RU2702390C2 - Electromechanical cylinder lock - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to electromechanical locks, and more specifically to secret locks with electronic coding method. Technical result of invention is achieved by using locking mechanism, which consists of hole 12, made on shaft 4, through hole 13, made in rotary sleeve 5, with ball placed in it, having freedom of movement along axis of this hole, and hole 14 made in housing 1. To open the lock it is necessary to supply voltage to the electromagnet coil, then to rotate the shaft. Holes are made so that at the angle of rotation of shaft 4 corresponding to anchor point 11 in the wall of slot 3 of sleeve 5, the axes of the holes coincide, and the anchor, resting against the wall of the slot, pushes the rotary bushing, transmitting rotation to it from the shaft, wherein the ball is pushed out of the housing opening, partially moving into shaft opening 12, and with further rotation can not leave this position, since is supported by the housing inner surface, providing reliable fixation of shaft 4 and rotary sleeve 5 between each other at any angle of rotation up to complete rotation by 360 degrees.

EFFECT: technical result consists in improvement of reliability of the lock, as well as in reducing power consumption during operation.

1 cl, 4 dwg

Description

Technical field

The invention relates to electromechanical locks, and more specifically to secret locks with an electronic encoding method.

State of the art

Known electromechanical lock RU 2151256, which contains mounted in the housing of the rotary sleeve with a locking cam. A shaft containing an electromagnet with an anchor is inserted into the bore of the sleeve. The anchor interacts with the walls of the groove of the rotary sleeve so that while applying voltage to the electromagnet and the shaft rotates, the anchor abuts against the wall of the groove of the sleeve, transmitting rotation from the shaft, and if there is no voltage on the electromagnet, the armature is pushed out of the groove under its own weight, however, rotation from the shaft is not transmitted to the rotary sleeve.

The well-known electromechanical lock is not reliable enough because it requires continuous voltage maintenance on the coil of the electromagnet, throughout the entire rotation cycle of the shaft until it is fully open, and in the event of a supply voltage from the key, contact bounce is inevitable during rotation of the key, which will lead to a power failure of the electromagnet and possible stopping the cam or bolt in the intermediate position.

Disclosure of invention

The technical result achieved by the implementation of this invention is to increase the reliability of the lock, as well as to reduce energy consumption during its operation. This technical result is achieved in that the rotating shaft is equipped with an opening whose axis is perpendicular to the axis of rotation of the shaft. The rotary sleeve is also equipped with a hole in which a ball or pin is placed having freedom of movement along the axis of the hole. The housing is equipped with a hole the size of which is slightly smaller than the diameter of the ball.

The interaction of the above holes and the ball forms a locking mechanism of the rotary sleeve and shaft. This happens as follows: to open the lock, it is necessary to apply voltage to the electromagnet coil, then rotate the shaft. The holes are made so that when the shaft is rotated through an angle corresponding to the moment when the anchor abuts against the wall of the groove of the sleeve, the axis of the holes matches, respectively, the anchor, resting on the wall of the groove, pushes the rotary sleeve transmitting rotation from the shaft, while the ball is pushed out of the hole of the housing moving along the axis the hole of the sleeve partially enters the hole of the shaft and with further rotation in the same direction cannot leave this position, since it is supported by the inner surface of the housing, ensuring reliable fixation of the shaft and the rotary sleeve with each other at any angle of rotation up to a full revolution of 360 degrees of the rotary sleeve. Moreover, after the occurrence of mutual fixation between the shaft and the rotary sleeve, the interaction between the armature and the groove of the rotary sleeve is no longer required, respectively, the voltage on the electromagnet coil is not required.

This property of the locking mechanism of the rotary sleeve and the shaft allows the lock to use an electric pulse supplied to the electromagnet coil at the moment the shaft rotates and corresponding to the length of time the shaft rotates an angle corresponding to the alignment of the axes of the shaft holes, the rotary sleeve and the housing, which makes it possible energy extraction from batteries. And the locking mechanism of the rotary sleeve and shaft increases the reliability of the lock, eliminating the possibility of stopping the rotary sleeve and the bolt in intermediate positions.

To ensure a more reliable contact between the key and the cylinder mechanism controller, it is proposed to use a socket for the key with two independent electrical contacts, spring-loaded in mutually perpendicular planes.

Brief Description of the Drawings

1. FIG. 1 Assembly drawing of an electromechanical cylinder lock mechanism.

2. FIG. 2 Longitudinal section of an electromechanical cylinder mechanism.

3. FIG. 3 The rotation cycle of the shaft 4 together with the rotary sleeve 5 (opening or closing the lock).

4. FIG. 4 The rotation cycle of the shaft 4 without mutual fixation with the rotary sleeve 5 (the opening or closing of the lock does not occur).

The best embodiment of the invention

The electromechanical lock consists of a housing 1 (Fig. 1) containing a rotary sleeve 5 coaxially mounted inside the housing into a cylindrical bore 7, by which a shaft 4 is inserted. The end part of the sleeve 5 is equipped with a cam 8 which serves to drive the locking bolt of the lock.

Mutually perpendicular through grooves are made in the shaft 4 longitudinally of its axis, which serve to install a magnetic circuit 10 and an electromagnet coil 17 in them. First, the coil 17 is installed, then the magnetic circuit 10, ensuring its reliable fixation.

In the space between the socket 6 and the shaft 4, a microcontroller 19 is installed (Fig. 2), to which on one side the terminals of the coil 17 are connected, and on the other hand a spring-loaded electrical contact 9 (Fig. 2). The power of the mechanism comes from the batteries located in the key. The key is inserted into slot 6, through contacts 9 and 18 spring-loaded in mutually perpendicular planes, power and code information is transmitted to the microcontroller 19, if the code matches, the controller 19 supplies voltage to the electromagnet coil 17. In this case, the anchor 11 is fixed in the position drawn to the magnetic circuit.

The key rotates the socket 6. The rotation from the socket 6 through the plug 20 is transmitted to the shaft 4. Thus, when the key is rotated, the anchor 11 abuts against the end wall of the groove 3, turning the sleeve 5 into rotation, and the locking mechanism of the rotary sleeve 5 and the shaft 4 starts working at the same time.

The locking mechanism consists of one or more holes 12 made on the longitudinal generatrix of the shaft 4, the through hole 13 made in the rotary sleeve 5, with a pin or ball placed in it having freedom of movement along the axis of this hole and the hole 14 made on the inner longitudinal forming surface casing 1. When the angle of rotation of the shaft 4 corresponding to the abutment point of the armature 11 in the end wall of the groove 3 is the alignment of the axes above the indicated holes 12, 13, 14, providing the ball 15 freedom of movement along the axes of these holes. Upon further rotation in the same direction of the shaft 4, the ball 15 is pushed out of the hole 14 of the housing 1, partially moving into the hole 12, but not completely leaving the hole 13. With a further rotation of the shaft 4, the ball 15 cannot leave this position, since it is supported by the inner surface of the housing 1 (Fig. 3), providing reliable mutual fixation of the shaft 4 and the rotary sleeve 5 with each other for joint rotation at any angle of rotation up to a full revolution of 360 degrees. When the shaft 4 is rotated 360 degrees, the axes of the holes 12, 13, 14 are again aligned and the ball 15 under the action of gravity partially moves to the hole 14, completely leaving the hole 12 of the shaft 4 freeing it for free rotation and at the same time will block the rotation of the rotary sleeve 5 relative to the housing one.

If, however, inserting the key into slot 6, the code does not coincide with the set one, then the controller 19 will not supply voltage to the coil 17, respectively, the armature 11 will not be held in the pulled position to the magnetic circuit 10, and when the shaft 4 is rotated, the armature 11 will be pushed out by a leaf spring 2 in a position in which it is not possible to interact with the end wall of the groove 3. The shaft 4 will make a free rotation (Fig. 4) in the hole 7 of the rotary sleeve 5, without bringing it into rotation. Cam 8 will not turn, and the locking bolt will accordingly remain without movement.

It should be noted that instead of the hole 12 at the end of the shaft 4, one or two grooves can be made, this will slightly reduce the length of the cylinder mechanism.

Industrial applicability

The electromechanical cylinder mechanism is structurally compatible with most of the known door locks and this determines the scope of its application: installation on the front doors of buildings, industrial structures and other structures in order to limit access by unauthorized persons.

Claims (2)

1. Electromechanical cylinder lock containing a rotary sleeve (5) installed in the housing (1), equipped with a cam (8), into the hole (7) of which a shaft (4) is inserted, containing an electromagnet (10) with an armature (11) that interacts with the walls of the groove (3) of the rotary sleeve (5), characterized in that one or more holes (12) are made in the shaft (4), a through hole (13) is made in the rotary sleeve (5) with a pin or ball ( 15) having freedom of movement along the axis of the hole (13), and a hole (14) is made in the housing (1), and when turning e of the shaft (4) at an angle corresponding to the stop of the armature (11) in the end wall of the groove (3), the axes of the holes (12), (13) and (14) are combined, providing the pin or ball (15) with freedom of movement along the axis of the holes (12), (13) and (14), which makes it possible to mutually fix the shaft (4) and the rotary sleeve (5), ensuring their joint rotation, or to block the rotation of the rotary sleeve (5) relative to the housing (1). 2. The lock according to claim 1, characterized in that at the end of the shaft (4) one or more grooves are made.

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