RU2194836C2 - Method for unlocking of electromechanical code lock - Google Patents

Abstract

FIELD: prevention of access of strangers to a room with the aid of an electromechanical code lock. SUBSTANCE: the lock has a closing cross-bar installed in the casing and linked with a mechanism for its movement and a means for its interlocking. The mechanism for movement of the closing cross-bar has a rotary sleeve with a spring-loaded cam. The interlocking means has an electromagnet with a spring-loaded armature. The cam is engageable with the spring-loaded armature and the cross-bar stop. The closing cross-bar is unlocked by displacement of the armature with the aid of the mechanism for movement of the locking cross-bar to the position in which the cross-bar is unlocked. In this position the armature is held due to supply of voltage to the electromagnet during a time period required for displacement of the cross-bar to the extreme position in which the lock is open. EFFECT: enhanced reliability of the lock against an unauthorized access to the room. 8 dwg

Description

 The invention relates to secret locks, and more specifically to a method for unlocking electromechanical combination locks.

 A known method of unlocking an electromechanical combination lock, including unlocking the locking bolt with moving it through the movement mechanism until the lock is completely unlocked when the locking bolt is locked in the form of an electromagnet anchor (RU 2098587 C1, 10.12.97).

 The known method of unlocking the lock does not provide sufficient reliability to limit access to the premises of unauthorized persons.

 The technical result achieved by the implementation of this invention is to increase the reliability of the castle against unauthorized entry into the room.

 The specified technical result is achieved by the fact that in the method of unlocking the electromechanical combination lock, including unlocking the locking bolt with moving it through the unlocking mechanism when the locking bolt is locked in the form of an electromagnet armature, according to the invention, the locking bolt is unlocked by moving the anchor using the mechanism of movement of the bolt to a position in which the locking bolt is unlocked, followed by holding the anchor in om position by energization of an electromagnet for a time interval required to move the locking bolt in the end position, wherein the lock is open.

 This method can be implemented in the electromechanical combination lock shown in the drawing, where Fig.1, 2 shows a General view of the lock in its original position; figure 3, 4 is a General view of the lock when unlocked locking bolt; figure 5, 6 is a General view of the castle with a locked locking bolt; in FIG. 7 is a general view of the lock with a portable control device; on Fig - portable control device.

 The electromechanical combination lock comprises a housing 1, a locking bolt 2 mounted in the housing and provided with a stop 3, in which the compression spring 4 constantly abuts. A mechanism for moving the locking bolt is installed in the housing, including a rotatable sleeve 5 fixed in the housing and placed in the groove 6 of the bolt 2. The cross section of the axial hole 7 of the sleeve 5 has any shape that has at least one angle, protrusion or recess in the cross section. A spring-loaded cam 8 is rigidly mounted on the sleeve 5, the return spring 9 of which is located on the sleeve 5, while one end of the spring 9 abuts against the wall of the housing, and its other end - into the cam 8.

An electromagnet 10 with a spring-loaded anchor 11, which is located under the locking bolt 2 at a distance l ₁ from it, is also located in the lock case. The spring 12 of the anchor 11 is fixed at one end in the housing, and the other at the anchor. A microcircuit is an electromagnet 10, which is a code recognition device 13 and is housed in an enclosure.

The ratio of the length l _{2 of the} armature 11 and the total length l _{3 of the} electromagnet 10 is selected within 0.1 <l ₂ / l ₃ <2, and the distance l _{1 is} selected with respect to the length l _{2 of the} armature 11 within 0.03 <l ₁ / l ₂ <0.3 and with respect to the minimum size l _{4 of} the fixation zone of the bolt holding element 2 in the locked state within 1.001 <l ₁ / l ₄ <5. The minimum value of the ratio of the length l _{2 of the} armature 11 to the length l _{3 of the} electromagnet is determined by the fact that if the length l _{2 of the} armature 11 is less than 0.1, the design of the lock is complicated and the reliability of holding the armature 11 in the closed position will decrease. When increasing the length l ₂ to a length close to the value 10 l ₃ , there is a need for a significant increase in effort and, accordingly, power and size of the electromagnet, which is difficult to make in a limited amount of lock space.

The distance l ₁ , by which the second working end of the armature is moved, is selected within the limits of not more than 0.03l ₂ -0.3l _{2 of} the armature length, because a value of less than 0.03l ₂ will not provide reliable retention of the crossbar 2, and more than 0.3l ₂ will lead to an unjustified increase in the dimensions of the lock.

The choice of the ratio of the distance l _{1 of the} movement of the second working end of the anchor to the minimum size l _{4 of} the fixation zone of the bolt holding element in the range from 0.001 to 5 is determined by the fact that the minimum limit will increase the compactness of the lock and the duration of the battery operation, and the maximum limit is selected based on the possibility at the initial moment of unlocking the lock, lead the anchor out of the bolt fixation zone by the mechanical force of the bolt moving unit.

 The lock also contains a portable device 14 (Fig.7, 8) control with an autonomous power source (not shown). The device 14 has a control panel with buttons 15 for entering the code and coaxial contacts 16 and 17 separated by an insulating gasket 18. The central contact 16 has an end section 19 of a shaped section similar to that of the axial hole 7 of the rotary sleeve 5. On both sides of the door 20 Coaxial sockets 21 are installed coaxially with the opening 7 of the rotary sleeve 5, insulators 22 and 23 are pressed into the internal cavity of each of them with pins 24 and 25 integrated between them and connected to the code recognition device 13. The groove 26 serves to better fix the device 14 in the contact socket 21.

 A method of unlocking an electromechanical combination lock is as follows.

 The position of the anchor 11 and the movement mechanism of the locking bolt 2 with the closed position of the lock is shown in figure 1. Before inserting the portable control device 14 into the contact slot 21 of the locked door, it is necessary to press the buttons 15 corresponding to the programmed code combination. After that, the device 14 is fully inserted into the contact socket 21 (the orientation of the device 14 with respect to the axis of rotation does not matter) so that the final section 19 of the central contact 16 of the square section engages with a rotary sleeve 5 having an inner surface of the same profile, the coaxial contacts 16 and 17 make electrical contact with the contacts 24 and 25 connected to the code recognition device 13.

 If the code is dialed correctly, then after some time (0.2 s), an audio or light signal will be given from the signal device (not shown) built into the device 14. This signal means that the programmed and dialed codes are identical and a voltage is applied to the electromagnet 10 from the code recognition device 13. In this case, when the device 14 is rotated, the rotary sleeve 5 together with the cam 8 starts to rotate in the direction indicated by arrow A, and the armature 11 is held in the “unlocked” position by supplying voltage to the electromagnet 10, which allows the bolt 2 to move freely for the time required person to fully open the door 20. With a further rotation of the device 14, the cam 8 rests against the stop 3 of the bolt 2, presses on it, compressing the spring 4, while the bolt 2 is completely retracted into the lock housing 1 and the lock is unlocked.

 Coaxial contacts 16 and 17 during the entire rotation time of the device 14 are in electrical contact with the contacts 24 and 25, thereby providing continuous power to the lock from a source located in the housing of the device 14.

 After the device 14 is removed from the contact slot 21, the rotary sleeve 5 with the cam 8 under the action of the return spring 9 and the bolt 2 under the action of the spring 4 will return to their original position and the door can be slammed.

 If the code is not dialed or typed incorrectly, then in this case it will also be possible to rotate the sleeve 5 (figure 5) together with the cam 8, but the voltage to the electromagnet 10 is not applied and the armature 11 under the action of the spring 12 will move to the "locked" position , resting against the end wall of the crossbar 2, thereby preventing its movement, and hence the unlocking of the lock.

 When unlocking the electromechanical combination lock, the locking bolt 2 is unlocked by moving the armature 11 to a position that allows the bolt 2 to move freely using a mechanism containing a rotary sleeve 5 with a spring-loaded cam 8. In this case, the anchor 11 is held in the “unlocked” position for a time interval, necessary to move the crossbar 2 to the extreme position at which the lock is open, by applying voltage to the electromagnet 10.

Claims (1)

 A method for unlocking an electromechanical combination lock, including unlocking the locking bolt with moving it through the movement mechanism until the lock is completely unlocked when the locking bolt is locked in the form of an electromagnet anchor, characterized in that the locking bolt is unlocked by moving the anchor using the bolt movement mechanism to a position in which the locking bolt is unlocked, with the subsequent holding of the armature in this position by applying voltage to the electromagnet in during the time interval required to move the locking bolt to the extreme position at which the lock is open.

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