch unlocking and / or retracting device. It can, as in the Figures 1a . 1b and 1c illustrated case, only be designed as a latch retraction device, specifically for a latch 11 which is designed as a conventional lock latch which is spring-loaded in the extending direction and which is not self-locking. The spring-loaded lock latch 11 has a prism-shaped end section which has a run-in slope, so that when the active wing 10 is closed, ie when the active wing 10 is pulled or pressed into the closed position, the lock latch 11 strikes with the run-in slope on the frame of the passive wing 110 and counteracts the spring action the lock latch 11 is retracted. The slope of the lock latch 11 facing away from the inlet slope is not designed as a slope, but rather as a blocking surface directed parallel to the sash plane, so that an active actuation of the lock latch 11 is required for opening the door or in a modified version in which the lock latch 11 has a Door release latch interacts, the door release latch is actuated. In such modified versions, an electric door opener can be arranged in the passive wing lock device. The lock latch 11 can then interact with the door opener latch and the door can be released from the closed position by electrical actuation of the door opener latch.

At opposite the Figures 1a . 1b and 1c modified versions, the lock latch 11 can also be designed as a self-locking lock latch - as a so-called latch bolt. The latch bolt can assume three positions, namely a first position retracted into the lock case 1a, a second position extended from the lock case comparable to the extended position in conventional lock latches and a third position in which the latch bolt is extended and locked at the same time and / or at least looks locked. In this third position, the latch bolt is extended approximately twice as far as a conventional lock latch in its extended position. In addition, the latch bolt is locked in this extended third position, as already mentioned. Please refer to the Figures 7a and 7b , which show an embodiment in which the latch 11 is designed as such a latch bolt. In this exemplary embodiment, the latch lifting device 31 is designed as a latch unlocking and retracting device, ie the latch actuating slide 31 a serves to unlock the latch bolt 11 in a first phase of the lifting process and to retract the latch bolt in the further course of the lifting process. Unlocking takes place in that the release pin 11a, which is displaceably mounted in the latch bolt, is first retracted by the latch actuating slide 31a, ie first the free end of the release pin 11a protruding from the latch bolt 11 in the locking position is retracted by the latch actuating slide 31a. The latch 11 is unlocked by the retraction, so that the latch bolt is retracted under further pressure by the latch actuating slide 31a. Modified designs with a latch bolt are also possible, in which the latch lifting device 31 is designed only as an unlocking device or only as a retraction device. In these cases, the retraction or unlocking can take place via a separate device. The same applies as described above for the bolt lifting device 32 in connection with the unlocking or retraction of the bolt.

With double-leaf doors, a certain amount of play with a gap between the passive leaf and the active leaf cannot be ruled out in the closed position of the double-leaf door. For this, in the embodiment of the characters 1a . 1b and 1c the latch actuating slide 32a a spring-loaded pressure piece 32c. In this exemplary embodiment, the pressure piece 32c is resiliently supported on the plate-shaped base body of the bolt actuating slide 32a via a helical compression spring. The pressure piece 32c, like the plate-shaped base body of the bolt actuating slide 32a, is guided horizontally in the linear guide device 32b, which is formed in the lock case 30a. The horizontal guidance results in a jamming-free linear sliding movement and exact positioning of the actuating slide 32a and the pressure piece 32c over the entire travel path and thus a safe positionally accurate return movement of the latch 22. The spring action of the pressure piece ensures that the lifting device 32 works properly, even for Designs of double-leaf doors with a relatively large tolerance range with a gap between the passive leaf and the active leaf.

In the Figures 2a and 2 B is one towards the Figures 1a . 1b and 1c modified embodiment shown, in which the trap lifter device 31 is modified. The latch actuating slide 31a has an actuating plate which is articulated on an output-side actuating lever of the lever gear 31b. The actuating lever has a pivot bearing which is fixed in the lock case 30a and is comparable to that Figures 1a . 1b and 1c actuated by the gear slide 36, but modified in terms of construction, in that a pressure pin mounted on the actuating lever is guided in an elongated hole in the gear slide 36. In the embodiment in the Figures 1a . 1b and 1c acts a control edge of the gear slide 36 together with the pressure pin of the actuating lever, the control edge being formed in the edge contour of the control slide 36.

In the Figures 3a and 3b is one towards the Figures 1a . 1b and 1c modified embodiment shown, in which the bolt lifting device 32 is modified. The bolt actuating slide 32a has a plate-shaped base body which is guided horizontally on the edge side in the linear guide device 32b fixed in the lock case 30a. The operating lever of the operating gear 32h is similar to that in FIGS Figures 2a and 2 B guided in an elongated hole in the gear slide 36 with the pressure pin mounted on the gear lever.

That in the Figures 6a and 6b The shown embodiment of the passive wing lock device 30 is compared to the embodiment of the Figures 1a . 1b and 1c modified in that the lock gear is modified with the gear slide 36. The gear slide 36 is not driven by a gearwheel with the upper locking bar connecting device 38o mounted in the upper lock housing, but is coupled via a lever gear reversing the direction of movement in a corresponding manner.

The latch lifting device 32 is structurally similar to that in the embodiment of FIG Figures 3a and 3b ,

The sensor devices

The trap lifting device 31 is in the embodiment of the Figures 6a and 6b and the embodiment of Figures 7a to 7d compared to the embodiments of Figures 1a . 1b and 1c and the Figures 2a and 2 B modified in that the trap lifting device 31 has a sensor device 32t, with which it is detected whether the trap 22 in the Lock case 30a of the passive wing lock device is retracted or extended or is being retracted or extended. The trap lifting device 31 has as in the Figures 6a and 6b and even better in the Figures 7a to 7d A latch actuating slide 31a can be seen, which is horizontally guided with its plate-shaped base body in the linear guide device 31b fixed in the lock case. A sensor plate 31tp is additionally displaceably guided in the linear guide device 31b. The sensor plate 31tp has two contact plates on its front end edge, which come into contact with the latch 11. The sensor plate 31tp is acted upon by a spring, in the case shown a leg spring. The spring is dimensioned such that it is overpressed when the latch 11 is retracted and the latch takes the sensor plate 31tp into contact with the contact plates. The sensor plate 31tp points in the Figures 6a and 6b lower edge region has a lateral actuating edge which interacts with the obliquely angled actuating edge of a plate-shaped detection element 31te which is movably mounted in a receptacle fixed in the lock case. The detection element 31te has an extension which engages in a light sensor 31s arranged in the lock housing 1a when the sensor plate 31tp enters the lock housing 30a. The retraction and extension of the trap 11 can thus be detected by the sensor device 31t.

The task and objective of the sensor device 31t is as follows:
The sensor device 31t has two functions for the lifting process. One function is to ensure that the latch 11 is completely extended from the lock housing 30a of the passive lock device when the vehicle is retracted, and thus the lock latch 11 cannot hinder the opening of the door. The other possible function is to ensure that the If the operating slide 31a does not extend too far out of the lock housing 30a when the latch is retracted, and it is ensured that the falling operating slide 31a does not hinder the opening and closing of the door. In order to prevent such a hindrance to the door, it can also be provided that the sensor slide has an entry and / or exit slope on its front end. The sensor device 31t controls a control device (not shown) of the lifting device 31. The control device is controlled via electrical signals which the sensor device 31t emits when the trap is detected and which are fed to the control device.

Another possible function of the sensor device 31t is that e.g. A control center can be used to monitor whether the double-leaf door is closed and locked. As far as locking monitoring is concerned, this applies to exemplary embodiments in which the latch is designed as a latch bolt and for exemplary embodiments in which a corresponding sensor device is additionally or alternatively provided in the area of the bolt lifting device 32.

In the exemplary embodiments shown in the figures, the sensor device 31t is only provided in the trap lifting device 31. The latch lifting device 32 in the exemplary embodiments of the figures provides for the spring loading of the latch actuating pressure piece 32c and the prism-shaped design of the latch actuating pressure piece 32c for proper functioning. The spring action ensures that the bolt is completely retracted into the lock case 1a of the active wing lock device, in which position it is then locked in the lock housing 1a, ie held in place becomes. The spring action in conjunction with the prism shape of the pressure piece then allows the double-leaf door to be opened and closed without mutual hindrance of the leaves when opening and closing in the area of the closed position, even with a large tolerance range with a gap between the two leaves in the closed position of the door.

Figure 12 shows an embodiment of the passive wing lock device with a sensor device 31s, which compared to the sensor device 31t of the embodiment of the Figures 7a to 7f is modified. Just like the embodiment of Figures 7a to 7f serves the sensor device 31s Figure 12 for detecting whether the latch 22 in the lock case 30a of the passive wing lock device is retracted or extended or is currently being retracted or extended. The sensor device 31s is composed of a light sensor 31se and a sensor button 31st. The light sensor 31se is an optical sensor. It has a U-shaped receptacle in which the free end of the sensor button 31st engages. In contrast to the embodiment of the Figures 7a to 7f is in the embodiment of Figure 12 the sensor button is not designed as a slide, but as a two-armed lever. The sensor button 31st in Figure 12 interacts directly with the light sensor 31se. In the embodiment of the Figures 7a to 7f is provided between the light sensor 31s and the button 31tp and a wedge-shaped transmission member 31te.

The sensor button 31st of the sensor device in Figure 12 is designed as a key lever which is pivotally mounted in the lock case about an axis 31sta fixed to the lock case. The feeler lever 31st is designed as a two-armed lever. The first lever arm 31stt is used for pushing the lock latch 11 of the active wing lock device. The second lever arm 31sts has one hook-like extension that protrudes into the U-shaped receptacle of the light sensor 31s. The first lever arm 31stt of the key lever 31st protrudes into the predetermined space of the passive wing lock, which is provided for receiving the latch 11 of the active wing lock. Next is an in Figure 12 Not shown spring is provided which acts on the feeler lever 31st towards the outside.

The sensor device according to Figure 12 works as follows: In the closed position of the door, the latch 11 of the active lock device moves spring-loaded into the space provided for the latch 11 of the passive wing lock device. In this case, the latch 11 comes into contact with the first lever arm 31stt of the feeler lever 31st, so that the feeler lever 31st is pivoted about its axis of rotation 31sta by the latch 11 entering the passive wing lock device. The hook-like extension of the feeler lever 31st, which projects into the light sensor 31s when the door leaf is open, has left the U-shaped receptacle of the light sensor 31se when the latch 11 has reached its closed position. Depending on its actuation or non-actuation, the light sensor 31se emits corresponding electrical signals which are processed by an electrical signal processing system.

In modified versions, the interaction of the push lever 31st and the light sensor 32se can also be provided such that the push lever 31st engages in the light sensor 31se when the latch 11 is moved into the receiving space of the passive wing lock case. When the sash is open, the hook-like extension of the push-button lever 31st is then outside the receptacle of the light sensor 31. Also in this modified embodiment, the light sensor 31se is dependent on its actuation or non-actuation corresponding electrical signals that are processed by an electrical signal processing system.

Figure 13 shows an embodiment of the passive wing lock device with two further sensor devices 32s and 37s, one of which is assigned to the bolt 22 and the other to the lock nut 37.

The sensor device 32t is used to detect whether the bolt 22 in the lock case 30a of the passive wing lock device is extended or retracted or is currently being extended or retracted. This sensor device 32t is constructed analogously to the sensor device 31t Figure 12 , which detects the position of the trap. The sensor device consists of a light sensor 31se and a sensor button 31st. The sensor button 31st is also designed as a two-armed lever which is pivotally mounted in the lock case about an axis 31sta. The sensor button 31st has a first lever arm 31stt, which is used to feel the bolt 22, and a second lever arm 31sts, which interacts with the light sensor 31 se.

The sensor device 37s serves to detect an actuation of the lock nut 37. For this purpose, a light sensor 37se is provided. The lock nut 37 has a radially projecting arm 37fs, which is provided with an extension designed as an angled edge. In the rest position of the passive wing lock device, the extension 37fs projects into the U-shaped receiving area of the light sensor 37se. If the operating handle on the passive wing lock is operated by a user, the lock nut 37 is rotated. Here, the edge-like extension 37fs of the lock nut 37 then leaves the receiving area of the electric light sensor 37se. The light sensor 37se then emits a corresponding electrical signal that can be processed by an electrical signal processing system. The sensor device 37s can be used to detect whether the passive wing lock was opened by the manual actuation of a handle or push rod arranged on the passive wing.

In Figure 14 A sensor device 36s is shown, which serves to detect a movement of the gear slide 36. For this purpose, a light sensor 36se is provided. The gear slide 36 has a projecting extension 37fs. In the rest position of the passive wing lock device, as in Figure 14 shown, the extension 37f is located outside the U-shaped receiving area of the light sensor 37se. If the passive wing lock is actuated by the actuation handle by a user or by the motorized actuation device, then the gear slide 36 is pushed upwards. Here, the extension 36fs of the gear slide 36 enters the receiving area of the electric light sensor 36se. The light sensor 36se then emits a corresponding electrical signal that can be processed by an electrical signal processing system. The sensor device 37t can be used to detect whether the passive wing lock was opened by the manual actuation of a handle or push rod arranged on the passive wing.

The sensors 31se, 32se, 36se and 37se are mounted on a common board mounted in the lock case. In addition, an electronic device for evaluating and / or further processing the data from the sensors is provided. This electronic device can be arranged in a separate housing. This separate housing can preferably be arranged coupled to the lock case.

The circuit board on which the sensors are arranged is electrically connected to the electronic device. For this purpose, electrical cable connections can be provided, for example, via which the circuit board is connected to the electronic device arranged in the separate housing.

The information from sensors 31s and 32s can be used, for example, in a public building to monitor whether a double-leaf door is open or is in the closed position or is locked. Furthermore, a monitoring center can determine whether a door has been unlocked by actuating the nut or by activating the motorized actuation device. When the lock device is unlocked using the motorized actuation device, the position of the lock nut remains unchanged and the signal from sensor 37s remains unchanged, while unlocking by actuating the handle results in rotation of the lock nut 37 and is detected by sensor 37s assigned to the nut.

The sensors can also be used to control the motorized actuation device when the lock device is unlocked. With the aid of sensors 31se and 32se, it can be detected during unlocking whether latch 11 or latch 22 no longer protrude into the associated receptacles of the passive wing lock, whereupon the motorized actuation device can be deactivated.

The actuation of the passive wing lock device

The passive wing lock device 30 can be actuated via a manual actuation device, not shown in the figures. The Manual actuating device can be designed as a rotary handle, which can be inserted into the lock nut 37, the lock nut 37 being part of the lock gear mechanism. The rotary handle can be designed as a conventional pusher or also as a push rod, a so-called panic push rod. Both the handle and the push rod can have a corresponding rotary connection which can be inserted into the lock nut 37 in a rotationally fixed manner for coupling with the lock gear.

By actuating the actuating device, the lock nut 37 is rotated, thereby actuating the lock gear. When the lock gear is actuated, the gear slide is moved. When the lock gear is actuated, the locking bar connecting devices 38o, 38u are vertically displaced in opposite directions depending on the direction of rotation of the actuation. In addition, the latch lifting device 31 and the latch lifting device 32 are actuated simultaneously or with a time delay when the lock gear is actuated.

The lock gear mechanism is designed such that actuation of the lock nut 37 in one direction moves the upper locking bar connecting device 38o upward and the lower locking bar connecting device 38u downward, and consequently the respective locking bars 380o and 380u are respectively extended, i.e. moved into their locking position. The lifting devices 31, 32 for lifting the latch 11 and the bolt 12 are actuated via the lock gear so that the latch actuating slide 31a and the latch actuating slide 32a are inserted into the lock housing 30a of the passive lock device 30. When the lock nut 37 is turned in the opposite direction by actuation, the locking bars move in the opposite direction Connection devices 38o, 38u, according to which the locking bars 380o, 380u are retracted, that is to say the unlocking of the locking bars takes place and the lifting device 31 and 32 are extended in order to move the locking bar 22 and the latch 11 of the active lock device back into the lock case of the active lock device.

Instead of the manual actuating device, a corresponding motorized actuating device with a rotary drive can also be coupled to the lock nut 37. The lock nut 37 is rotated in a corresponding manner by this motorized actuating device and the lock gear is actuated, so that the two locking bars connecting devices 38o, 38u and the lifting devices 31, 32 are actuated in the same way.

A motorized actuating device can also be used which, in contrast to this, has a linear output. The linear output can be coupled directly to the gear slide 36. The actuation of the lock gear by the linear output of the motorized actuating device then acts in the same way as when the lock gear is actuated by rotating the lock nut 37, as described above.

The Figures 5a and 5b show the passive wing lock device 30 with such a motorized actuating device 37m arranged at the lower end of the lock case 30a. The coupling of the motorized actuating device 37m to the lock gear takes place via a coupling slide 37k, which has one end on the linear output of the motorized actuator 37m and is coupled at its other end to the gear slide 36 of the lock gear in a non-moving manner. Figures 5c and 5d show the clutch slide 37k coupled to the gear slide without the motorized actuating device 37m being coupled. The configuration with the motorized actuating device can be optional.

The anti-tamper devices

Different manipulation protection devices are provided in the exemplary embodiments shown in the figures, but are not part of the invention. The tamper protection devices are intended to prevent the locking bars from being retractable by external pressure acting on the locking bar 380o and / or 380u.

One version of such a tamper protection device is in the Figures 4a, 4b and 4c shown. Here, a blocking member 39b movably mounted in the lock housing 30a is provided, which blocks a displacement of the locking bar in the retracting direction when external pressure is applied, in that the blocking member 39b engages in a recess 36a in the gear slide 36 in its blocking position. Figure 4a shows the position before a manipulation attempt is made by external pressure on the locking bars 380o, 380u.

Figure 4b shows the blocking member 39b in the blocking position during a manipulation attempt. The gear slide 36 is manipulated to apply pressure to the locking bars relative to the position in FIG Figure 4a on Move a bit upwards and is held against a further upward displacement by the blocking member 39b.

Figure 4c shows the blocking member 39b in the release position, in which it is disengaged from the gear slide 36. In this release position, the blocking member 39b is displaced by the actuation of the lock nut 37, namely in that, by rotating the lock nut 37 in the illustration in the figure in the counterclockwise direction, the driver 37a fixed with the lock nut 37 interacts with the blocking member 39b and the blocking member 39b in the representation in the Figure 4c shifted to the left.

This first embodiment of the tamper protection device in the Figures 4a to 4c thus acts on the gear slide 36 and thus on both locking bars; however, it requires an actuating device on the lock nut 37. A second embodiment of a tamper protection device is shown in FIGS Figures 9a and 9b shown. This manipulation protection device does not require actuation of the lock gear via the lock nut 37, but the actuation of the lock gear can also be effected via a linear output of the gear slide, for example via the motorized actuation device 37m Figures 5a and 5b respectively. This embodiment of the tamper protection device sees in the embodiment of the Figures 9a and 9b a link device 39k, which is formed between the upper locking bar connecting device 38o and the gear slide 36. The link device 39k has a link slot 39ok which is formed with the plate-shaped main body of the upper locking bars connecting device 38o. The link device 39k also has a lever 39h, which is mounted in a pivot bearing fixed to the lock case and has a link pin at one end, which in the Link slot 39ok engages and has at its other end a guide pin which engages in an elongated hole which is formed in the gear slide 36.

The link slot 39ok is designed as an angular slot with an upper vertical branch and a lower horizontal branch. In the event of a manipulation attempt, the link pin 39s moves into the upper vertical branch of the link slot 39ok and blocks a vertical movement of the upper locking bars connecting device 38o (see Fig. 9a ). As a result, no manipulation movement is transmitted to the gear slide 36.

In the event that there is no attempt at manipulation, i.e. no pressure is exerted on the upper locking bar 380o from the outside, the arrangement of the lever 39h, which can be spring-loaded accordingly, so that the link pin 39s moves into the horizontal branch of the link slot 39ok. By actuating the lock gear, i.e. By actuating the gear slide 36, the upper locking bar connecting device 38o and thus the upper locking bar 380o can now be operated, i.e. extend and retract.

The above-described link device 39k thus forms in the exemplary embodiment described above Figures 9a and 9b a tamper protection device for the upper locking bar 380o.

For the lower locking bar 380u, which in the relevant embodiment is moved in the same direction as the gear slide 36 of the lock gear, a tamper protection device is provided, as shown in FIGS Figures 10a and 10b is shown. This Manipulation protection device has a blocking lever 39p which is mounted in a pivot bearing fixed to the lock case. It is spring loaded and / or gravity loaded into the Figure 10a with its free end facing left. In this position, a blocking pin 39s which is fixed in motion with the gear slide 36 engages in the hook-shaped recess of the blocking lever 39p. When the gear slide 36 is moved upward for unlocking by actuating the lock gear, there is a relative displacement between the blocking pin 39s and the blocking lever 39p, in which the blocking pin 39s slides up on the curve edge of the blocking lever 39p and the blocking lever 39p in the illustration in FIG Figure 10a pivots counterclockwise (see Fig. 10b ). If the gear slide 36 is now moved downward in the opposite direction by actuating the lock gear via the actuating device, the reverse relative movement takes place back into the position in FIG Figure 10a ,

Figure 10c shows the situation in case of a manipulation attempt. In this case, the plate-shaped base body of the lower locking bar connecting device 38u is guided upwards by the upward pressure acting on the locking bar 380u in the elongated holes and thereby comes into contact with the lower bottom of the blocking lever 39p. In this way, a movement of the lower locking bar 380u is counteracted in a manipulation attempt and the lower locking bar 380u is blocked in the extended position. The vertical movement of the lower bolt connecting device 38a is therefore not transmitted to the gear slide 36.

Figure 11 shows an eleventh embodiment of the passive wing lock device with a tamper protection device for the lower Locking bar 380u, the tamper protection device according to Figure 11 against the tamper protection device according to Figures 10a to 10 c is modified. The tamper protection device has a blocking lever 39p which is mounted in a pivot bearing fixed to the lock case. The blocking lever has a blocking stop 39b which, in the blocking position, cooperates with the lower locking bar connecting device 38u, as in FIG Figure 11 is shown. The blocking stop 39b is designed as a stop step on the side edge of the blocking lever 39p. The attempt at manipulation is in Figure 11 shown. Figure 11 shows the protection against manipulation during a manipulation attempt. The protection against manipulation consists in the fact that when pressure is exerted on the lower locking bar connecting device 38u, the lower locking bar connecting device 38u comes into abutment position against the blocking stop 39b of the blocking lever 39p and is thereby blocked against further displacement in the vertical direction upwards. As a result, no vertical movement is transmitted to the gear slide 36 through the lower locking bar connecting device 38u.

The blocking lever 39p is provided with a link slot, in which a link pin 36k of the gear slide 36 engages. If, in the case of a proper unlocking by actuating the nut 37 or the motorized actuating device 37m, the gear slide 36 is moved upward for unlocking, the pin 36k fixed with the gear slide moves vertically upward and thereby runs in the link slot 39k of the blocking lever, thereby causing the blocking lever 39p is pivoted counterclockwise in the case shown. The blocking lever 39p then no longer protrudes in the pivoted manner into the movement range of the lower locking bars connecting device 38u. Simultaneously with the pivoting of the blocking lever 39p, a Lever pivoted 38h. The lever 38h is pivotally mounted in the lock case 38a about an axis 38a which is fixed to the lock case and cooperates with an actuating stop arranged on the foot side on the gear slide 36. When the gear slide 36 is pushed up, the lever 38 is pivoted clockwise in the illustrated case. The lever 38h is designed as an actuating lever of the lower locking bar connecting device 38u. With its free end, it cooperates with a corresponding stop on the lower locking bar connecting device 38u. The lower locking bar connecting device 38u is thus moved in the same direction as the gear slide 36 and the lower locking bar is moved into the lock case.

LIST OF REFERENCE NUMBERS

10

active wing

110

passive wings

1

Active wing lock

1a

Lock case from 1

11

Cases

11a

release pin

17

lock follower

22

bars

22a

release pin

30

Passive wing lock

30a

Lock case from 30

31

Fall lifting device

31a

Fall actuation slide

31b

guide means

31c

Fall actuating pressure piece

31h

lever means

31t

sensor device

31tp

Sensor slide with contact surfaces on the face

31te

detection element

31s

light sensor

32

Latch lifting device

32a

Bolt actuating slide

32b

guide means

32c

Spring-loaded thrust piece

32h

lever means

36

gear shifter

36g

reverse gear

37

lock follower

37a

takeaway

37m

Motorized actuator

37k

coupling slider

39k

block mechanism

39ok

link slot

39h

rocker arm

39b

blocking member

39p

Lower locking lever

39s

blocking pin

38o

Upper locking bars connecting device

38op

Plate-shaped body of 38o

380o

Upper locking bar

38u

Lower locking bars connecting device

38ub

blocking lever

380U

Lower locking bar

10

active wing

100

stationary frame

110

passive wings

Claims (14)

1. Passive leaf locking device (30) for a door, a window or similar having a fixed mountable frame (100) with at least one active leaf (10)- subsequently referred to as the active leaf -supported in the frame, and at least one passive leaf (110) - subsequently referred to as the passive leaf,
   wherein it is provided that
   the passive leaf locking device (30) is mountable in and/or on the passive leaf (110) and has a locking mechanism, which is supported in the lock case (30a), and a lock actuating device, and
   the locking mechanism of the passive leaf locking device has a latch lifting device (31) for unlocking and/or retracting a latch (11) engaging in a predetermined space of the passive leaf locking device, in particular lock latch or latch bolt of an active leaf locking device (1) mounted in and/or on the active leaf, and
   the locking mechanism has a bolt lifting device (32) for unlocking and/or retracting a bolt (22) of an active leaf locking device (1) mounted in and/or on the active leaf (10), said bolt (22) engaging in a predetermined space of the passive leaf locking device, and
   the locking mechanism has an upper locking rod connecting device (38o) of an upper locking rod (380o) guided in and/or on the passive leaf (110), which is extendable upwards for locking and retractable downwards for unlocking, and
   the locking mechanism has a lower locking rod connecting device (38u) of a lower locking rod (380u) guided in and/or on the passive leaf (110), which is extendable downwards for locking and is retractable upwards for unlocking, and
   the lock actuating device has a motor drive device (37m), and
   the driven element of the motor drive device (37m) is coupled with or couplable with the latch lifting device (31) and the bolt lifting device (32) and the upper locking rod connecting device (38o) and the lower locking rod connecting device (38u) directly or via a gear,
   characterised in that
   the locking mechanism of the passive leaf locking device has a lock gear with a gear slide (36), which is coupled with a pivotably supported lock follower (37) via the gear, wherein the gear slide (36) is drivable by means of an actuating handle, which is couplable in the lock follower (37) by insertion, and the gear slide (36) is guided vertically upwards in the lock case (30a) and is moveable downwards, and
   the gear slide (36) is connected to the lower locking rod connecting device (38u) and is connected to the upper locking rod connecting device (38o) and is connected to the latch lifting device (31) and is connected to the bolt lifting device (32), and
   the gear slide (36) of the locking mechanism is coupled with or is couplable with the driven element of the motor drive device (37m) directly or via a gear, and when the locking device is unlocked by means of the motor drive device (37m), the position of the lock follower (37) remains unchanged, while an unlocking by actuating the handle results in a rotation of the lock follower (37).
2. Locking device according to claim 1,
   characterised in that
   the lower locking rod connecting device (38u) is coupled with or is couplable with the gear slide (36) in a moveably fixed manner in the same direction of movement, and the upper locking rod connecting device (38o) is coupled with or is couplable with the gear slide (36) via a gear reversing the direction of movement, for example, lever gear or gear transmission (36g); or
   the upper locking rod connecting device (38o) is coupled with or is couplable with the gear slide (36) for moving in the same direction of movement, and the lower locking rod connecting device (38u) is coupled or is couplable with the gear slide (36) via a gear reversing the direction of movement, for example lever transmission or gear transmission (36g).
3. Locking device according to one of claims 1 or 2,
   characterised in that
   the driven element of the motor drive device is formed as linear driven element, which is connected to or is connectable to the gear slide (36) directly or via another gear.
4. Locking device according to one of the preceding claims,
   characterised in that
   the locking mechanism is supported in the lock case (30a) and the motor device is arranged on an end of the lock case (30a) in a separate housing.
5. Locking device according to one of the preceding claims,
   characterised in that
   the passive leaf locking device has a sensor device (31t) in order to detect whether a latch (11) of an active leaf locking device (1) mounted on the active leaf engages or does not engage in a predetermined space of the passive leaf locking device (30), wherein the sensor device (31t) is formed in such a way that it outputs electrical signals to an electrical signal processing device depending on the result of this detection, and/or
   the passive leaf locking device has a sensor device (31t) in order to detect whether a bolt (22) of an active leaf locking device (1) mounted in or on the active leaf engages or does not engage in a predetermined space of the passive leaf locking device (30),
   wherein the sensor device (31t) is formed in such a way that it outputs electrical signals to an electrical signal processing device depending on the result of this detection.
6. Locking device according to one of the preceding claims,
   characterised in that
   the passive leaf locking device has a sensor device in order to detect whether the driven element of the motor drive device (37m), which drives at least one of the locking rods and/or at least one of the lifting devices, has reached a predetermined position or not,
   wherein the sensor device is formed in such a way that it outputs electrical signals to an electrical signal processing device depending on the result of this detection.
7. Locking device according to one of the preceding claims,
   characterised in that
   the passive leaf locking device has a sensor device (37s) in order to detect whether a lock follower (37) of the locking mechanism has reached a predetermined position or not, wherein the sensor device (36s) in formed in such a way that it outputs electrical signals to an electrical signal processing device depending on the result of this detection.
8. Locking device according to one of the preceding claims,
   characterised in that
   the passive leaf locking device has a sensor device (36s) in order to detect whether a gear slide (36) of the gear of the locking mechanism has reached a predetermined position or not, wherein the sensor device (36s) is formed in such a way that it outputs electrical signals to an electrical signal processing device depending on the result of this detection.
9. Locking device according to one of claims 7 or 8,
   characterised in that
   the lock follower (37) has a section (37fs) which actuates a sensor (37se) of the sensor device (37s) when the lock follower (37) is shifted, and/or
   the gear slide (36) has a section (36fs) which actuates a sensor (36se) of the sensor device (36s) when the gear slide (36) is shifted.
10. Locking device according to one of the preceding claims,
    characterised in that
    the sensor device has a sensor and a probe which directly or indirectly cooperates with the sensor, which is moveably supported in the lock case and cooperates in a probing manner with the component to be detected.
11. Locking device according to claim 10,
    characterised in that
    the probe has a section which actuates the sensor when the probe is moved.
12. Locking device according to one of the preceding claims,
    characterised in that
    the electrical signal processing device is connected to an electrical control device of the motor drive device of the lock actuating device and/or to an electrically switchable on/off-switching device of the latch lifting device and/or the bolt lifting device and/or a central monitoring device.
13. Locking device for a door, a window or similar, having a fixed mountable frame with at least one active leaf - subsequently referred to as the active leaf -supported in the frame, and at least one passive leaf - subsequently referred to as the passive leaf,
    here, the locking device comprises a passive leaf locking device, which is mountable in or on the passive leaf, and an active leaf locking device, which is mountable in or on the active leaf,
    wherein it is provided that
    the active leaf locking device has a locking mechanism with a latch and/or a bolt, and the passive leaf locking device is formed according to one of the preceding claims.
14. Door or window having a fixed mountable frame with at least one active leaf-subsequently referred to as the active leaf - supported in or on the frame, and at least one passive leaf - subsequently referred to as the passive leaf,
    having a locking device which comprises an active leaf locking device and a passive leaf locking device, wherein the active leaf locking device is mounted in or on the active leaf, and the passive leaf locking device is mounted in or on the passive leaf, wherein it is provided that

    - the active leaf locking device has a locking mechanism with a latch and/or a bolt, and

    - the passive leaf locking device is formed according to one of claims 1 to 12.

Images