The present invention relates generally to an electromechanical lock device and then particularly to a lock device in which an electrically or electromechanically actuated latch mechanism is spring biased for improved security and better performance.
Electromechanical lock devices that include an electrically co-acting or controlled release mechanism for manoeuvring a lock cylinder are known to the art. Such lock devices are described in for example U.S. Pat. No. 5,839,307 and the Swedish patent SE 9904771-4. It is there described how an actuator is rotated by means of an electric motor. The actuator in turn permits or prevents the movement of a side bar. A way to manipulate such a latch mechanism is to try to hammer on the lock or in another way try to rotate the actuator to the release position.
The European patent publication EP 1 134 335 A2 describes a lock device, wherein a spring is used for mechanically returning an actuator to a latching position. This design is shown in
An object of the present invention is to provide a lock device of the above kind in which the electrically controlled latch mechanism exhibits higher security as well as better performance than known devices and which also is easier to assemble.
The invention is based on the insight that a spring acting on an actuator can be provided with two legs, which abut either side of an abutment portion of the actuator.
Accordingly, the invention provides a lock device according to claim 1.
One advantage afforded by the inventive lock device is that the damping spring prevents overshoots during rapid rotation of the actuator. This can thereby be rotated more quickly between its end positions. Since the two legs of the damping spring all the time abut the abutment portion of the actuator, manipulation of the latch mechanism is made more difficult to achieve by means of hammering or the like. Self balancing is achieved by two legs abutting the abutment portion of the actuator. This has several advantages. Firstly, the damping spring can be easily assembled without any fixation in the core. Furthermore, the balancing ensures that a predetermined force is applied on the neck portion, which increases accuracy and therewith performance.
The invention will now be described by way of example and with reference to the accompanying drawings, in which
a and 3b illustrate in detail a latch mechanism that comprises a side bar, an actuator, a motor, a pivotal pin, and a damping spring included in a lock device according to the present invention;
a and 4b illustrate in detail the pivotal pin shown in
a and 5b illustrate in detail the actuator shown in
a-d illustrate different end views of the actuator and the damping spring in different rotational positions of the actuator;
a-c illustrates top views of the latch mechanism shown in
There follows a detailed description of preferred embodiments of the invention.
The function or modus operandi of the tumbler pins is ignored throughout the entire description, and it is assumed and an appropriately profiled key has been inserted in the lock. When it is said, for instance, that the core is blocked or latched it is meant that the core is blocked by the electrically controlled latch mechanism.
The core also includes a generally cylindrical actuator 30 which can be rotated by means of a motor 40. The motor is connected to an electronic module 48 by means of two conductors 42a, 42b. These conductors are intended to extend in a groove in the barrel surface of the core. In addition to a custom-made micro-regulating unit with associated memories for storing and executing software together with drive circuits for driving the motor 40 etc, the electronic module also includes a key contact 44 in the form of an electrically conductive metal strip which is intended to make mechanical contact with a key inserted in the key channel 12. This enables the key and the electronic module to exchange electrical energy and data. Thus, a battery powering the motor 40 and the electronic module 48 can be placed either in the lock device or in the key. A damping spring 46 is provided radially inwards of the motor for damping rotation of the motor 40.
Rotation of the actuator 30 can also be influenced by a pivotal pin 50 which has a rotational axle that extends generally at right angles to the rotational axis of the actuator. The pivotal pin is disposed in a channel 16 (not shown) that extends up to the key way 12
The side bar 20, the actuator 30 and the motor 40 with associated components, such as the damping spring 46, are disposed in a recess 10a in the barrel surface of the core and are held in place by a cover 18. Correspondingly, the electronic module 48 is disposed in a recess in the barrel surface of the core opposite the recess 10a.
The latch mechanism comprising the side bar 20, the actuator 30, the motor 40, the damping spring 46, and the pivotal pin 50 will now be described in detail with reference to
The barrel surface of the actuator 30 is generally cylindrical in shape and includes a longitudinally extending recess 30a which is intended to accommodate a part of the side bar 20 when the actuator is located in a release position. The barrel surface of the actuator also includes a recess 30b which extends around the midway portion of the actuator through an angle of about 225 degrees, as shown in
The interaction between the actuator 30 and the damping spring 46 will now be explained with reference to
The leg portions 46d, 46e extend mutually parallel to each other.
The leg portions 46d, 46e squeeze the neck portion 30c of the actuator, which is provided with a varying radius, see
The leg portions 46d, 46e always abut radially opposite surfaces of the neck portion 30c of the actuator. They thereby exert equally large but oppositely directed forces on the neck portion 30c of the actuator, whereby self-balancing is achieved. This entails several advantages. Firstly, the damping spring can be assembled without any fixation in the core. It is sufficient that it is simply placed radially inside of the motor 40 like in the illustrated example and thereby is kept in place. It thus provides for easy assembly. Furthermore, the balancing ensures that a predetermined force is exerted on the neck portion, increasing accuracy and thereby performance.
The long sides 46a, 46b of the spring are preferably made as long as possible in order to obtain good dynamics for the spring. In the present example they have a length which essentially corresponds to the length of the motor 40, approximately 10 millimetres.
The function of the shape of the neck portion will now be described with reference to
Besides functioning as a protection against manipulation, the damping spring also functions to dampen overshoots during rapid change of the rotational position of the actuator. In order to avoid delays in the locking function, as short rotation time as possible is desired for rotation of the actuator between the release position in
In an alternative embodiment shown in
A damping spring 146 corresponding to the above described spring 46 abuts the shaft interconnecting motor and actuator, wherein the shaft is considered to be part of the actuator. This damping spring thus has the same general shape as in the first embodiment. The function thereof is also to dampen the movement of the motor shaft and to make manipulation more difficult, although the motor shaft undergoes only linear movement and no rotational movement. The motor shaft can be provided with varying diameter in the longitudinal direction if so desired.
A pivotal pin 150 corresponding to the pin of the first embodiment is provided for mechanical movement of the actuator during removal of the key from the lock device. It is thus provided with a tap 150a or other means making it possible to influence by means of a key inserted into the lock device. It is also spring biased by means of a spring (not shown). During turning of the pivotal pin, see
Preferred embodiments of a lock device according to the invention have been described above. The person skilled in the art realizes that these can be varied within the scope of the appended claims.
The electric operation of the actuator to its latching position has been described as a 90 degrees rotation. It will be appreciated that other degrees also are feasible as long as the recess 30a for the side bar is not exactly facing the side bar.
It will be appreciated that the abutment portion that is defined by the neck portion of the actuator can have a different shape or place on the actuator.
It will be appreciated that, although a combination of an electrically controlled latch mechanism and conventional tumbler pins has been shown, the inventive idea is also applicable to lock devices lacking other latching than the described latching mechanism.
The damping spring 46 has been described with a specific shape. It will be appreciated that this spring can have a different shape as long as the spring exhibits two mutually parallel leg portions abutting radially opposite surfaces on the neck portion of the actuator or the shaft interconnecting the motor and actuator. The short side portion 46c can thus have a rounded shape.
Number | Date | Country | Kind |
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0500976-6 | Apr 2005 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE06/00505 | 4/27/2006 | WO | 00 | 1/16/2008 |