RU2164279C2 - Mechanism of electromechanical cylinder lock - Google Patents

Abstract

FIELD: locking mechanisms. SUBSTANCE: mechanism of electromechanical cylinder lock includes base member housing cylinder of lock which rotates with reference to base member while mechanism of lock is open. Latching unit functionally dependent on electronic code prevents turning of cylinder of lock relative to base member in position of latching independent of mechanism of lock mentioned above. Latching unit includes latching member turned electromechanically that is matched with guiding groove made in cylinder of lock or in rotary member. Latching member is capable of uninterrupted turning so that in turned position ensuring latching it prevents free rotary motion of cylinder of lock with regard to base member. EFFECT: given latching unit is reliable in operation and structurally uncomplicated as rectilinear motion controlled by spring is excluded. 9 cl, 5 dwg

Description

 The invention relates to a mechanism for an electromechanical cylinder lock in accordance with the preamble of paragraph 1 of the claims.

 The reliability of a cylinder lock or similar can be improved by supplying it with a blocking means, the operation of which depends on the electronic code supplied separately. Various electromechanical cylinder locks of this kind are known. Typical of most of them is that they are quite complex and require a lot of space. They can also be inconvenient for production in the case when it is required to make significant changes in the lock cylinder itself or in other elements of the lock mechanism. As examples, the solutions shown in the publications of Great Britain Application No. 2112055 A, Application No. 0281507 B1 for a European Patent, Applications No. 0381320 B1 for a European Patent and Applications for Finland No. 960903 (corresponding to PCT Application No. 96/00830) can be cited. Common to these solutions is that the movement of the blocking element, driven electrically, between the locking and tripping positions is carried out in a straight line under the control of the spring. The solutions are complex, the required volume and linear size are unrealistic, because they are determined by the operation of the spring.

 The objective of the invention is to create a new, structurally uncomplicated and reliable when working solution for blocking means, the operation of which depends on the electronic code, and for means of controlling them, in which the aforementioned disadvantages of the prior art are largely eliminated.

 The objective of the invention can be seen in the described form in paragraph 1 and in other claims. In accordance with the invention, the locking means comprises a rotatable electromechanically locking element, which is mated to a guide groove made in the lock cylinder or in the rotary element, and while being able to continuously rotate so that in the rotated position that provides the lock, it prevents the free rotational movement of the lock cylinder relative to the body part. Since the solution is based solely on the use of the rotation of the blocking element, its design can be made simple and does not take up much space.

In a better embodiment of the invention, the guide groove is located in the plane of the cross section of the lock cylinder around the lock cylinder or the pivoting member, therefore capable of continuously rotating, and contains at least one expanded portion which, in the locked position of the locking member, is in cooperation with the locking member . By supplying the guide groove with two extended sections, which are located at an angular distance of about 180 ^o from each other, the cylinder lock mechanism can be continuously rotated, with the same direction of rotation, the locking and disengaging positions are interchanged.

 In practice, the end of the blocking element located on the surface of the guide groove may have at least a substantially rectangular cross-sectional shape, such that its smallest size corresponds essentially to the width of the guide groove and its largest size corresponds to essentially the width of the expanded portion of the guide groove.

 At the end of the blocking element, located opposite to the guide groove, a permanent magnet is installed, which is in interaction with the poles of the electromagnet. To achieve a useful effect, the permanent magnet has an annular shape and is magnetized in the direction of the plane of the cross section of the axis of rotation of the blocking element. Therefore, the blocking element can be made structurally uncomplicated, compact object. The ring shape is also advantageous because in this case the magnetic field of the electromagnet contributes to the rotation of the blocking element as efficiently as possible.

The rotation of the blocking element is provided by changing the polarity of the electromagnet. As a result of this, the reciprocating movement can occur between the locking and disengaging positions. Therefore, the mechanism includes restrictive elements of 90 ^o , set to limit the rotation of the blocking element, made reciprocating between the positions of disengagement and blocking. Therefore, in the absence of other controls, the blocking element is stable in each of the extreme positions (bistable), since the poles of the permanent magnet oppose the poles of the electromagnet, which are made, for example, of magnetic iron and which are respectively located in elements elongated diametrically opposite on either side of the blocking item. In addition, only a short control pulse, for example, 40 ms in duration, is required to rotate the blocking element, which corresponds well to the battery mode.

 The blocking element and the electromagnet causing it to rotate are advantageously located in a separate assembly located at the end of the lock cylinder and attached together with the lock body part, preferably by means of common screws, to any particular installation object. In this case, there is no need to change the lock cylinder or the lock mechanism, which is advantageous from the point of view of production technology.

 The locking mechanism with the achievement of the useful effect of the mechanism is made in the form of a cylinder mechanism of the castle, equipped with rotary locking discs.

The invention is described below by way of example with reference to the drawings, in which:
FIG. 1 is a general view of a locking assembly in which an embodiment of the mechanism of an electromechanical cylinder lock is used;
FIG. 2 is a solution for blocking means included in the mechanism of FIG. 1, partially in section;
FIG. 3 is a section according to III-III of FIG. 2;
FIG. 4 is a section with an increase in IV-IV of FIG. 2;
FIG. 5 reflects the principle of operation of the electromagnetic blocking means according to the invention.

 In the drawing, number 1 shows a cylinder lock included in the locking device and operating in a known manner using the key rod 2a 2. In the shown construction, the cylinder lock 1 interacts with the lock case 3 located in the door or in a similar product to move the lock bolt 3a, placed in it. The cylinder lock incorporates a housing 1a of the mechanism and a cylinder 1b of the lock located rotatably inside it. A real locking mechanism can be made on the basis of several well-known solutions, for example, on the basis of a cylinder lock mechanism equipped with rotary locking discs, as shown in US Pat. No. 4,211,097, and therefore the mechanism will not be described in more detail here.

 The locking device is additionally equipped with an electronic unit 5, electrically controlled by a locking means 16, which, in the embodiment shown in the drawings, is located in a separate blocking means unit 4 located between the cylinder lock 1 and the object to be locked which interacts with it, which in this case is case 3 locks located in the door. The operation of the locking means 16 is independent of the locking mechanism of the cylinder lock 1, and in the locked position it prevents the transmission of force from the key 2 through the cylinder lock 1 to the lock bolt 3a. The operation of the locking means 16 depends on the electronic code stored in the memory circuit 2b located in the key and supplied or read from the key. For this purpose, the locking device is provided with antenna means 7, which can operate in a known manner, for example by induction.

 As a power source for the locking device, you can use any source that is suitable for this purpose, such as a mains or battery (not shown). The locking device is preferably provided, especially when the battery is used as a power source, with a current switching means 6, which supplies current to the electronic unit 5 only if the key is inserted in the lock 1, thereby prolonging the useful time of the battery.

 After inserting the key 2 into the lock 1 and connecting the means 6 for switching the current of the circuits of the electronic unit 5 to the power source, the electronic code is fed and / or read using the antenna means 7. If the code is correct, the electronic unit 5 forces the locking means 16 to move to the disengaged position, after which the lock bolt 3a can be moved with the key 2. The locking device is also equipped with a safety device 8 installed in a known manner, which protects the parts 1, 4, 6 and 7 from an attempt to break in from the outside.

 In FIG. 2-5, the construction of the blocking means assembly 4 is shown in more detail and the principles of the blocking means are reflected. The transmission of force from the cylinder lock 1 to the node 4 occurs using a rotary element 9 connected to the cylinder 1b of the castle and continuously transmitting its rotational movement. The transfer of force from the rotary element 9 to the housing 3 of the lock can occur using a flat rotating element (not shown) of a known type. In addition, the design includes a locking element 10, holding both the rotary element 9, and the specified rotating element in their places in the node 4.

 The blocking assembly 4 is equipped with an electromagnet containing a coil 11 and poles 12a and 12b of magnetic material, a circuit board 14 with a Hall sensor and wiring 15 to the electronic unit 5, as well as a blocking element 16. The blocking element 16 is equipped with a rectangular head 16b located in interacting with the guide groove 17 and two widened portions 17a and 17b therein formed in the pivoting member 9. When the head 16b of the locking member 16 is transverse to any one of the expanded portions 17a and 17b, as shown in FIG. 2 and 3, there is no space for its movement in the guide groove 17, and it prevents the rotation of the rotary element 9 relative to the node 4 and at the same time, therefore, the rotation of the lock cylinder 1b relative to the housing 1a of the mechanism.

The other end of the blocking element 16 is provided with a permanent magnet 16a, which interacts with the poles 12a and 12b of the electromagnet in the manner shown in FIG. 4 and 5, as a result of which its rotation is limited by elements 13 to 90 ^o . The operation of the blocking element 16 is controlled by the electronic unit 5 and the electronic code supplied to the unit from the key 2. When the correct code is received, the electronic unit 5 controls the electromagnet so that its polarity is reversed, as a result of which the blocking element 16 is rotated 90 ^° from the indicated lock position. Then, the head 16b of the locking element 16 enters completely into the guide groove 17 and allows rotation of the pivoting element 9 and, therefore, the transmission of force from the key through the lock cylinder 1b to the lock bolt 3a.

 Since the permanent magnet 16a of the blocking element 16 tends to move to one of the final positions, based on the polarity set at each moment of time, its state in each case will be stable. When the poles 12a and 12b are arranged as shown, i.e. sequentially in the direction of insertion of the key, it is impossible to expose the blocking element 16 to the influence of a magnetic field outside the door with the aim of its rotation. Due to the annular shape of the permanent magnet 16a, the blocking element 16 can rotate in the magnetic field of the electromagnet as efficiently as possible.

 The blocking unit assembly 4 is further provided with holes 18, which can be used for mounting the assembly 4 by means of screws (not shown) to the lock housing and to the door together with the cylinder lock and, possibly, also with the protective device 8.

 The implementation of the invention does not depend on the used cylinder lock mechanism, as well as on the method used to transfer the code from the key memory circuit to the electronic unit for the purpose of its control.

 Therefore, the invention is not limited to the embodiment shown, and several modifications are possible within the scope of the accompanying claims.

Claims (10)

 1. The mechanism of an electromechanical cylinder lock, comprising a housing part of the lock and inside it a lock cylinder, which in the open state of the lock mechanism is rotatable relative to the housing part, and locking means, functionally dependent on the electronic code and which in the locked position is configured to create an obstacle the rotation of the lock cylinder relative to the housing part, regardless of the specified lock mechanism, characterized in that the said locking means comprises a turn electromechanically lockable element that is interfaced with a guide groove made in the lock cylinder or in the rotary element, and is made with the possibility of continuous rotation so that in the rotated position that provides locking, it has the ability to prevent the free rotational movement of the lock cylinder relative to the body part .  2. The mechanism of the cylinder lock according to claim 1, characterized in that the guide groove is located in the plane of the cross section of the cylinder of the castle, around the cylinder of the castle or the rotary element, therefore made with the possibility of continuous rotation, and contains at least one extended section, which the locked position of the blocking element is configured to interact with the blocking element. 3. The mechanism of the cylinder lock according to claim 2, characterized in that the guide groove contains two extended sections, which are located at an angular distance of 180 ^o from each other.  4. The mechanism of the cylinder lock according to any one of the preceding paragraphs, characterized in that the end of the blocking element located on the surface of the guide groove has a substantially rectangular cross-sectional shape such that its smallest size corresponds essentially to the width of the guide groove , and its largest size corresponds essentially to the width of the expanded portion of the guide groove.  5. The cylinder lock mechanism according to any one of the preceding paragraphs, characterized in that the end of the blocking element, located opposite to the guide groove, is equipped with a permanent magnet, which is in interaction with the poles of the electromagnet, respectively located on opposite sides of the permanent magnet of the blocking element in the elements, elongated diametrically opposite on opposite sides from the axis of rotation of the blocking element.  6. The cylinder lock mechanism according to claim 5, characterized in that the permanent magnet has an annular shape and is magnetized in the direction of the plane of the cross section of the axis of rotation of the blocking element.  7. The mechanism of the cylinder lock according to any one of the preceding paragraphs, characterized in that the rotation of the blocking element is provided by changing the polarity of the electromagnet. 8. The mechanism of the cylinder lock according to any one of the preceding paragraphs, characterized in that the mechanism includes restrictive elements set to limit the rotation of the blocking element to approximately 90 ^o , made reciprocating between the disengagement and locking positions.  9. The mechanism of the cylinder lock according to any one of the preceding paragraphs, characterized in that the blocking element and the electromagnet causing it to rotate are located in a separate assembly located at the end of the lock cylinder and attached together with the lock body part, preferably by means of common screws, to each specific installation object .  10. The mechanism of the cylinder lock according to any one of the preceding paragraphs, characterized in that the locking mechanism is made in the form of a cylinder mechanism of the castle, equipped with rotary locking discs.

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