RU2609789C1 - Lock - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: present invention relates to lock devices controlled by electronic devices or manually, and can be used for doors locking of cupboards, safes etc. The lock comprises interacting with each other catch made with possibility of deviation from its axis and comprising a stock with at least one head, and lock device comprising a housing with made input opening, the opening size exceeds size of the catch head, and internal cavity connected with input opening, the cavity size exceeds size of input opening in which lock is located, the lock is made with possibility of longitudinal movement inside the housing and interaction with the catch head, and at least one return device made with possibility to ensure the lock movement towards the catch, and at least one holding device made with possibility of the lock holding in the position ensuring free exit of the catch head from the lock device. Wherein the lock has a fixed limiter made with possibility of partial closing of the input opening, wherein ration of the catch head size to distance from edge of the fixed limiter to edge of input opening depends on lock position in the housing.

EFFECT: simple design of lock and its manufacturing due to reduced number of elements, simple manufacturing and assemblage of design upon simultaneous keeping of lock reliability.

13 cl, 14 dwg

Description

The present invention relates to locking devices controlled by electronic means or manually, and can be used to lock the doors of cabinets, safes, etc.

Known electromagnetic lock (patent RU No. 2382861, IPC E05B47 / 02, published February 27, 2010) containing a crossbar, a spring-loaded rod of the crossbar with a head, a cylindrical body, an electromagnet with a cylindrical core (holding device) located inside the electromagnet coil, an electromagnet coil is installed in the inner cavity of the housing, a latch made in the form of a glass and placed in the inner cavity of the housing with the possibility of longitudinal movement on the side surface of the latch, in a plane parallel to its bottom, more than two holes are evenly distributed with balls placed therein (stops), the holes for balls are made in the form of two parts of different diameters connected by a conical transition, and the diameter of the holes located on the outer surface of the retainer is equal to the diameter of the balls and located on the inner surface - less than the diameter of the balls, the depth of the holes of each diameter is such that the surface of the balls located in them coincides with the outer surface of the latch and stands for its inner rotation The diameter of the crossbar rod is less than the diameter formed by the surfaces of the protruding parts of the balls above the cylindrical part of the retainer hole, the outer end of the crossbar rod contains a head with a diameter equal to the diameter of the cylindrical part of the central hole of the retainer, and the inner end has a threaded thread, a lock nut, and a fixing washer. Additionally, a cylindrical permanent magnet (return device) is introduced into it. And the amount of displacement of the latch in the housing is such that in one position the latch is adjacent to the end surface of the cylindrical core, and the balls extend beyond the inner surface of the latch, in the other, the outer end surface of the middle outer cylinder of the latch is adjacent to the inner end surface of the sleeve, and the balls are in the region the inner surface of the retainer, and the cylindrical body, the cylindrical core, the retainer and the ring are made of magnetically conductive material, and on the outer surface The ring groove is made for the conclusions of the electromagnet coil.

A well-known castle is selected as a prototype, as it contains the largest number of essential features that match the essential features of the claimed technical solution.

However, the prototype has a significant drawback, consisting in the complexity of the design due to the use of a large number of elements and in the complexity of manufacturing, in particular, due to the need for high-precision holes for the balls in the retainer.

The objective of the present invention is to create a new lock with the following technical result: simplification of its design and its manufacture by reducing the number of elements, simplifying their manufacture and simplifying assembly of the structure while maintaining the reliability of the locking.

The problem is solved due to the fact that in the known castle, including interacting with each other crossbar, made with the possibility of deviation from its axis and containing a rod with at least one head on it, and a locking device consisting of a housing in which the input an opening the size of which exceeds the size of the bolt head, and an internal cavity connected to the inlet, the size of which exceeds the size of the inlet, in which the latch is arranged, made with the possibility of longitudinal movement within the housing and interacting with the crossbar head, and at least one return device configured to allow the latch to move toward the crossbar, and at least one holding device configured to hold the latch in a position that allows the bolt head to freely exit the shutoff of the device according to the present invention, a fixed stop is formed in the latch, which is configured to partially overlap the inlet, while the size ratio olovki bolts and distance from edge to edge of the fixed restrictor inlet depends on the position of the retainer in the housing.

There are options for the development of the main technical solution, consisting in the fact that:

- the fixed stopper of the lock is equipped with a stop;

- the latch is cylindrical, the fixed limiter of which is formed in the form of a protrusion;

- the latch is equipped with longitudinal ribs;

- the latch is made in the form of a plate, part of which is bent at a right angle, and in the non-bent part a hole is formed adjacent to the bent part and made with the possibility of entering into it part of the crossbar head;

- the holding device is made electromagnetic;

- the holding device is made electromechanical, for example in the form of an electric motor with a gearbox or in the form of an electric motor without a gearbox;

- the holding device is made mechanical with a manual drive;

- the return device is made in the form of a permanent magnet built into the latch from the side of its interaction with the crossbar head;

- the return device is made in the form of a permanent magnet built into the bolt head from the side of its interaction with the latch;

- the return device is made in the form of at least one spring, made with the possibility of acting on the latch.

Thus, the claimed technical solution with all its essential features makes it possible to simplify the design of the lock and its manufacture by reducing the number of elements, simplifying their manufacture and simplifying assembly of the structure, due to the formation of a fixed stopper in the retainer, which is able to partially overlap the inlet, which eliminates balls of the retainer design and, as a result, simplify it. At the same time, the locking reliability is maintained due to the fact that by the formation of a fixed stop on the movable latch, it is possible to change the distance from the edge of the fixed stop to the edge of the inlet, i.e. it becomes possible to overlap part of the inlet so that the distance from the edge of the limiter to the edge of the inlet will be less than the head of the crossbar. As a result of this, the bolt head will not be able to exit the locking device. In addition, the claimed invention allows you to use any shape of the head of the crossbar, in contrast to the prototype, where the shape can only be rounded, since the movable stops (balls) will act on the head around the circumference. This additionally improves the functionality of the inventive castle.

Moreover, in contrast to the known technical solutions, where a crossbar is used, made with the possibility of deviation from its axis, in the claimed technical solution this feature is used for another purpose. So, for example, in the prototype, the deflection of the bolt is used to center and compensate for inaccuracies in the relative position of the locking device and the bolt when installing the lock. In the claimed invention, such an application also takes place, but the possibility of bending around the edge of the inlet and / or stop (if any) is added.

The essence of the claimed invention and the possibility of its practical implementation is illustrated by the description and drawings below.

FIG. 1 is a side view of the lock in the general embodiment (the initial position is “open”, the entrance of the bolt head to the inlet and the deviation of the bolt).

FIG. 2 is a side view of a lock in a general embodiment (“closed” position).

FIG. 3 is a side view of a lock in a general embodiment (holding the lock).

FIG. 4 is a side view of the lock in the general embodiment (the position is “open”, the bolt head exits the inlet and the bolt deviates).

FIG. 5 is a side view of the lock with an emphasis on a stationary limiter (the initial position is “open”, the entrance of the bolt head to the inlet).

FIG. 6 is a side view of the lock with an emphasis on a stationary limiter (the head of the bolt goes around the emphasis due to the deflection of the bolt.).

FIG. 7 is a side view of the lock with emphasis on a stationary limiter (the "closed" position).

FIG. 8 is a side view of a lock with an emphasis on a fixed stop (holding the latch).

FIG. 9 is a bottom view of the lock with a latch in the form of a plate (the initial position is “open”, the entrance of the bolt head to the inlet, the latch is held).

FIG. 10 is a side view of the lock with a latch in the form of a plate (the initial position is “open”, the entrance of the bolt head to the inlet, the latch is held).

FIG. 11 is a bottom view of the lock with a latch in the form of a plate (the initial position is “open”, the entrance of the bolt head to the inlet, the latch is released).

FIG. 12 is a side view of the lock with a latch in the form of a plate (the bolt head bends around the stationary limiter, made in the form of the edge of the hole due to the deviation of the bolt).

FIG. 13 is a side view of a lock with a lock in the form of a plate (the "closed" position).

FIG. 14 is a side view of a lock with a lock in the form of a plate (holding the lock).

The lock (Fig. 1-14) includes a crossbar interacting with each other, made with the possibility of deviation from its axis and containing a rod 1 with at least one head 2 on it, and a locking device consisting of a housing 3, from one end of which there is cover 4, and on the other hand, an inlet 5 is formed, the size of which exceeds the size of the head 2 of the crossbar. An inner cavity 6 is formed in the housing 3, connected to the inlet 5, the size of which exceeds the size of the inlet 5. A latch 7 is arranged in the inner cavity 6, which is capable of longitudinal movement inside the housing 3 and interacts with the head 2 of the crossbar, and at least one a return device 8, configured to move the latch 7 toward the crossbar, and at least one holding device 9, configured to hold the latch 7 in a position that provides free th exit of the head 2 of the bolt from the locking device.

A fixed stopper 10 (hereinafter referred to as the stopper) is formed in the latch 7, which is configured to partially overlap the inlet 5, and the ratio of the size of the head 2 of the crossbar and the distance from the edge of the stop 10 to the edge of the inlet 5 depends on the position of the latch 7 inside the housing 3. When the latch 7 is released and the bolt does not act on it, the limiter 10 overlaps part of the inlet 5 and the distance from the edge of the limiter 10 to the edge of the inlet 5 is smaller than the size of the head 2 of the crossbar, which does not allow the head 2 Igel come out of the locking device. When the latch 7 is held by the holding device 9, the distance from the edge of the stopper 10 to the edge of the inlet 5 is larger than the size of the head 2 of the bolt, which allows the head 2 of the bolt to exit the locking device.

The limiter 10 of the latch 7 can be equipped with a stop 11 (Fig. 5-14). The stop 11 serves to redistribute the locking forces. The force from the crossbar, through its head 2, is transmitted simultaneously to the edge of the inlet 5 and the stop 11 on the limiter 10. Thus, the axial load is distributed so that the bending moment does not act on the crossbar, in contrast to the general version, when the axial force from the crossbar through its head 2 is transmitted only to the edge of the inlet 5.

In a general embodiment (Fig. 1-4), the axial force through the bolt is transmitted to the edge of the inlet 5 through the head 2 of the bolt. The head 2 of the crossbar interacts with the edge of the inlet 5 with one of its part. The distance from the place of interaction of the head 2 with the edge of the inlet 5 to the crossbar axis forms a shoulder. The result is a moment. Thus, a tensile force and a bending moment act on the crossbar. In the embodiment with an emphasis 11 on the limiter 10 (Fig. 5-8) and the variant with the lock 7 in the form of a plate (Fig. 9-14), the axial force is transmitted through the head 2 of the bolt to the edge of the inlet 5 and the emphasis 11 on the limiter 10. The force acting on each interaction site is less than the force on the edge of the inlet, in the general embodiment. The place of interaction of the head 2 of the crossbar with the inlet 5 and the stop 11 on the limiter 10 are symmetrical about the axis of the crossbar. Thus, the moments from the action of forces on the edge of the hole 5 and the stop 11 cancel each other out. As a result, only the axial force acts on the bolt (bending moments are compensated) and the force is distributed in two places (the edge of the hole 5 and the stop 11 on the limiter 10), each of which acts only half of the axial force. Loads on parts of the lock are reduced.

The housing 3 can be made integral or collapsible. The inlet 5 can be formed directly at the end of the housing 3 from the side of its interaction with the head 2 of the bolt or in the cage 12 (Fig. 9-14) installed in the housing 3 between in front of the internal cavity 6.

Before the inlet 5 from the side of the head 2 of the bolt in the housing 3 of the locking device, an inlet cone 13 can be formed, which is designed to position the head 2 of the bolt at the entrance to the inlet 5.

The bolt, the housing 3, the cover 4, the latch 7 can be made of metal, in particular of a magnetically conductive material, to ensure their interaction with the magnetic field of an electromagnet (Fig. 1-8) and / or a permanent magnet (Fig. 5-8). It is also possible that the case 3 is made of plastic, and the holder 12 is made of metal to reinforce the edges of the inlet 5.

The internal cavity 6 is a free space inside the housing 3, communicating with the inlet 5.

The latch 7 can be made of any shape suitable for performing the function assigned to it.

In one embodiment, the latch 7 can be made, for example, cylindrical, the limiter 10 of which is formed in the form of a protrusion (Fig. 1-8). The shape and length of the protrusion is determined by the geometrical parameters of the inner cavity 6 and the inlet 5. At the same time, the restrictor 10 may protrude from the inlet 5 outward from the locking device to improve the operational characteristics of the lock or due to the design features of a particular lock design.

In this case, the latch 7 (to prevent its rotation due to the cylindrical shape in the inner cavity 6) may be provided with longitudinal ribs (not shown in the drawing) or at least one groove (not shown in the drawing).

The technologically proposed embodiment of the latch 7 and the limiter 10 in it can be obtained, for example, in the following ways.

In the cylindrical retainer 7, the limiter 10 is formed by removing part of the material from the side of the interaction of the retainer 7 with the head 2 of the bolt (Fig. 1-8). In this case, the removed part is located along the longitudinal axis of the latch 7 and is shifted to the edge of the cylinder. The length of the removed part is performed not less than the length of the head 2 of the crossbar, and the thickness is such as to allow the head 2 of the crossbar to pass between the limiter 10 and the wall of the inner cavity 5.

The cylindrical retainer 7 can be cast, and the stop 10 is formed by a part of the forming surface of the mold in the form of a branch of the cavity. The branch is located on the side of the interaction of the retainer 6 with the head 2 of the bolt, along the longitudinal axis of the retainer 7 and is shifted to the edge of the cylinder. The size of the branch is not less than the length of the head 2 of the crossbar, and the thickness should provide free passage of the head 2 of the crossbar between the limiter 10 and the wall of the internal cavity 6.

The cylindrical lock 7 can be made by pressing from powder material in the form of a cylinder, and the stopper 10 is formed by a part of the molding cavity of the mold, in the form of a branch of the cavity. The branch is located on the side of the interaction of the latch 7 with the head 2 of the bolt, along the longitudinal axis of the latch 7, is shifted to the edge of the cylinder. The size of the branch is not less than the length of the head 2 of the crossbar, and the thickness should provide free passage of the head 2 of the crossbar between the limiter 10 and the wall of the internal cavity 6.

On the limiter 10 from the side of its interaction with the edge of the inlet 5, an entry chamfer 14 can be formed, which serves to simplify the entry of the head 2 of the crossbar into the inner cavity 6.

In another possible embodiment, the latch 7 can be made in the form of a plate (Fig. 9-14), part 15 of which is bent at a right angle, and in the non-bent part 16 an opening 17 is formed adjacent to the bent part 15 and made with the possibility of entry into it parts of the head 2 of the crossbar. In this case, the limiter 10 is the non-bent part 16, and the stop 11 is the edge of the hole 17, with which the head 2 of the bolt engages when passing into the internal cavity 6. A partition 18 can be made in the housing 3.

At the same time, at the end of the plate from the side of its interaction with the head 2 of the bolt in the non-bent portion 16 in front of the hole 17, a lead-in recess 19 can be made that repeats the shape of the lead-in cone 13 in the meta where the latch 7 exits.

From the above examples it is seen that the return device 8 can be made in the form of at least one spring configured to act on the latch 7 (Figs. 1-4, 9-14).

Also, the return device 7 can be made in the form, for example, of a permanent magnet embedded in the latch 7 from the side of its interaction with the head of the bolt 2 (Fig. 5-8) or built into the head 2 of the bolt from the side of its interaction with the latch 7 (in the drawing not shown). Moreover, in the case of embedding the permanent magnet in the latch 7, a through technological hole 20 can be formed in the latch 7.

The holding device 9, in turn, can be made electromagnetic (Fig. 1-8), electromechanical (Fig. 9-14), mechanical with a manual drive (Fig. 9-14), or a combination thereof (Fig. 9-14) . For example, in the case of emergency opening, due to a power outage or failure of the electric motor, or jamming of the mechanism, the main holding device 9 can be supplemented with a manual cable for emergency (manual) opening 21.

Usually, the bolt is installed on the door (not shown in the drawing), and the locking device is installed in the door jamb (not shown in the drawing) if the lock is mortise (the lock is in the open state when voltage is applied to the electromagnet of the holding device 9), or door jamb (not shown in the drawing), if the design of the lock is overhead.

The principle of operation of the inventive castle.

A lock made in accordance with FIG. 1-4, works as follows. In the initial position "open", in which the coil of the electromagnet of the holding device 9 is de-energized, the latch 7 is pressed by the return device (spring) 8 to the edge of the inlet 5. When closing the door, the head 2 of the crossbar along the entry cone 13 is shifted into the internal cavity 6 of the housing 3 of the locking device . Then she pushes the latch 7 in front of her, squeezing the return device 8. In this case, the limiter 10 is shifted relative to the edge of the inlet 5, leaving enough space for the passage of the head 2 of the crossbar inward. Then, the head 2 of the bolt, due to the possibility of the deviation of the bolt from its axis, bends around the edge of the inlet 2 and rests on the latch 7, pressing it to the cover 4 of the housing 3. When the door is opened, the head 2 of the bolt leaves the locking device, the latch 7 under the action of the return device 8 moves after the head 2 of the crossbar. When the latch 7 rests against the edge of the inlet 5, the stop 10 will occupy a position in which the distance between the edge of the stop 10 and the edge of the inlet 5 becomes much smaller than the head 2 of the crossbar and does not allow the head 2 of the crossbar to exit the locking device. The lock is closed in this case. The initial position for opening the lock is the position at which the head 2 of the bolt fits into the inner cavity 6 and abuts against the latch 7, pressing it to the cover 4 of the housing 3 and compressing the return device 8. To open the lock, a voltage is applied to the coil of the electromagnet of the holding device 9. In this case, the force of magnetization of the latch 7 to the cover 4 of the housing 3 will be greater than the force created by the device 8 return. In this case, when the door is opened, the latch 7 remains stationary, and the stop 10 will be displaced relative to the edge of the inlet 5, leaving enough space for the passage of the head 2 of the crossbar. Next, the head 2 of the bolt, due to the possibility of the deviation of the bolt from its axis, bends around the edge of the inlet 5 and leaves the inner cavity 6. The lock is open.

A lock made in accordance with FIG. 5-8, works as follows. In the initial position "open", in which the coil of the electromagnet of the holding device 9 is de-energized, the latch 7 is in an arbitrary position. When closing the door, the head 2 of the crossbar along the inlet cone 13 is shifted into the inner cavity 6 of the locking device. Then she pushes the latch 7 in front of her until the latch 7 rests against the cover 4 of the housing 3. In this case, the stop 11 of the limiter 10 of the latch 7 is shifted relative to the edge of the inlet 5 of the housing 3, leaving enough space for the head 2 of the bolt to pass into the housing 3. Then the head 2 bolts, due to the possibility of deviation of the bolt from its axis, bends around the stop 11, reaches the bottom of the latch 7 and is magnetized to the return device 8 (permanent magnet) mounted in the latch 7. The latch 7 remains pressed against the cover 4 of the housing 3. When opening the door, the head 2 of the bolt will begin to leave the inner cavity 6, dragging the latch 7 behind it, being magnetized to it by the return device 8, mounted in the latch 7. When the latch 7 rests against the edge of the inlet 5, its stop 11 will be aligned with the edge of the inlet 5 As a result, the distance between the stop 11 of the latch 7 and the edge of the inlet 5 will become much smaller than the head 2 of the crossbar and will not allow the head 2 of the crossbar to leave the inner cavity 6. The lock is closed in this case. The initial position for opening the lock is the position in which the head 2 of the bolt fits into the inner cavity 6 and rests on the latch 7, magnetized to the return device 8, and presses the latch 7 on the cover 4 of the housing 3. To open the lock on the electromagnet coil of the holding device 9 voltage is applied. In this case, the force of magnetization of the latch 7 to the cover 4 of the housing 3 will be greater than the force of magnetization of the head 2 of the bolt to the return device 8 mounted in the latch 7. In this case, when the door is opened, the latch 7 remains stationary, and the stop 11 of the latch 7 will be shifted relative to the edge the inlet 5, leaving enough space for the passage of the head 2 of the crossbar. Next, the head 2 of the bolt, due to the possibility of the deviation of the bolt from its axis, goes around the stop 11, goes around the edge of the inlet 5 and leaves the inner cavity 6. The lock is open.

A lock made in accordance with FIG. 9-14, works as follows. In the initial open position, the latch 7 is locked by the holding device 9 in a position in which the edge of the hole 17 is offset from the edge of the inlet 5, leaving enough space for the passage of the head 2 of the crossbar. In this case, the latch 7 abuts against the partition 18 of the housing 3. When closing the lock, a voltage of the corresponding polarity is applied to the electric motor 22 of the holding device 9. In this case, the electric motor 22 through the gear 23 acts on the latch 7, releasing it (the locking plate 24 of the retaining device 9 is out of engagement with the groove 25 on the latch 7). The latch 7 under the action of the return device 8 (in this embodiment, made in the form of a combination of two springs located on opposite sides of the latch 7) moves toward the yoke 12 until it rests against the yoke 12. Then, the head 2 of the crossbar the cone 13 is shifted into the inner cavity 6 of the locking device. Then she pushes the latch 7 in front of her, stretching the return device 8. The edge of the hole 17 is shifted relative to the edge of the inlet 5 of the holder 12, leaving enough space for the head 2 of the bolt to pass into the housing 3. Then, the head 2 of the bolt, due to the possibility of the deviation of the bolt from its axis, bends around the edge of the hole 17 and abuts against the bent part of the plate 15 latch 7, pressing it to the partition wall 18 of the housing 3. The latch 7 remains pressed against the partition 18 of the housing 3. When the lock is opened, the head 2 of the bolt moves to the exit of the locking device, the latch 7 is activated by the return device 8 moves after the head of the 2 bolts. When the latch 7 rests on the yoke 12, the edge of the hole 17 will be aligned with the edge of the inlet 5. As a result, the distance between the edge of the hole 17 and the edge of the inlet 5 will become much smaller than the head 2 of the crossbar and will not allow the head 2 of the crossbar to leave the inner cavity 6. Lock in this case is closed.

The initial position for opening the lock is the position in which the head 2 of the bolt fits into the inner cavity 6 and abuts against the bent part of the latch plate 15, pressing it against the partition 18 of the housing 3 and stretching the return device 8. To open the lock on the electric motor 22 of the holding device 9, a voltage of the polarity opposite to that which was necessary to lock the lock is supplied. The electric motor 22, through the gear 23, cockes the holding device 9 (the locking plate 24 of the holding device 9 is pressed towards the groove 25 on the latch 7). When the latch 7 is pressed against the partition 18 of the housing 3, the holding device 9 will work by locking the latch 7 (the locking plate 24 will enter the groove 25 in the latch 7) in a position in which the edge of the hole 17 is offset from the edge of the inlet 5, leaving enough space for passage head 2 bolts. In this case, when the lock is opened, the crossbar head 2, due to the possibility of the bolt deviating from its axis, goes around the edge of the hole 17, goes around the edge of the inlet 5 and leaves the inner cavity 6. The lock is open.

If it is impossible to open the lock, due to a power outage, as well as a failure of the electric motor or jamming of the mechanism of the holding device 9, the lock opens as follows.

The initial position for opening the lock is the position in which the head 2 of the bolt fits into the inner cavity 6 and abuts against the bent part of the latch plate 15, pressing it against the partition 18 of the housing 3 and stretching the return device 8.

To open the lock, the latch 7 is held by the cable 21 fixed thereon, overcoming the force, the return device 8, and is pressed against the partition 18 of the housing 3. The edge of the hole 17 is offset from the edge of the inlet 5, leaving enough space for the passage of the head 2 of the crossbar. In this case, when the door is opened, the crossbar head 2, due to the possibility of the crossbar deflecting from its axis, goes around the edge of the hole 17, goes around the edge of the inlet 5 and leaves the inner cavity 6. The lock is open.

Thus, the technical result of the inventive lock is achieved, namely, simplification of its design and its manufacture by reducing the number of elements, simplifying their manufacture and simplifying assembly of the structure while maintaining the reliability of locking.

Claims (13)

1. A lock comprising a crossbar interacting with each other, configured to deviate from its axis and containing a rod with at least one head on it, and a locking device consisting of a housing in which an inlet is formed whose size exceeds the size of the crossbar head , and an internal cavity connected to the inlet, the size of which exceeds the size of the inlet, in which the latch is placed, made with the possibility of longitudinal movement inside the housing and interaction with the head of the bolt and at least one return device configured to allow the latch to move toward the bolt, and at least one holding device configured to hold the latch in a position that allows the bolt head to freely exit the locking device, characterized in that in the latch a fixed stop is formed, made with the possibility of partial overlapping of the inlet, the ratio of the size of the head of the crossbar and the distance from the edge of the fixed limiter to The inlet opening depends on the position of the latch inside the housing. 2. The lock according to claim 1, characterized in that the fixed stopper of the lock is provided with a stop. 3. The lock according to claim 1, characterized in that the latch is cylindrical, the fixed limiter of which is formed in the form of a protrusion. 4. The lock according to claim 3, characterized in that the latch is provided with longitudinal ribs. 5. The lock according to claim 1, characterized in that the latch is made in the form of a plate, part of which is bent at a right angle, and in the non-bent part a hole is formed adjacent to the bent part and configured to allow part of the crossbar head to enter into it. 6. The lock according to claim 1, characterized in that the holding device is made electromagnetic. 7. The lock according to claim 1, characterized in that the holding device is electromechanical. 8. The lock according to claim 7, characterized in that the holding device is made in the form of an electric motor with a gearbox. 9. The lock according to claim 7, characterized in that the holding device is made in the form of an electric motor without a gearbox. 10. The lock according to claim 1, characterized in that the holding device is made mechanical with a manual drive. 11. The lock according to claim 1, characterized in that the return device is made in the form of a permanent magnet built into the latch on the side of its interaction with the crossbar head. 12. The lock according to claim 1, characterized in that the return device is made in the form of a permanent magnet built into the bolt head from the side of its interaction with the latch. 13. The lock according to claim 1, characterized in that the return device is made in the form of at least one spring configured to act on the latch.

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