NO323115B1 - DORLES - Google Patents

Description

The present invention relates to door locks of the type described in the introduction to claim 1.

Door locks of this type usually also include a bolt which is activated by a cylinder mechanism, where turning a key in the lock's opening direction will retract both the bolt and a latch.

However, the invention can also be applied to door locks of the type that lack a standard latch and where the latch also functions as a latch. Typically, such locks are also provided with a safety latch which ensures that the latch cannot be pressed in by means of a tool inserted into the door crack when the door is closed. In this respect, the shutter can only be retracted with the help of the key and with the help of the door knob or the twister when this is permitted.

However, the invention can also be applied to other types of locks, e.g. locks that lack a safety catch of the above type.

FI-B-854835 (WårtsilåVAbloy) describes a door lock of the same type as the door lock according to the invention, which lacks a rail and where "coupling devices" are provided between the button drop tube and the door knob or similar turning directions, and which includes a solenoid for controlling the coupling devices. Depending on the application, the solenoid in an active state will either establish a connection between the drop tube and the drop or bring this connection to an end, however always so that the drop can be activated via the cylinder lock.

The constructions described in the publication are technically complicated, i.a. because the solenoid armature during its movement between its end positions is designed to rotate and displace various component elements in the locking mechanism itself. Thus, in order to make the device function satisfactorily, it is necessary that the solenoid armature perform a not insignificant functional work. This increases the risk of unsatisfactory function of the lock and shortens its service life.

US-A-3 748 878 (Balzano, et al) describes a lock of the type in question where a power transmitting connection between a button and a rail can be controlled by a solenoid. In this lock construction, the electrically controlled coupling device can be moved in the direction of the button's axis to break or establish the connection of the button and the rail.

DE-A-2 151 904 (Hemmen) describes a lock of the relevant type where the solenoid always releases the lock when it is activated.

SE-B-426 858 (FAS) describes another type of coupling device for switching on or connecting the drop pipe which activates the drop.

SE-B-442 420 (WSO CPU-System) describes a somewhat different lock construction comprising a rail, a button or the like, and an electrically actuated button connection device. The coupling device is in the form of a disk which along its circumference is provided with at least one tooth which cooperates with a bracket-borne rotatable hook which is connected to the electric maneuvering device in a way that enables turning of the hook into and out of engagement with the tooth. The device is mainly affected by the same disadvantages as the devices described in the aforementioned Finnish publication.

DE-C1-38 17 696 (Meyers & Meister) describes a mechanical combination lock comprising a coupling system with a rotatable or rotatable carrier disk, which lock is particularly intended for safes, vaults and safety storage cabinets. The disc has a recess or notch in which a chin-bearing abutment element connected to a rail ("Einfallhebel") is capable of engaging when permitted by a solenoid-activated locking element. The locking element is movable at right angles to the plane of movement of the carrier disc and the abutment element. When the abutment element engages with the washer, rotation of the washer causes the rail to be pulled back to its lock release position. Code discs arranged between the notches or recesses are mounted adjacent and parallel to the driver disc.

This type of combination lock thus differs from door locks such as e.g. is intended for use in houses, apartments and buildings, and which is provided with a trap which has a flanged or similarly enlarged part at one end, and where the trap is activated by two separate mechanisms, one of which is a cylinder lock mechanism, to which the present invention shall be attributed.

Further examples of the state of the art can be found in DE-A-26 22 720 (Matzanke) and EP-Al-0 315 056 (Hellmuller + Zingg).

The purpose of the invention is to provide a door lock of the above type which comprises only a few reliably cooperating enough components, and where the solenoid armature does not need to perform any actual work in connection with the activation of the device which is required to enable or prevent the retraction of the case by activating the button drop pipe.

These and other purposes are achieved in accordance with the invention with a locking device of the above-mentioned type with the characteristic features indicated in the characteristic of claim 1.

When using a coupling element provided with a stop stop intended for the above-mentioned interaction with a stop stop on a solenoid armature, the solenoid does not need to perform any other operational function in connection with the activation of the fall with the downpipe, via the coupling element or movement out of engagement with the coupling element to avoid such actuation, other than that necessary to ensure that the armature stop will be in or out of engagement with the stop on the coupling element by means of movement of the armature stop in a plane parallel to the plane of motion of the remaining elements. In other words, the solenoid armature is not necessary to activate any elements which are included in the locking mechanism in question and which are required to maneuver the fall using the fall tube, which is the case with constructions according to known technology. This reduces the number of lock components required, while reducing the risk of damage to the lock and the risk of lock malfunctions, while also increasing the lock's reliability and extending its life.

In practice, the anchor's stop stop can be arranged on an element connected to the anchor, e.g. a sliding element which moves mainly in a straight line between two end positions in said plane.

For this purpose, the sliding element may comprise an elongated hole which receives a pin to control the movement of the sliding element.

The stops in question can have the simple form of shoulders, the direction of which when engaging with each other is perpendicular to the direction of movement of the sliding element. It appears from this that the work which must be done by the solenoid armature in moving a sliding element of this simple design together with its associated shoulder in and out of engagement with the shoulder of the coupling element is practically negligible. Movement of the sliding element together with the supply of current to the solenoid will preferably be against the action of a spring, which functions to return the sliding element and its stop shoulder, biased by the spring, to their initial or original position when the current supply to the solenoid is interrupted.

In a practically preferred embodiment, the coupling element has the form of a hook element with two adjacent recesses or openings for alternative engagement with a coupling device connected to the downpipe, e.g. a pin that extends parallel to the axis of rotation of the downpipe.

In this embodiment, the coupling element has a simple and compact construction, while at the same time the engagement of the downpipe with the coupling element is made easier.

In practice, it is preferred that the pivot shaft in the coupling element is mounted in an elongated hole in the element, so that, when the coupling device engages with one of the recesses, the coupling element will be both rotatable and displaceable on the pivot shaft.

The possibility of combined turning and linear movement of the coupling element produces the invention's special function of allowing free passage of the downpipe when the two stop stops engage, while, when this is not the case, initial movement of the downpipe will cause the coupling the element is rotated about its axis of rotation to bring the downpipe into engagement with the second recess by means of the coupling device, to reliably connect the downpipe to the coupling element. Continued turning movement of the drop tube will then cause the coupling element to both rotate and move linearly in relation to its axis of rotation, and to pull the drop back to its lock release position, with the help of the coupling element which grips the flange on the end of the drop or an element placed next to it.

The coupling element is preferably activated by a spring, which, when the stop stops are not in mutual engagement, causes initial rotation of the coupling element so that the button drop tube's coupling device is able to engage in the other recess on the coupling element.

The present invention will now be described in more detail with reference to an exemplary embodiment thereof and also with reference to the accompanying drawings. Figures 1-4 show a latch according to the invention. The illustrated locks are shown prior to installation, and the figures show the lock box and the various lock mechanisms housed in it. The button downpipe mechanism that activates the trap is shown in different positions, where figures 1-3 show engagement of the downpipe mechanism and retraction of the trap, while fig. 4 shows the downpipe in a disconnected state. More specifically: Fig. 1 shows the initial position of the coupling hook when the stop stops are out of mutual engagement and prior to the initial turning movement of the button drop tube. Fig. 2 shows the position of the coupling hook after initial turning movement of the hook and the button drop tube, to achieve coupling engagement between the coupling element and the button drop tube. Fig. 3 shows the state of the lock when the button or twister is still turned and the catch is retracted. Fig. 4 shows the stop stops in engagement with each other, where the coupling hook remains in its initial position and free passage of the button's drop tube arm is permitted.

The illustrated drop lock consists of a lock box 1 which comprises a lock post 2 and which accommodates a rail 6 and an associated locking mechanism, represented by a cylinder drop tube 4 with a toothed segment 4a in engagement with a toothed segment 5, which, via a pin 8 in a opening 6a arranged in the bolt 6, causes the bolt to move linearly in and out of a locked position in response to turning the lock key (not shown) in an associated cylinder lock (not shown). The pulley mechanism cooperates with a driver arm 7 which cooperates with the second rod device in the lock, namely the catch 24, in a manner which is described in detail below. The trap 24 typically comprises a trap rod 24a and a trap flange 24b. The drop flange is activated by a spring 25. The drop rod 24a is enclosed by a plate or disk 9 in the vicinity of the drop flange 24b.

The trap 24 is maneuvered in the usual way by means of a button trap tube 15 with a trap tube arm 15a and a trap tube hub or bushing 16. The trap tube is rotatable about an axis 15c. The downpipe can be activated by a button, a knob or a similar device (not shown) in the usual way.

The downpipe arm 15a activates the flange 24b on the downpipe 24 via a coupling element which in the case shown is in the form of a coupling hook 10 provided with two mutually adjacent recesses 1 Oa and 1 Ob which interact with a coupling device in the form of a pin 15b on the downpipe arm 15a in a way which is described in more detail below.

The coupling hook is provided with an elongated hole 10d which accommodates a pivot pin 10c, which enables the coupling hook 10 to both be turned on and moved linearly in relation to the pin 10c. The coupling hook 10 is also provided with a stop stop 1 Oe, with a function that will be described in more detail below. The coupling hook 10 is biased by a spring 23 which tries to turn the hook 10 around the pivot pin 10c in a clockwise direction. The drop tube 15 is rotated clockwise around the hub 15c against the action of a spring 17. Reference number 20 denotes a mount for a solenoid 21 with an armature 21a which cooperates with a sliding element 22. The sliding element is provided with an elongated hole 22a which accommodates a pin 22b, which pin controls or gives rise to the rectilinear movement of the sliding element. The sliding element carries a stop stop 22e intended for interaction with the stop stop 10e on the hook element 10 (cf. below). The solenoid armature 21a is biased in the outward direction by a spring 19, i.e. it is biased towards the position where the stop stops 10e and 22e on the respective hook element 10 and sliding element 22 engage with each other.

Voltage is applied to the solenoid 21 by means of an electrical contact device 14 placed on the outside of the lock box, the electrical arrangement inside the lock box comprising a protection diode 18.

The latch mechanism also comprises a safety latch 26 provided with a dirk protection 27 and a safety latch hook 11 actuated by a spring 28. The arrangement prevents the latch 24 from being pulled back from its locking position to its locking release position, e.g. using a screwdriver or similar inserted in the door crack. The safety catch 26 is affected by a spring 29. A spring 30 is provided for activation of the toothed segment 5.

The safety catch 11 is also adapted to cooperate with a microswitch 12 mounted in the lock box, which enables the state of the lock to be indicated electrically. Connection of the drop tube 15 to the coupling hook 10 to cause movement of the drop 24 to its lock release position by means of the twister or button will now be described with reference to figures 1-3. Connecting the downpipe to the chin 10 requires that the stop stop 10e on the chin is out of engagement with the stop stop 22e on the sliding element 22 connected to the solenoid armature 21a. In the illustrated embodiment, this is carried out by supplying current to the solenoid 21 by means of the electrical contact device 14 located on the outside of the lock box, whereby the solenoid armature 21a will be attracted against the action of the spring 19 and the coupling device, i.e. that the pin 15b, on the downpipe arm 15a will engage with the recess 10a in the coupling hook 10, which thus holds the downpipe arm 15a in the position shown in fig. 1.

Activating the button (not shown) causes the downpipe, and thus the downpipe arm 15a, to be turned to the position shown in fig. 2, i.e. that the pin 15b leaves the recess 10a and enters the recess 1 Ob in the coupling hook, as the hook is simultaneously rotated clockwise by means of the bias exerted by the spring 23. The coupling hook 10 and the downpipe 15 are thus connected. Continued rotation of the downpipe 15 to the position shown in fig. 3 will then result in further rotation of the coupling hook 10 about its axis 10a. At the same time, the coupling hook is moved in relation to the pivot pin 10a which is located in the elongated hole 10d. During this movement, the coupling hook grips the plate 9 which rests against the flange 24b of the trap, so that the trap 24 is pulled back.

When the button or knob is released, all component elements are returned to the position shown in fig. 1 under the influence of the downpipe spring 17.

Fig. 4 shows what happens when current supplied from the electrical contact device 14 to the solenoid is broken and the knob or knob is turned. The solenoid armature 21a is pressed by the spring 19 to the right of the figure, resulting in corresponding rectilinear movement of the sliding element 22. As shown in fig. 4, the stop stop 10e on the coupling hook 10 engages with the stop stop 22e on the sliding element 22, which means that the coupling hook 10 will be prevented from turning clockwise under the influence of the spring 23 when the button or twister is activated to turn the downpipe clockwise. The trap tube arm 15a and the pin 15b instead pass under the hook portion 10f of the coupling hook 10, i.e. the trap remains locked in its locking position.

It appears from this that the solenoid armature does not contribute to the rotation or displacement of any vital components that belong to the locking mechanism itself or the components that are active when connecting parts in the locking mechanism. The sole purpose of the solenoid armature is to generate rectilinear movement of the sliding element 22 which carries the stop stop 22a from one end position to another, where the coupling elements 10e and 22e are either mutually engaged or disengaged.

When current is again applied to the solenoid, the solenoid armature will be returned by the action of the spring 19.

It should be understood that the activation direction of the solenoid can be opposite to that described, i.e. so that the stop stops are moved out of their position with mutual engagement or engagement when the current to the solenoid is interrupted.

The locking components described above may also have a different design or configuration than the one described and illustrated within the scope of the inventive idea as stated in the accompanying patent claims.

Claims (6)

1. Door lock comprising a lock box (1) which accommodates a catch (24) comprising a catch rod (24a) and a catch flange (24b), and which is movable from a locking position to a lock release position against the action of a spring (25), where the latch (24) can be activated by mechanisms located on different sides of the latch in the lock box, namely by a key-activated cylinder mechanism with a latch tube (4) which, via further functional elements (for example 5, 7), causes a movement of the latch to be moved to its lock release position in response to turning a lock key, and a button drop tube (15) which can be rotated by means of a button, a turner or similar device and which cooperates with a coupling element (10) which is rotatable about a pivot pin (10c) so that rotational movement of the button drop tube in one position of the coupling element (10) causes a retraction of the drop (24) to its lock release position, and in another position causes the drop to remain unaffected by the movement of the button drop tube lse, where the coupling element (10) also cooperates with a solenoid armature (21a) which is mounted in the lock box and, depending on the position of the armature, cooperates by moving the coupling element (10) to one or the other of the aforementioned rotational positions, where the coupling element (10) and the solenoid armature (21a) carries mutually interacting stop stops (10e, 22e) which are movable in a plane parallel to the plane of movement of the trap (24), and the armature-supported stop stop (22e) is mounted on an element, e.g. a sliding element (22), which generally moves in a straight line between two end positions in the aforementioned plane, characterized in that said stop stops (10e, 22e) when they are in mutual engagement or engagement, in that the anchor-supported stop stop (22e) is arranged to take a position below the coupling element, stop stop (10e) and thereby prevent an initial rotation of the coupling element , function so that they hold the coupling element in a position where it is unaffected by the rotary movement of the button drop tube (15); that the anchor-supported stop stop (22e) after movement in said plane is out of engagement with the stop element (10e) carried by the coupling element, which is arranged to rest on the button drop tube and follow the latter when this is moved, and that rotational movement of the button drop tube (15 ) causes the button drop tube to be connected to the coupling element (10), as continued rotation of the button drop tube results in retraction of the drop (24) by means of the direct or indirect action of the coupling element on the drop drop flange (24b). 2. Door lock according to claim 1, characterized in that the sliding element (22) comprises an elongated hole (22a) which receives a pin (22b) for controlling or guiding the linear movement of the sliding element. 3. Door lock according to requirements 1-2, characterized in that the coupling element has a hook-like shape (10) which comprises two mutually adjacent recesses (10a, 10b) for alternative engagement with a coupling arrangement, for example a pin (15b), which is connected to the button drop tube (15) and which extends parallel to the axis of rotation (15c) in the button drop tube. 4. Door lock according to claim 3, characterized in that the pivot shaft (10c) in the coupling element (10) is located in an elongated hole (10d) in the coupling element, so that, when the coupling device (15) engages in one of the recesses (10a, 10b), the coupling element (10) both is rotatable and linearly displaceable in relation to the pivot shaft (10c). 5. Door lock according to claim 4, characterized in that, when the stop stops (10e, 22e) are out of mutual engagement, rotation of the button drop tube (15) results in rotation of the coupling element (10), engagement of the coupling device (15b) in the other (10b) of the said recesses in the coupling element (10), continued rotation and linear movement of the coupling element relative to its axis of rotation (10c), and retraction of the drop (24) by engagement with its drop flange (24b) or an element (9) mounted adjacent to it. 6. Door lock according to claim 5, characterized in that the coupling element is activated by a spring (23) which functions so that it rotates the element clockwise around the pivot shaft (10c).