The present invention relates to a locking device suitable for allowing or restricting access into an area or space.
Locking devices for restricting access into an area or space are known in the art. Locking devices usually comprises one or more locking elements, such as a bolt, a bar or similar, for denying the opening of a closing element barring an opening into the area, such as a door, lid, window, hatch or similar. The position of the locking element is controlled by actuation of a lock requiring a key, key code, key signal or similar to be operated. Generally, the locking element is arranged to engage a striking arrangement, such as a strike plate, provided in for example a jamb or in another closing element for holding the closing element locked and immovable.
One example of a closing element is a sliding door which opens and closes in a sideway direction relative to the opening that it covers, and with a normally straight, linear motion. The edge of the door leaf, inside which the locking device is normally provided, thus makes contact with a striking arrangement in a door jamb or in the edge of another door leaf with a straight movement, directly towards the face of the striking arrangement. In order to allow locking of the door the locking element is therefore provided with a hook-shaped part, in order to enable engagement with the striking arrangement.
One problem with this and other locking devices is that if the closing element for some reason becomes loaded, for example by people leaning against the door in an emergency situation, the locking element may become pressed against a surface in the striking arrangement so that frictional forces blocks the locking element from moving. Hence it may become very difficult, or indeed impossible, to unlock the closing element. In electric locks, having locking elements moved by an electric motor, this problem has hitherto been addressed by providing an oversized and overly strong electric motor, in order to generate the high forces needed to overcome possibly increased friction. This in turn gives rise to problems with power supply, connectivity, and available space.
One objective of the present invention is to indicate a locking device which is simpler and/or less expensive to manufacture.
Another objective of the present invention is to indicate an improved locking device adapted to allow an automatic lock function.
Yet another objective of the present invention is to indicate a locking device allowing a safer and/or a more secure lock function.
According to one aspect of the invention one or more of these objectives are achieved with a locking device comprising a strike member arranged to strike the striking arrangement upon closing of the closing element, and to actuate a lock state control mechanism to move the locking element into an engaging position in response to the strike member hitting the striking arrangement. Hence, when closing the closing element the locking element is automatically moved towards its engaging position. Thus it is not necessary to include an electric motor specifically for moving the locking element. This in turn leads to that it is not necessary to include electric cables for a power supply to the locking device, making installation of the locking device simpler, and decreasing the risk for electric faults and fire. The mechanical lock state control mechanism further allows a faster and more efficient locking operation.
The locking device is preferably adapted to restrict access into an area or space in cooperation with at least one closing element arranged to cover an opening or entrance into said area or space. The locking device is preferably adapted to be installed in association with the closing element, more preferably inside a door leaf. Alternatively, however, the locking device may also be adapted to be installed inside an immovable object being close to the closing element and/or to the opening into the area or space, such as inside a door jamb.
A locking element may comprise a bolt, a bar, or any other rigid or solid member able to make a fixing connection between a movable closing element and an immovable object, such as a door jamb, or to another movable object, which is then likewise immobilised by the fixing connection, such as a second door in a door pair. Preferably the locking element is arranged to engage with a striking arrangement in order to make a fixing connection holding the closing element immobile. The locking element may then engage either the striking arrangement in order to hold the closing element closed. An important point is that the locking element may engage with the striking arrangement for holding the closing element closed both in a locked state, in which the closing element is fully locked and needs a key, key code or similar to open, and in an unlocked state, in which the closing element is closed but may be moved either due to an opening operation by a user or by the application of an opening force, a function which is similar to the function of a latch bolt.
In one embodiment the state controlling mechanism comprises a lever having a first lever arm connected with the strike member, and a second lever arm connected with the locking element, and which arms are pivotable around a common pivot point joining the first and the second lever arms. Preferably the lever is adapted to transfer motion between the strike member and the locking element in order to control the position of the strike element dependent on the state of the strike member. Hence an efficient mechanical connection and communication is achieved. The strike member is preferably projecting out from the locking device in order to hit the striking arrangement. Preferably the strike member is then pushed in inside the locking device by the striking arrangement when the closing element is closed. The strike member is then preferably arranged to actuate the lock state mechanism to extend the locking element into its engaging position when it is being pushed in.
In one embodiment the state controlling mechanism comprises a spring connected with and arranged to transfer forces between the first and the second lever arms. Hence the relative positions of the arms may change, giving a slack in the relative positions of, and in the motion between, the strike member and the locking element. Thus one of the strike member or the locking element may move while the other remains stationary. This gives the advantage that during opening or closing of the closing element the locking element may begin to retract before the strike member begins to be projected. This also gives the advantages of reduced tolerance demands allowing a simpler manufacturing, and also a more robust and reliable locking device. The stiffness of the spring affects the maximum force with which the strike member may push out the locking element via the lever, and also the force resisting a retraction of the locking element when opening the closing element, when the strike member is still under pressure from the striking arrangement.
In one embodiment the locking element comprises an engagement surface adapted to engage with the striking arrangement, which engagement surface is shaped to generate a force when the closing element is being opened, which force acts to move the locking element towards a non-engaging position. Preferably the locking element is then in an unlocked state. Hence the closing element may be opened automatically when the locking element is in an unlocked, but engaging, state by simply moving the closing element towards its open position. Due to that the force for moving the locking element originates from the movement of the closing element it is not necessary to arrange an electric motor inside the locking device for actuating the locking element, giving the same advantages as stated above.
Preferably, the engagement surface is also angled so as to decrease any frictional forces originating from a loading of the closing element. Hence there is less strain acting on the locking element so that it is simpler to move the locking element towards its non-engaging position and to open the closing element in case of loading of the closing element.
In one embodiment the locking device comprises a spring arranged to press the striking member towards a protruding position. Hence it is ensured that the striking member is in a protruding position when the closing element is open and the striking member is not in contact with the striking arrangement. The spring is preferably simultaneously also arranged to press the locking element towards its non-engaging state, preferably via the lock state control mechanism.
In one embodiment the locking device is shaped to be installed in association with at least one sliding door. The locking device according to the present invention is particularly suited for being associated with sliding doors, which otherwise have been difficult to provide with satisfactory locking devices. Preferably the locking element then comprises a hook-shaped part comprising an engagement surface for engagement with the striking arrangement facing back towards the locking device. Since sliding doors are opened by sliding in a direction parallel with the extension of the door, it is advantageous to provide an engagement surface facing towards the door for hindering the opening. Another advantage is that a closing element provided with the locking device may easily be opened in case of an emergency situation, so that it is no longer necessary to provide an additional emergency exit door as is currently the case.
According to one embodiment of the locking device the locking element is rotatable around a pivot point between a first, engaging position, and a second, non-engaging position. Hence the locking element may more easily move from its engaging position to its non-engaging position. In particular, the locking element may move more easily in case the closing element (or locking element) is loaded so that frictional forces are created which could hamper the movement. Also, in case of sliding doors, it is easier to provide a properly shaped and angled engagement surface.
In one embodiment the locking device comprises a blocking mechanism arranged to, in a first state, block the locking element from moving towards a non-engaging position, and to, in a second state, allow movement of the locking element towards the non-engaging position. Hence the blocking mechanism may control the locked or unlocked state of the locking element by blocking or allowing its movement from the engaging position to the non-engaging position. Thus the blocking mechanism may also determine the locked or unlocked state of the locking device as a whole. Preferably the present state of the blocking member is controlled by operation of a user, such as by use of a key, key code or similar.
The blocking mechanism further ensures that the locking device remains locked even if the locking element is subjected to a strong force in the direction of its non-engaging state. The blocking mechanism further ensures that the locking device remains locked even if the locking element is subjected to a rapid succession of sharp blows, a tampering attempt known as knocking. This in turn ensures that the inclusion of an engagement surface as stated above is not detrimental to the security of the locking device.
According to one embodiment the blocking mechanism comprises a blocking member arranged to block the locking element from moving towards its non-engaging position by being positioned and held immobile in the movement path of the locking element. The blocking member may also be positioned in a non-blocking position, in which the blocking member admits movement of the locking element towards its non-engaging position. Such a blocking member may easily be moved between its blocking and non-blocking position with but a low force, such as from a solenoid, while still being able to block high forces subjected to it by the locking element.
According to one embodiment an engagement part of the locking element adapted to engage the striking arrangement and a blocking part of the locking element adapted to be blocked by the blocking element are arranged on opposite sides of the pivot point. Hence the blocking member may be positioned close to the outer wall surface of the housing of the locking device, which is normally the most stable and durable wall surface. Thus the blocking mechanism will be more hardy, and more difficult to break.
According to another embodiment the blocking mechanism may instead be connected with and arranged to move the locking element, and may comprise a slot formed on one link and a sliding element formed on another link and arranged to slide along said slot, wherein the slot is angled so as to block motion of the sliding element, and thus of the links and of the locking element, when the locking device is locked and the locking element is pressed towards its non-engaging state.
According to another embodiment the strike member may be provided with a bevelled surface adapted to hit the striking arrangement. Hence the locking device is arranged to be suitable for use in association with a hinged door.
The invention is now to be described as a number of non-limiting examples of the invention with reference to the attached drawings.
In
The locking device comprises a locking element 9, which is solid and rigid in order to be able to make a fixing connection between the closing element and the door jamb. In this example the locking element is arranged to engage with a striking arrangement 11, in this example a strike plate, provided in the door jamb 7 in order to hold the closing element 3 closed in the closed position. The locking element 9 may thus be moved between an engaging position, shown in
The locking device further comprises a strike member 13 arranged to strike the striking arrangement upon closing of the closing element, and to actuate a lock state control mechanism 15 to move the locking element 9 into an engaging position in response to the strike member hitting the striking arrangement 11. Hence, when closing the closing element, that is, when going from the state in
In this example the lock state control mechanism comprises a lever 17 having a first lever arm 19 connected with the strike member, and a second lever arm 21 connected with the locking element, and which arms are pivotable around a common pivot point 23 joining the first and the second lever arms. The lever thus provides a mechanical connection and communication between the strike member and the locking element, and is adapted to transfer motion between the strike member and the locking element in order to control the position of the strike element 9 dependent on the state of the strike member 13. In this example the first and the second arms are arranged on opposite sides of the common pivot point 23. Thus, when the first arm is pressed in one direction, the second arm is pressed in the opposite direction, and vice versa.
The locking device comprises a housing 25 enclosing the mechanism of the locking device, and which is further provided with a front plate 27 arranged to face the striking arrangement. The strike member 13 is movable between a first position in which the strike member is arranged to project out of the front plate 27 in order to be able to strike the striking arrangement (
The state controlling mechanism 15 also comprises a spring 31 connected with and arranged to transfer forces and/or motion between the first 19 and the second 21 lever arms. Hence the relative positions of the arms may change, giving a slack in the relative positions of, and in the relative motions between, the arms and thus of the strike member and the locking element. During an opening or closing operation this allows that only one of the strike member or the locking element moves, while the other remains stationary, wherein the risk of the locking device becoming stuck due to the connection via the state controlling mechanism decreases. Otherwise, in the closed position, in which the strike member is forced into its second, pushed in, position, while the locking element is forced into its extended, engaging position, a stiff lever arm could lead to a deadlock between the locking element and the strike member.
The locking device is in this example shaped to be installed in association with a sliding door 3. A sliding door opens and closes in a sideway direction relative to the opening that it covers, and with a straight, linear motion. The front plate 27 of the locking device thus makes contact with the striking arrangement with a straight movement, directly towards the face of the striking arrangement. The locking element is provided with an engaging part 33, which in this example is hook-shaped, in order to enable a more secure engagement with the striking arrangement. The engaging part 33 is further provided with an engagement surface 35 facing towards the front plate 27 of the locking device, and thus towards the door 3, for stopping the door from opening.
The engagement surface 35 is further adapted to engage with the striking arrangement 11, and is shaped to generate a force when the closing element is being opened, which force acts to move the locking element 9 towards a non-engaging position. In this example the engagement surface 35 is angled slightly, so that when the engagement surface is pressed towards the edge of the striking arrangement, a force is generated which moves the locking element to move towards its non-engaging position. Thus the closing element may be opened automatically, at least when the locking element is in an unlocked, but engaging, state by simply moving the closing element towards its open position so that the engagement surface 35 is pressed towards the striking arrangement. The angle of the engagement surface also decreases any frictional forces originating from a loading of the closing element. Hence there is less strain acting on the locking element so that it is simpler to move the locking element towards its non-engaging position.
In this example the locking element is rotatable around a pivot point 37 between its first, engaging position, and a second, non-engaging position. Hence the locking element 9 may more easily move from its engaging position to its non-engaging position. In particular, this allows for easier movement of the locking element in case the locking element is under strain. In this example the engagement surface 35 is thus angled to generate a force which rotates the locking element to move towards its non-engaging position.
In order to allow locking of the locking element, the locking device comprises a blocking mechanism 39 arranged to, in a first state, block the locking element from moving towards its non-engaging position, and to, in a second state, allow movement of the locking element towards its non-engaging position. The blocking mechanism is preferably operator controlled, for example by a user of the lock, and actuable by the use of a key, key code, unlock signal or similar.
In this example the blocking mechanism 39 comprises a blocking member 41 arranged to block the locking element from moving towards its non-engaging position by being positioned and held immobile in the movement path of the locking element 9, as shown in
In this example the locking element further comprises a blocking part 47 of the locking element 9 adapted to be blocked by the blocking element 41. The engagement part 33 and the blocking part 47 of the locking element are arranged on opposite sides of the pivot point 37 of the locking member 9. Hence the engaging part and the blocking part will move in different directions when the locking element is rotated. The blocking part 47 is in this example arranged to move towards the inner surface of the front plate 27 when the locking element is rotated towards its non-engaging position in which the engagement part is retracted. The blocking member 41 is in this example arranged to be positionable in between the front plate and the blocking part of the locking member in its blocking state. The pivot point 37 of the locking element is then also provided at a location below the blocking member 41. Since the front plate of the housing 25 is normally thick and durable to withstand tampering attempts, the front plate provides a stable counter-stay for the blocking member. The blocking member is further arranged to bear against the inner surface of the front plate for support in its blocking position. Thus the function and reliability of the blocking member is improved.
The blocking mechanism 39 and the blocking member 41 ensures that the locking device remains locked even if the locking element is subjected to a strong force in the direction of its non-engaging state. The blocking mechanism further ensures that the locking device remains locked even if the locking element is subjected to a rapid succession of sharp blows, a tampering attempt known as knocking. This in turn ensures that the provision of an angled engagement surface as stated above is not detrimental to the security of the locking device.
In the following the operation of the locking device in conjunction with the closing element and the door jamb will be described in closer detail.
In a locked state, as shown in
In an opening operation and departing from
In a closing operation and departing from
In a locking operation the user issues a control signal to the solenoid 43 to move the blocking member 41 into its blocking position, as shown in
The invention is not intended to be limited to the examples shown but may be varied freely within the framework of the following claims.
In particular the striking arrangement need not comprise a strike plate, but may simply be a surface arranged on a movable or immovable object cooperating with the locking device, and the locking device could be provided in association with a swinging door instead of a sliding door. The strike member could then be provided with a beveled surface in order to be pushed into the locking device more easily, and the locking element could similarly be provided with an engagement surface beveled in a sideway sense. The blocking mechanism need to comprise a blocking member, but could be provided by other means as described in this application or elsewhere.
Number | Date | Country | Kind |
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1050735 | Jul 2010 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE2011/050844 | 6/27/2011 | WO | 00 | 1/3/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/005662 | 1/12/2012 | WO | A |
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