RU2170798C1 - Code magnetomechanical lock - Google Patents

Abstract

FIELD: locksmith's work. SUBSTANCE: the lock has a secret mechanism, having a body with a hole, revolving casing, closing member kinematically connected to the revolving casing, key provided with a fixing arm relative to the secret mechanism and seats for orienting magnets, magnetosensitive interlocking member installed inside the casing, a cylindrical bush is installed in the body hole coaxially with the revolving casing, blind grooves are made on the bush cylindrical surface and in the revolving casing, they correspond to the shape of the magnetosensitive interlocking member, a ferromagnetic plate restricting the transverse motion of the magnetosensitive interlocking member is inserted in one of the grooves. The revolving casing has a blind hole in the end, the cylindrical bush has the shape of a cup, whose bottom has a collar with an annular groove and axial hole for attachment of the pin of ferromagnetic material, the ferromagnetic plate is inserted in the groove of the revolving casing, and from the end the revolving casing is spring-loaded to the body, a blind hole for the pin of ferromagnetic material is provided in the key axis. EFFECT: enhanced stability to breaking in. 3 cl, 6 dwg

Description

 The invention relates to techniques for protection against unauthorized access to safes, containers, elevator shafts and other special rooms, etc., in particular to locks with permanent magnets, and can be used both in everyday life and in technology and other fields of activity .

 In practice, all types of locks are widely used: mechanical, electromechanical, electromagnetic and magnetic locks. Known devices for authorization of access: coded electrical and electronic locks, devices for locking and unlocking locks using electrical, magnetic, electronic and electron-optical means. Their descriptions are respectively given in the following patents of the Russian Federation: N 2019660, 1994, BI N 17; N 2023126, 1994, BI N 21; N 2034124, 1995, BI N 12, etc.

 In RF patent N 2023126, 1994, BI N 21, the locking safety device is provided with a radiation source and receiver, an information processing unit, and a hologram is applied to the key, which is an encoding and control element for locking and unlocking the lock.

 The main disadvantages of such devices is the need for power for electronic circuits, optical elements and emitters, which significantly reduces the reliability of their work.

 A known lock containing a housing in which the core is freely placed with three longitudinal grooves on the side surface. In the core is a series of locking discs alternating with intermediate washers. In the center of the discs, turnkey semi-cylindrical holes are made. Disks for limiting angular movement on their body have radial recesses in which pins are freely placed. Locking pins are installed in the grooves of the glass, each of which has the shape of a double-sided comb and is mounted with the possibility of moving together in the grooves of the glass and the body, moreover, from one end under the action of a spring, and from the front side by pressing the protruding part to the stop. The external protrusions of the pins interact with the grooves and protrusions and block the rotation of the core in the housing, and the internal protrusions with the locking discs and the recesses on their end surface, which block the movement of the locking pins. To lock the lock, three keys with different locations of the code grooves are used, which are alternately installed in the key hole, and 1/3 of the diameter of the surface of the locking discs with each key is used. Thus, it is possible to close with one, two and three keys (ed. Certificate N 1624108, 1991, BI N 4).

 The disadvantages of using such combination mechanical locks include: design complexity, inconvenience associated with the need to have three keys.

 Known electromagnetic code lock (ed. Certificate. N 1810451, 1993, BI N 15), which contains sequentially connected in the control circuit code reed switches, a magnetic key made in the form of a block of isolated from each other code magnets installed with the possibility of interaction with code reed switches , an end push-button switch, and the magnetic key contains an additional magnet controlling the end switch.

 The disadvantage is the cumbersome design, the need for separate power supplies for the control circuit and the electromagnet.

 A common drawback of all code devices having a push-button code set is that they do not exclude the possibility of taking a print of the key according to its physico-topological parameters, in particular the resistance of electrical circuits between the contacts facing the surface of the key or lock case; by changing the magnetic permeability of the key surface or its external magnetic fields, which will ensure the selection of the master key for unauthorized unlocking of the lock.

 In addition, as a rule, not all buttons of the code panel are used, and therefore it is not difficult to set a code to unlock the lock.

 In this regard, magnetic locks have some advantage, which contain permanent magnets and do not have a special code dialing panel, but in essence all are code locks, because their closing and unlocking occurs due to the permanent magnets of the control element, which can be made in various forms - a plate, a key, etc.

 Known magnetic cylinder lock mechanism comprising a housing with a central through hole and through radial holes. A rotary cylinder with a key channel and blind radial holes, which are cylindrical indentations coaxially aligned with through radial holes in the body, is installed in the central hole of the housing. Compression springs and locking pins are installed in the through radial openings of the housing, the end parts of which facing the rotary cylinder can either be placed in the blind radial holes of the rotary cylinder when the cylinder mechanism is closed, or the locking pins are completely located in the through radial openings of the housing when the position is open cylinder mechanism. The locking pins are spring-loaded with compression springs, which are fixed either with plugs or with a casing put on the case when assembling the lock. The locking pins are made of magnetic material with the properties of a permanent magnet with a coercive force of at least 1200 Oe and are installed during assembly of the mechanism so that the ends of the locking pins and magnetic elements located on the same axis in the body of the key core are made of the same magnetic material with the properties of a permanent magnet , were directed towards each other by the same-named magnetic poles. The body, the rotary cylinder, the key and the springs are made of non-magnetic material (RF patent N 2030534, 1995, BI N 7).

 However, for the failure-free operation of such a locking mechanism, it is necessary, in particular, that the magnetic interaction between the magnetic element in the key and the locking pin coaxial to it is greater than the force returning the locking pins of the compression spring, which counteracts the movement of the locking pins when the locking mechanism is unlocked. In FIG. Figure 1 shows the nature of the change in the repulsive force of two coaxial permanent magnets depending on the distance between them. For comparison, in the same drawing shows the power characteristic of the spring.

 From FIG. Figure 1 shows that the magnetic repulsive forces of the permanent magnets are large enough at small distances, when the distance between the opposite poles of the permanent magnets is practically zero, they decrease very quickly when the gap between the magnets increases by a fraction of a millimeter and slowly decrease, tending to zero with a further increase in distance. The compression force of the spring increases linearly according to Hooke's law. Therefore, in this design, in order for the permanent magnets in the key to be able to squeeze the locking pins when the locking mechanism is opened, either the returning springs must be weak enough, or the travel of the locking pins should be small enough. If the return springs are not strong enough, an unreliable locking mechanism of the locking mechanism will be observed, since the force of the springs may not be sufficient both to lift the locking pins in the lower position and to overcome the friction forces arising from the movement of the locking pins in a horizontal position . Obviously, the adjustment of such a locking mechanism is quite complicated, while the weakening of the springs during operation is also necessary. If the stroke of the locking pins is small, and this is a fraction of a millimeter, then the reliability of locking the lock will be low, since when you try to rotate the rotary cylinder without a key, it is possible to push the locking pins and spontaneously open the lock mechanism.

 Closest to the proposed invention is a technical solution protected by British patent 1201160, 1980.

 Magnetomechanical combination lock containing a secret mechanism having a housing with an opening, a rotary holder, a locking member kinematically connected to the rotary holder, a key provided with a locking element relative to the secret mechanism and sockets for orienting magnets, a magnetically sensitive locking element mounted inside the holder in the housing opening a cylindrical bushing is installed coaxially with the rotary cage; blind grooves are made on the cylindrical surface of the bushing and in the rotary cage corresponding to yoke magneto locking member in one of the slots is inserted a ferromagnetic plate limiting lateral movement of the locking magnetosensitive element.

 This code lock has all the disadvantages of code locks, the locking and unlocking of which is carried out with socket wrenches with orienting magnets, because secret encoding can be easily revealed.

 The technical problem solved by the invention is to increase the reliability of the locking mechanism of the magnetic lock by simplifying its design, eliminating compression springs, but without reducing the degree of secrecy.

 The technical result is achieved due to the fact that the coded magnetomechanical lock contains a secret mechanism having a housing with a hole, a rotary holder, a locking member kinematically connected to the rotary holder, a key provided with a locking element relative to the secret mechanism and sockets for orienting magnets, a magnetically sensitive blocking element, mounted inside the holder, a cylindrical sleeve is installed coaxially with the rotary holder in the hole of the housing, on the cylindrical surface of the sleeve and in the rotary cage made blind grooves corresponding to the shape magnetosensitive locking member in one of the slots is inserted a ferromagnetic plate limiting lateral movement of the locking magnetosensitive element. The rotary holder has a blind hole in the end face, the cylindrical sleeve has a cup shape, the bottom of which has a shoulder with an annular groove and an axial hole for attaching a pin made of ferromagnetic material, the ferromagnetic plate is inserted into the groove of the rotary holder, and from the end the rotary holder is spring-loaded to the body, and along the key axis there is a blind hole for a pin made of ferromagnetic material. The magnetically sensitive blocking element is made in the form of a key made of non-magnetic material with an even number of permanent magnet inserts magnetized in opposite directions.

 The working part of the key is cylindrical, with the number of blind transverse sockets for orienting permanent magnets equal to the number of permanent magnets of the magnetically sensitive blocking element magnetized in the opposite direction.

 New features in combination with the known ones allow achieving a solution to the technical problem, which is the aim of the invention, i.e. simplification of the design, leading to increased reliability, is achieved by eliminating the springs pushing the locking pins. A key that contains permanent magnets and serves to connect the rotary cage to the groove of the rotary cylindrical sleeve is disengaged, moves into the groove of the rotary holder and is held in this position by means of a magnetic plate. In addition, a key containing permanent magnets is used only to translate the locking mechanism of the lock from the locked position to the open position and vice versa. And in the "open" position and, which is much more important to increase reliability, in the "locked" position the key with permanent magnets is not engaged with the rotary cylinder rotated by the key. Thus, none of the elements of the locking mechanism when trying to unauthorized opening does not work on the cut. When trying to unauthorized opening, the rotary cylindrical sleeve rotates freely, and the spring-loaded rotary sleeve remains stationary.

 Recoding of the lock code is carried out by shifting the locking protrusion on the key and the corresponding groove or hole on the cylindrical sleeve.

 The invention is illustrated by the following drawings.

 In FIG. 2 shows a lock secret mechanism in the open or locked position; in FIG. 3 is a view of the secretion mechanism along the A-A section; in FIG. 4 - a lock secret mechanism complete with a key when opening or locking; in FIG. 5 is a section along B-B; in FIG. 6 is the key.

 The lock secret mechanism comprises a housing 1, a cylindrical sleeve 2 with a blind groove 3 and a collar 4, a rotary holder 5 with a groove 6, a key 7, inserts of permanent magnets 8, a plate of ferromagnetic material 9, a pin 10 connecting the rotary holder with the locking element of the lock (not shown in the drawings), an axial pin 11, a ring 12, a split spring 13, a key 14 with orienting magnets 15, a protrusion 16 and a blind axial hole 17.

 Code magnetomechanical lock operates as follows.

 In the closed or open position (see Fig. 2), the movable key 7 with inserts of permanent magnets 8 turns out to be a retracted plate 9 of ferromagnetic material inside the groove 6 of the rotary holder 5 and exits from the groove 3 of the cylindrical sleeve 2. Cylindrical sleeve 2 made in the form of a cup, the bottom of which has a collar 4 with an axial hole for the pin 11 of ferromagnetic material. A split spring 13 is inserted into the annular groove of the shoulder 4, which compresses the rotary holder to the housing 1. As a result, the cylindrical sleeve 2 rotates freely around the axis without transmitting force to the rotary holder 5 connected to the locking member, which in FIG. 2 is not shown, by means of a pin 10, which converts the rotational movement of the rotary cage into the translational movement of the locking member. A bolt, latch, etc., with a corresponding groove into which pin 10 is inserted, can be used as a locking member. In the position shown in FIG. 2, the locking member may be in the “open” or “closed” state, but in any case its rotation will not change due to rotation of the cylindrical sleeve, since the rotary cage spring-loaded to the housing remains stationary.

 When placing the key 14 (see figure 4) in the channel of the cylindrical sleeve 2, it is fixed in it due to the protrusion 16 and the blind axial hole 17, into which the pin 11 of the ferromagnetic material is inserted. The pin has a twofold purpose: to strengthen the magnetic field of the key 14 and protect against unauthorized access to the lock secret mechanism. Under the influence of the forces of attraction of the permanent magnets 15 of the key 14, having 8 inserts aligned with the permanent magnets located in the key 7, the key 7 moves into the blind groove 3 of the cylindrical sleeve 2, mechanically connecting it to the rotary holder 5, the pin 10 of which is in the groove of the locking member . In this position, the rotation of the key through the cylindrical sleeve 2 is transmitted to the rotary holder 5 and through the pin 10 is converted into the translational movement of the locking element. The direction of rotation of the key depends on the position in which the locking element was “open” or “closed”. Depending on this, the lock can be opened or closed.

 When removing the key 14 from the axial channel of the cylindrical sleeve 2, the key 7 with permanent magnets 8 is pulled by the restrictive plate 9 of ferromagnetic material into the blind groove of the rotary sleeve 5, mechanically disconnecting it from the cylindrical sleeve 2, i.e., translating it into the position shown in FIG. 2.

 The conversion of the lock secret mechanism is carried out by changing the locking elements on the key and the cylindrical sleeve relative to the keyway grooves. This makes it possible to open or close the lock only with an individual key. The locking element can be made in various ways - as shown in FIG. 2, i.e. due to the displacement of the hole 18 of the rotating cylindrical sleeve 2 or by introducing a blind groove on the inner surface of the cylindrical sleeve 2.

 The positive effect of the use of the invention is to increase the reliability of locking and simplify the design of the secret mechanism of the castle, which does not have elements working on a slice.

Claims (3)

 1. Magnetomechanical combination lock containing a secret mechanism having a housing with a hole, a rotary holder, a locking member kinematically connected to the rotary holder, a key provided with a locking element relative to the secret mechanism and sockets for orienting magnets, a magnetically sensitive locking element mounted inside the holder, in a cylindrical bushing is mounted coaxially with the rotary holder, a blind groove is made on the cylindrical surface of the sleeve and in the rotary holder, corresponding to in the form of a magnetically sensitive blocking element, a ferromagnetic plate is inserted into one of the slots, restricting the lateral movement of the magnetically sensitive blocking element, characterized in that the rotary cage has a blind hole in the end face, the cylindrical sleeve has a cup shape, the bottom of which has a shoulder with an annular groove and an axial hole for mounting a pin made of ferromagnetic material, the ferromagnetic plate is inserted into the groove of the rotary holder, and from the end the rotary holder is spring-loaded to the housing, and about the axis of the key has a blind hole the pin of a ferromagnetic material.  2. The magnetomechanical lock according to claim 1, characterized in that the magnetically sensitive blocking element is made in the form of a key made of non-magnetic material with an even number of inserts of permanent magnets magnetized in opposite directions.  3. The magnetomechanical lock according to claim 1 or 2, characterized in that the working part of the key is cylindrical, with the number of blind transverse sockets for orienting permanent magnets equal to the number of permanent magnets of the magnetically sensitive blocking element magnetized in the opposite direction.

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