SE506763C2 - Locks - Google Patents

Abstract

The lock housing (1) of a door lock houses two mutually independent mechanisms for retracting a latch bolt (24) from its locking position. The one mechanism enables the latch bolt to be retracted by turning a key in a cylinder lock provided with a cylinder follower (4), in a conventional manner. The second mechanism enables the latch bolt to be retracted with the aid of a knob follower (15) in coaction with a coupling hook (10), providing that a stop member (22e) which is actuated by the core (21a) of a solenoid (21) and which moves in the movement plane of the coupling hook is not in engagement with a corresponding stop member (10e) on the coupling hook (10). In this regard, rotational or pivotal movement of the knob follower causes a coupling means (15b) associated with said knob follower to engage a second recess (10b) in the coupling hook (10), therewith coupling the knob follower and the coupling hook together, wherein further rotation of the knob follower causes the latch bolt to be retracted by virtue of the coupling hook actuating the enlargement (24b) on the latch bolt rod. When the stop members (10e, 22e) are mutually engaged, the knob follower coupling means (15b) will pass by the coupling hook without engaging the same. The core-carried stop member (22e) is rectilinearly movable and the core does not function to move or swing the members of the lock mechanisms.

Description

soe 765 “.e - 2 between its end positions is arranged to rotate resp. displace various elements that form components of the locking mechanism itself.

Thus, in order for the arrangement to work, the anchor of the solenoid must perform a not insignificant job. This increases the risk of unsatisfactory function and shortens the service life of the door lock.

U.S. Pat. No. 3,748,878 (Balzano et al.) Discloses a lock of the type in which a force-transmitting connection between a knob and a locking piston is controllable by means of a solenoid. In this locking construction, the electrically controlled coupling means are displaceable in the direction of the rotary shaft for breaking resp. coupling of the knob and the locking piston.

DE, A, 2 151 904 (Hemmen) describes a lock of the current type in which the solenoid always switches on when switched on.

SE, B, 426 858 (FAS) describes another type of coupling means for breaking the connection with resp. engage the rower that maneuvers the plunger.

SE, B, 442 420 (WSO CPU-System) describes a slightly different locking construction comprising a locking piston and a pressure and an electrically actuable coupling device for the pressure. The coupling device consists of a disc whose circumference is provided with at least one tooth which cooperates with a pivotable hook supported on a bracket which is connected to the electrical actuator, so that it can be pivoted in resp. out of engagement with the tooth. This arrangement has essentially the same disadvantages as the above-mentioned Finnish publication.

DE, C1,38 17 696 (Meyers & Meister) describes a mechanical combination lock comprising a coupling system with a rotatable or rotatable drive disc, especially intended for safes and safes. The disc has a recess in which a mounting element ("Einfallhebel") connected to a control piston and attached to a hook member can be included, as an electromagnet-actuated locking element allows this. The locking element is movable perpendicular to the plane of travel of the drive plate and the mounting element. When the attachment element is in engagement with the disc, rotation thereof causes the locking piston of the lock to be pulled to its release position.

Adjacent to the drive disc are with this parallel code discs which are also provided with recesses.

This type of combination lock differs from such door locks for villas, flats and premises provided with a drop piston and a bange where the drop piston is actuated by two separate mechanisms, one of which is a cylinder lock mechanism, to which the present invention relates.

Further examples of the state of the art can be found in DE, A, 26 22 720 (Matzanke) and EP, A1, 0 315 056 (Hellmüller + Zingg).

OBJECT OF THE INVENTION - An object of the present invention is to provide a door lock of the type indicated which has a few components which cooperate reliably with each other and in which the anchors of the solenoid do not have to perform any actual work in connection with activation of necessary means to enable- resp. make it impossible to retract the plunger when the pressure rudder is actuated.

Brief description of the invention This and other objects are fulfilled by a locking device according to the invention which is of the type stated above and has the characterizing part specified in claim 1.

By using a stop element provided with a stop stop arranged for cooperation with a stop stop acted on by the solenoid anchor, the solenoid does not have to perform another operational function in connection with the pressure rudder's manipulation of the drop piston via the coupling element resp. movement out of engagement with the coupling element to avoid such manipulation than to ensure that the stop stop affected by the anchor is in resp. out of engagement with the stop on the coupling element. In other words, the solenoid tank does not have to affect anything contained in the locking mechanism itself and for the drop piston 506 765- snow 763 ',. . 4 operation by means of the pressure rudder necessary element as is the case with the prior art structures. This reduces the number of elements included in the locking mechanism at the same time as the risk of damage and the risk of downtime decreases and the reliability and service life of the lock as a whole increases.

In a preferred embodiment, the slide element can have a long hole, in which a pin is included for controlling its displacement movement.

The stop stops themselves can have the simple shape of stop lugs whose engagement direction is perpendicular to the direction of movement of the slide element. It will be appreciated that the work that the solenoid armature needs to perform to displace a slide member of this simple structure together with the associated stop lug to or from its engaging position with the stop lug of the coupling element is the least possible. The displacement in either direction in connection with the current to the solenoid is closed suitably against the action of a spring, which means that the slide element and the stop lug, affected by the spring, return to the original position when the current to the solenoid is interrupted.

In a preferred embodiment in practice, the coupling element has the form of a hook element with two adjacent recesses for alternative engagement of a coupling member connected to the pressure rudder, e.g. a pin running parallel to the pivot axis of the rudder.

With this design of the coupling element, a simple and compact construction is obtained at the same time as the engagement of the pressure rudder against the coupling element is facilitated.

In practice, it is further preferred that the pivot shaft of the coupling element is accommodated in a long hole therein, so that the coupling element upon engagement of the coupling member in one of said recesses is both pivotally and slidably arranged on the pivot shaft. - '506 763 5.

This possibility of combined pivoting and displacing movement of the coupling element conditions the special function of the invention to allow free passage of the pressure rudder when the two stop stops engage with each other while, when this is not the case, initial movement of the pressure rudder causes the coupling element to pivot about its pivot axis so that the pressure rudder can by means of said coupling means engage in said second recess for reliable connection of the pressure rudder and the coupling element. The continued oscillating movement of the pressure rudder then causes both oscillation and displacement of the coupling element relative to its axis of rotation and retraction of the drop piston to its release position by engaging the coupling element against the bang of the drop rule piston or an element arranged next to it.

The coupling element is preferably actuated by a spring which, when the stop lugs are not engaged, causes the initial rotation of the coupling element so that the coupling means of the pressure rudder can engage in said second recess on the coupling element.

An embodiment of the invention will be described in more detail below with reference to the accompanying drawings.

Brief description of the drawing figures All drawing figures 1-4 are plan views of a drop rule lock according to the invention, the various figures schematically showing plan views of the lock housing with the lid removed and accommodating the various locking mechanisms. The pressure row actuating mechanism of the drop piston is then shown in different positions, Figs. 1-3 showing the engagement of the pressure row mechanism and retraction of the drop piston while Fig. 4 shows the disengaged pressure row. The different figures show in more detail: Fig. 1 shows the initial position of the clutch hook at disengaged stop stops and before the pivoting movement of the pressure rudder is started. 506 765 "f l \ 6 Fig. 2 shows the position of the coupling hook after initial pivoting thereof and the pressure rudder so that coupling engagement between the two elements is effected.

Fig. 3 shows the position when the pressure movement is completed and the plunger is retracted.

Fig. 4, finally, illustrates the stop stops in engagement, the coupling hook remaining in the initial position and free passage of the pressure rudder arm being allowed.

Description of the preferred embodiment The drop bolt lock shown in the drawings consists of a lock housing 1 provided with a locking post 2 which receives partly a control piston 6 with associated locking mechanism represented by a cylinder rudder 4 with a tooth segment 4a in engagement with a tooth segment 5 which via a pin 8 in a recess 6a in the control piston 6 causes its displacement to and from the locking position when turning the key (not shown) in an associated cylinder lock (not shown). A locking arm 7 also cooperates with the locking mechanism of the control piston, which in the manner described below cooperates with the second piston of the door lock, namely the drop piston 24, which is usually provided with a piston rod 24a and a bange 24b. It is actuated by a spring 25. In the area of the bang 24b, the piston rod 24a is surrounded by a washer 9.

For maneuvering the drop piston 24, there is in the usual way a pressure rudder 15 with a pressure rudder arm 15a and a pressure rudder hub 16. The pressure rudder is pivotable about a shaft 15c.

The pressure rudder can be affected in the usual way by a pressure, a knob or the like (not shown).

The pressure rudder arm 15a acts on the bange 24b of the drop piston 24 via a coupling element which in the embodiment shown has the shape of a coupling hook 10 which is provided with two adjacent recesses 10a and 10b which in the manner described below cooperate with a coupling member in the form of a pin 15b on pressure rudder arm l5a. The clutch hook is further provided with a long hole 10d which receives a pivot shaft 10c and more specifically so that the clutch hook 10 is both pivotable on and displaceable relative to said shaft 10c. The coupling hook 10 also has a stop stop 10e, the function of which will be described in more detail below. It is further actuated by a spring 23 which tends to pivot the clutch hook 10 clockwise about the pivot axis 10c. 17 denotes a spring against the action of which the pressure rudder 15 is pivoted clockwise around the hub 15c. Denoted by 20 is a bracket for a solenoid 21 which is provided with an anchor 21a which cooperates with a slide element 22 provided with a long hole 22a which receives a pin 22b so that the slide element is guided for rectilinear movement. The slide element accommodates a stop stop 22e arranged for cooperation with the stop stop 10e on the hook element 10 (cf. below). The armature 21a is actuated in the outward direction by a spring 19, i.e. to the position in which the stop stop 10e * of the hook element 10 and the stop stop 22e of the slide element 22 engage with each other.

The solenoid 21 is energized by means of a connector 14 located outside the lock housing, the electrical arrangement inside the lock housing including a protective diode 18.

The piston mechanism also includes a locking case 26 with a pin guard 27 and a pawl 11 actuated by a spring 28.

The arrangement prevents the return of the drop piston 24 from locking to release position e.g. by means of a screwdriver or the like inserted in the door slot. The interlocking cases 26 are actuated by a spring 29. For the action of the gear segment 5 there is a spring 30.

The latch 11 is further arranged for co-operation with a microswitch 12 accommodated in the lock housing, whereby electrical indication of the locking position can be provided. Coupling of the pressure rudder 15 with the coupling hook 10 for displacing the drop piston 24 to the release position by influencing the pressure will now be explained with reference to Figs. 1-3. The said connection presupposes that the stop stop 10e of the coupling hook is out of engagement with the stop stop 22e on that of the anchor 507 765 of the solenoid 21. The slide element 22 connected to the slide member 22 which in the embodiment shown is produced by actuating the connector 14 outside the lock housing for power supply to the solenoid 21, the solenoid armature 21a being attracted against the action of the spring 19. The pressure rudder arm 15a coupling means, i.e. the pin 15b engages thereby in the recess 10a in the coupling hook 10 which is then held by the pressure rudder arm 15a in the position shown in Fig. 1. The influence of the pressure not shown causes the pressure rudder and thus the rudder arm 15a to pivot to the position shown in Fig. 2, i.e. the pin 15b leaves the recess 10a and is included in the recess 10b in the coupling hook which simultaneously turns clockwise affected by the spring 23. Coupling hook 10 and pressure rudder 15 assumes a coupled position, which means that continued pivoting of the pressure rudder 15 to the position shown in Fig. 3 causes further pivoting of the coupling hook 10 about the shaft 10a at the same time as the coupling hook is displaced relative to said pivot shaft 10a accommodated in the long hole 10d. During this movement, the coupling hook engages against the washer 9 abutting against the bang 24b, whereby the drop piston 24 is moved to the retracted position.

If the pressure is released, all elements return to the position shown in Fig. 1 under the influence of the rudder spring 17.

Fig. 4 illustrates what happens if the current from the connector 14 to the solenoid is interrupted and the pressure is affected. Under the action of the spring 19, the anchor 21a is pushed to the right in the figure, which results in a corresponding rectilinear displacement of the slide element 22. As can be seen from Fig. 4, the stop stop 10e of the coupling hook 10 engages with the stop stop 22e of the slide element 22, which means is prevented from swinging clockwise under the action of the spring 23 when the pressure is actuated so that the pressure rudder is swung clockwise. Instead, the pressure rudder arm 15a with the pin 15b passes under the hook part 10f of the coupling hook 10, ie the drop piston remains locked in the occupied locking position.

It appears from this that the anchors of the solenoid do not contribute to the oscillation or displacement of any of the locking mechanism itself or to the connection of vital components included in the locking mechanism; the sole task of the solenoid armature is to provide a rectilinear displacement of the slide element 22 provided with the stop stop 22e from its one to its other end position, in which the coupling elements 10e and 22e stand respectively. do not interfere with each other.

The return of the armature when the current to the solenoid is interrupted takes place by the action of the spring 19.

Of course, the activation direction of the solenoid can instead be the opposite, ie so that the stop stops are moved out of the engaged position when the current to the solenoid is interrupted. Other design of constituent components is also possible within the scope of the inventive idea as expressed in the appended claims.

Claims (6)

'soe 765' ._ - 10 Patentkrav Door lock with a locking housing (1) which receives a falling piston (24) provided with a piston rod (24a) and a bang (24b) movable against the action of a spring (25) from a locking position to a release position, which can be actuated by different mechanisms located on the sides of the piston in the lock housing, namely a key-actuated cylinder mechanism with a rudder (4) which via additional functional elements (eg 5, 7) acts on the piston so that it is moved to its release position during key rotation, and on the other hand a by means of a pressure, knob or corresponding rotatable pressure rudder (15), which so cooperates with a coupling element (10) pivotable about a shaft (10c) that in a position of the coupling element (10) causes the pivoting movement of the pressure rudder to retract the piston (24) to its release position and in another position of the coupling element, the piston remains unaffected by the movement of the rudder, and which coupling element (10) also cooperates with an anchor (21a) accommodated in the lock housing, which, depending on its int The position of the coupling element (10) assumes one or the other pivoting position, characterized in that the coupling element (10) and the armature (21a) of the solenoid (21) have a cooperating, cooperating plane parallel to the plane of movement of the drop piston (24). stop stops (10e, 22e) which in mutual engagement hold the coupling element in a position unaffected by the pressure rudder (15) during its pivoting movement, that the anchor stop stops (22e) are arranged on an element, e.g. a slide element (22), which is substantially rectilinearly movable between two end positions in said plane, and that, when the stop stop (22e) affected by the armature, after movement in said plane, is out of engagement with the stop stop (10e) of the coupling element, the pivoting of the pressure rudder (15) causes it to be coupled to the coupling element (10) and, in the event of further pivoting of the pressure rudder, retraction of the plunger (24) by the coupling element directly or indirectly influencing the bangs (24b) of the plunger. - åsoe 763 11 Door lock according to claim 1, characterized in that the slide element (22) has a long hole (22a) in which a pin (22b) is included for controlling its displacement movement. Door lock according to one of the preceding claims, characterized in that the coupling element has the shape of a hook element (10) with two adjacent recesses (10a, 10b) for alternative engagement of a coupling member connected to the pressure rudder (15), e.g. a pin (l5b), which runs parallel to the pivot axis (15c) of the rudder. Door lock according to claim 3, characterized in that the pivot axis (10c) of the coupling element (10) is received in a long hole (10d) therein, so that the coupling element (10) upon engagement of the coupling member (15b) in one of said recesses (10a, 10b) is both pivotable on and displaceable relative to the pivot axis (10c). Door lock according to claim 4, characterized in that pivoting of the pressure rudder (15), when the stop stops (10e, 22e) are out of engagement, causes pivoting of the coupling element (10), engagement of the coupling member (15b) in the second recess ( 10b) in the coupling element (10), continued pivoting and displacement of the coupling element relative to its pivot axis (10c) and retraction of the drop piston (24) by engaging its bange (24b) or an element (9) arranged next to it. Door lock according to claim 5, characterized in that the coupling element is actuated by a spring (23) for the element's pivoting clockwise about the axis (10c).