RU2387774C1 - Method for lock unlocking and lock that realises this method - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method for unlocking of lock consists in the fact that changing levels from initial position into working one, which complies with the lock code, ends with fixation of levels in specified working position, at the same time changing levels into working position and fixation of levels in this position is executed in a certain angular sector of key turn under conditions of mechanical blocking of latch motion, and latch unlocking and its displacement is carried out in another angle sector of key rotation, where access to levels is closed. To execute these operations, locks comprises mechanisms of displacement and mechanical blocking of latch and installation of levels into initial position, and also protective screen that closes access to levels from outside in certain angle sectors of key rotation.

EFFECT: improved resistance of locks to criminal opening performed by non-destructive check methods.

7 cl, 21 dwg

Description

The claimed group of inventions relates to locking devices and can be used in the development of safe and household door locks, which have a high degree of resistance to criminal opening, carried out by non-destructive methods.

The claimed inventions are intended for use in locks containing a deadbolt with a thrust stand and a set of plate delays (levers), moved relative to the thrust thrust of the deadbolt when turning the key with a beard.

Locks of the type in question include, for example, the locks presented in the copyright certificates of the USSR: [1] - SU 168141 A1, ЕВВ 25/02, 01/01/1965; [2] - SU 370329 A1, E05B 21/02, 02/15/1973; [3] - SU 1227784 A1, E05B 25/06, 04/30/1986; [4] - SU 1481364 A1, E05B 25/00, 05.23.1989; as well as in patents of the Russian Federation: [5] - RU 2034973 C1, E05B 35/08, 05/10/1995; [6] - RU 2174177 C1, E05B 25/00, 09/27/2001. These locks are characterized by the installation of levers in the guides with the possibility of their movement in the direction perpendicular to the direction of movement of the bolt. The bolt has a figured hole with thrust sections designed for force interaction with the key, and a thrust stand interacting with the levers. Suvalds have figured openings in which there is a persistent rack of a deadbolt, and arched sections intended for interaction with a key. The profile configuration of the deadbolt stop and the configuration of the figured holes in the levers determine the lock code. In the process of unlocking and locking the lock, the levers are installed in the working position corresponding to the lock code, which allows the stop of the deadbolt to pass through the levers, and a moving force is applied to the deadbolt, which, when the lock is unlocked, moves the bolt into the lock case and, when locking the lock, - extends from the housing. The installation of the suvald in the working position and the movement of the deadbolt occur within the same time phase, while the key simultaneously acts with its beard on the levers and a deadbolt, namely, on the arched contact sections of the levers and thrust sections of the deadbolt. During the movement of the bolt, the levers due to their springs are in constant contact with the key, providing free passage of the persistent bar of the bolt through the figured holes of the levers. With the key removed, the levers under the action of the springs are set to their original state, blocking the thrust stand in the figured holes of the levers.

According to the same principle, single-turn locks with lamellar rotary levers, which are moved by the key in the angular direction simultaneously with the longitudinal movement of the bolt, work, see, for example, US patents: [7] - US 4462230, E05B 25/00, 07/31/1984; [8] - US 5502990, E05B 25/00, 02/02/1996; [9] - US 1935225, US C1, 70-75, 11/14/1933. The levers in these locks are mounted on the same axis of rotation with the possibility of angular movement under the action of the key, have a deadbolt slot made in the radial direction relative to the axis of rotation, and arcuate contact sections designed to interact with the key. The profile configuration of the deadbolt strut and the angular position of the slots of the levers determine the lock code. In the locked state of the lock, the levers under the action of their springs are in the extreme angular initial position, blocking the possibility of moving the bolt inside the lock case. Unlocking and locking the lock is performed by turning the key, while in the locks [7] and [8], the force is transferred from the key to the bolt by means of an intermediate element acting as a lever, and in the lock [9] there is a direct interaction of the key with the bolt. In locks [7] - [9], as in the locks considered above [1] - [6], the installation of the levers in the working position corresponding to the lock code and the movement of the bolt is carried out within one time phase, while the levers at the expense of their the springs are in constant contact with the key, allowing free passage of the deadbolt stub through levers. With the key removed, the levers under the action of their springs are in the initial position, blocking the possibility of moving the bolt.

As a prototype of the claimed inventions adopted the design and method of unlocking the lock, implemented in the lock presented in US patent [10] - US 3884058, E05B 21/00, 05/20/1975.

The prototype lock contains a deadbolt located in the housing of the bolt, mounted with the possibility of reciprocating movement in the process of unlocking and locking the lock by turning the key, a set of plate levers installed with the ability to move relative to the deadbolt of the bolt, as well as a key with a beard, inserted into the lock through the corresponding key hole made in the housing. The levers are mounted on the axis of rotation, spring-loaded relative to the body, have curly slots with an arcuate contact section designed to interact with the key beard, and a passage designed to pass the deadbolt stub. The bolt has a figured hole with thrust sections designed to exert movement forces created by the key, under the action of which the bolt is pushed into the housing when the lock is unlocked and pushed out of the housing when the lock is locked. The profile configuration of the deadbolt support and the location of the aisles in the levers determine the lock code. In the locked state of the lock (the bolt is extended, the key is removed), the levers under the action of their springs are in the extreme angular (initial) position, in which the position of the passages in the levers does not coincide with the position of the thrust stand, thereby providing a code blocking of the bolt.

During unlocking, the key is applied to the levers, setting them in the working position corresponding to the lock code, which makes it possible for the deadbolt to pass through the passages in the figured slots of the levers, and also apply the force created by the key to the deadbolt, moving it inside the case the castle. The installation of the levers in the working position and the movement of the bolt is carried out within the same time phase, while the key simultaneously acts with its beard on the levers and deadbolt, namely, on the arched contact sections of the levers and thrust sections of the bolt. During the movement of the deadbolt, the levers due to their springs are in constant contact with the key, providing free passage of the persistent rack of the deadbolt through the levers. The lock is locked in the reverse order.

Thus, in the prototype, as in the above counterparts [1] - [9], there is a simultaneous installation of the levers in working position and the movement of the deadbolt, which is achieved due to the simultaneous application of the forces created by the key to the levers and deadbolt.

The simultaneity of these operations negatively affects the resistance of the prototype lock in relation to a criminal showdown. The fact is that with this method of unlocking the lock, it is fundamental that you can simultaneously access the bolt and the levers from the side of the key hole, as well as the ability to simultaneously move them relative to each other, which makes it possible to identify the lock code and open the lock with master keys, the action of which is based on the simultaneous application of efforts to the bolt and levers. It also facilitates the possibility of criminal opening of the lock, the almost linear nature of the movement of the levers depending on the applied force, due to the action of the leverage springs, which allows for controlled movement of the levers with master keys.

As a measure designed to somewhat complicate the possibility of criminal tampering with master keys, in the design of the prototype lock, teeth made on levers are used. Due to these teeth, the false working positions of the suvald during the manipulation of master keys are simulated, which increases the time of opening the lock, however, these measures are not enough to radically solve the problem of protecting the castle from criminal opening.

The technical result, the achievement of which the claimed invention is directed, is to increase the resistance of locks to criminal opening by non-destructive methods.

The essence of the proposed method of unlocking the lock is that in the lock containing the deadbolt with a stop, the levers and a key with a beard act as a key on the levers, moving them from the initial position to the working position corresponding to the lock code, which makes it possible to pass the stop the bolt through the corresponding passages in the levers, and also apply the force created by the key to the bolt, moving it. Unlike the prototype, the transfer of the levers from the initial position to the working position is completed by fixing the levers in the installed working position, while the levers are put into working position and the levers are fixed in this position in a certain angular sector of turning the key under conditions of mechanical locking of the deadbolt and unlocking the deadbolt and its movement is carried out in another corner sector of the key rotation, where access to the levers is blocked.

The essence of the castle that implements the inventive method in the embodiment of the safe lock is as follows. The lock contains a bolt housed in a housing with a thrust stand installed with the possibility of reciprocating movement in the process of unlocking and locking the lock by turning the key, and levers mounted to move relative to the thrust stand of the bolt. The bolt has a figured hole with thrust portions intended for application of forces, under the action of which the bolt moves into the housing when the lock is unlocked and moves out of the housing when the lock is locked. Levers have a passage for a deadbolt stand and a thrust section for applying a displacement force on the side of the key bar during the installation of the levers in the working position corresponding to the lock code, which allows the dead end of the deadbolt to pass through the levers. Unlike the prototype, the lock contains a mechanism for moving and mechanically locking the deadbolt and setting the suvald to its initial position, made in the form of a rotary cylinder with a key groove installed in the figured hole of the deadbolt and shaped slots, with a key groove for interacting with levers and a leash for interaction with a deadbolt, as well as a protective shield that blocks access to the levers from the side of the key groove in the latter, when the lock is unlocked, in the corner sector of the key rotation. Suvalds are separated from each other and the body by friction elements, ensuring independence of their movement and maintaining the established position when removing the movement force. The curved slots of the levers having a passage for the stop bar of the deadbolt and the thrust section for applying the driving force from the side of the key beard also have a thrust section for applying force from the thrust side of the rotary cylinder when the levers are in the initial position, and the curly hole of the bolt has a thrust section , designed to interact with the leash of the rotary cylinder in the implementation of mechanical locking deadbolt. The mutual angular arrangement of the key groove, the lead and the stop of the rotary cylinder, as well as the profile of the lead of the rotary cylinder and the configuration of the figured hole of the bolt and the figured slots of the levers are made in such a way that in the first phase of unlocking the lock - the phase of withdrawal of the stop of the rotary cylinder from the interaction with the levers, corresponding to the first the angular sector of key rotation, the deadbolt is blocked from moving by the leash of the rotary cylinder, as well as levers, which are in the initial position; in the second phase of unlocking the lock - the phase of setting the levers to the working position corresponding to the second angular sector of key rotation, the levers are in interaction with the key, and the deadbolt is blocked from moving by the leash of the rotary cylinder; in the third phase of unlocking the lock - the phase of withdrawal of the key from interaction with the levers corresponding to the third angular sector of turning the key, the deadbolt is blocked from moving by the leash of the rotary cylinder, and the levers are in the working position set by the key, fixed by friction elements; in the fourth phase of unlocking the lock - the phase of unlocking and moving the bolt corresponding to the fourth angular sector of key rotation, the levers are in the working position, fixed by friction elements and a thrust stand located in the passages of the figured slots of the levers, and the bolt is in interaction with the leash of the rotary cylinder, its movement inside the case. In the first phase of locking the lock, corresponding to the reverse rotation of the key in the fourth angular sector, the levers are in the working position, fixed by friction elements and an abutment stand located in the passages of the figured slots of the levers, and the bolt is in interaction with the leash of the rotary cylinder, which extends it from the housing ; in the second phase of locking, corresponding to the reverse rotation of the key in the third angular sector, the extended deadbolt is blocked by the leash of the rotary cylinder, and the levers are in the working position fixed by the friction elements; in the third phase of locking, corresponding to the reverse rotation of the key in the second angular sector, the extended deadbolt is blocked by the leash of the rotary cylinder, and the levers are in the working position; in the fourth phase of locking, corresponding to the reverse rotation of the key in the first angular sector, the extended deadbolt is blocked by the lead of the rotary cylinder, and the levers are in interaction with the stop of the rotary cylinder, which sets the levers to the initial position.

In particular cases of the execution of this lock, the first angular sector corresponds to the angle of rotation of the key and the rotary cylinder in the range from 0 ° to 30 °, the second angular sector corresponds to the angle of rotation of the key and the rotary cylinder in the range of 30 ° to 100 °, the third angular sector corresponds to the angle of rotation key and the rotary cylinder in the range from 100 ° to 120 °, and the fourth angular sector corresponds to the angle of rotation of the key and the rotary cylinder in the range from 120 ° to 160 °.

The essence of the castle that implements the inventive method in a variant of a household door lock is as follows. The lock contains a bolt housed in a housing with a thrust stand installed with the possibility of reciprocating movement in the process of unlocking and locking the lock by turning the key, and levers mounted to move relative to the thrust stand of the bolt. The bolt has a figured hole with thrust portions intended for application of forces, under the action of which the bolt moves into the housing when the lock is unlocked and moves out of the housing when the lock is locked. Levers have a passage for a deadbolt stand and a thrust section for applying a displacement force on the side of the key bar during the installation of the levers in the working position corresponding to the lock code, which allows the dead end of the deadbolt to pass through the levers. Unlike the prototype, the lock contains a rotary cylinder with a key groove for a double-chisel key, connected by a first gear with a rotary roller designed to reset the suvald to its initial position, and a second gear with a rotary leash designed to move the bolt, as well as a protective shield, blocking access to the levers from the side of the key groove in all angular sectors of the key rotation, except for the sectors of interaction of the key with levers. The swivel leash is located in the figured hole of the bolt, the thrust sections of which are designed to interact with the swivel leash. The rotary roller is located in the corresponding figured holes of the suvald having a thrust portion for interaction with the rotary roller. The rotary cylinder is located in the corresponding figured holes of the levers with a thrust section for interaction with the key beard. Suvalds are separated from each other and the body by friction elements, ensuring independence of their movement and maintaining the established position when removing the movement force. The configuration of the figured holes of the suvald and the bolt, the profile of the rotary leash and the rotary roller, their angular position relative to the key groove of the rotary cylinder, and also the gear ratios of the gears are made in such a way that in the first phase of unlocking the lock - the phase of withdrawing the rotary roller from the interaction with the levers, corresponding to the first angular sector of turning the key in the unlocking direction, the deadbolt is blocked from movement by a rotary leash, as well as levers that are in the initial position; in the second phase of unlocking the lock - the phase of setting the levers to the working position corresponding to the second angular sector of turning the key in the unlocking direction, the levers are in interaction with the key, and the deadbolt is blocked from moving by a turning leash; in the third phase of unlocking the lock - the phase of withdrawing the key from interaction with the levers corresponding to the third angular sector of turning the key to the unlocked side, the deadbolt is blocked from movement by a rotary leash, and the levers are in the working position set by the key, fixed by friction elements; in the fourth phase of unlocking the lock - the phase of unlocking and starting to move the deadbolt, corresponding to the fourth angular sector of turning the key in the unlocking direction, the levers are in the working position fixed by the friction elements, and the deadbolt is in interaction with a rotary leash moving it inside the case; in the fifth phase of unlocking the lock - the phase of ending the movement of the bolt and setting the levers to the initial position, corresponding to the fifth angular sector of turning the key to the unlocking side, completing its full revolution, the bolt interacts with the rotary leash, and the levers with the rotary roller moving the levers from the working position in the initial. In the first phase of locking the lock - the phase of withdrawal of the rotary roller from interaction with the levers corresponding to the first angular sector of turning the key in the direction of locking, the levers are in the initial position, fixed by friction elements; in the second phase of locking the lock - the phase of setting the levers to the working position and the beginning of the movement of the deadbolt corresponding to the second angular sector of turning the key towards the locking direction, the levers are in interaction with the key, and the deadbolt is in interaction with a rotary leash that extends it from the housing; in the third phase of locking the lock - the phase of moving the bolt corresponding to the third angular sector of turning the key in the unlocked direction, the levers are in the working position set by the key, fixed by the friction elements, and the bolt is in interaction with the rotary leash moving it from the housing; in the fourth phase of locking the lock - the phase of the beginning of the locking of the deadbolt corresponding to the fourth angular sector of turning the key toward the locking direction, the extended deadbolt contacts the rotary leash, which carries out its mechanical locking, and the levers are in the working position fixed by the friction elements; in the fifth phase of locking the lock - the phase of setting the suvald to the initial position, corresponding to the fifth angular sector of turning the key in the locking direction, completing its full revolution in the opposite direction, the levers are in interaction with the rotary roller that moves the levers from the working position to the initial, and the extended bolt blocked from movement by a swivel leash.

In particular cases of this lock, the first angular sector of turning the key in the unlocked direction is in the range from 0 ° to 45 °, the second angular sector of turning the key in the unlocking direction is in the range from 45 ° to 90 °, the third angular sector of turning the key in the unlocking direction is in the range from 90 ° to 180 °, the fourth angular sector of turning the key to the unlocked side is in the range from 180 ° to 315 °, the fifth angular sector of turning the key in the unlocking direction is in the range from 315 ° to 360 °, the first angular sector is key in side well, the locking is in the range from 360 ° to 315 °, the second angular sector of turning the key to the locking side is in the range from 315 ° to 270, the third angular sector of turning the key in the locking direction is in the range from 270 ° to 90 °, the fourth angular sector turn the key in the direction of locking is in the range from 90 ° to 45 °, the fifth angular sector of turning the key in the direction of locking is in the range from 45 ° to 0 °. The first gear transmission connecting the rotary cylinder to the rotary roller has a gear ratio of 1: 1, and the second gear transmission connecting the rotary cylinder to the rotary leash is a reduction gear with a gear ratio of 2: 1. The levers are installed with the possibility of their movement in the direction perpendicular to the direction of movement of the bolt, while the function of the guides for the levers is performed by a protective screen and a cylindrical stand serving as the axis of rotation of the rotary leash.

The fundamental difference between the proposed method and the locks that implement the inventive method from the prototype and analogues is that when the lock is unlocked, the operation to transfer the levers from the initial position to the working position corresponding to the lock code is separated in time from the operation to move the bolt and ends with fixing the levers in established working position. At the same time, in the phase of transferring the levers from the initial position to the working position, it is impossible to move the bolt due to its mechanical blocking, and in the phase of unlocking and moving the bolt, direct access to the levers is blocked. Together, this makes the use of master keys for opening the lock ineffective due to the inability to simultaneously change the position of the levers and deadbolt.

The essence of the claimed inventions and the possibility of their implementation are illustrated by illustrative materials presented in figures 1-21, where:

figure 1 presents a schematic drawing of a safe lock, explaining the composition of its main elements (section in the transverse plane along the key groove, deadbolt in the extended position, the key is removed from the lock);

figure 2 is the same, a section from the side of the level;

figure 3 is an example of a housing cover of a safe lock (two projections);

figure 4 is an example of a deadlock of a safe lock (two projections);

figure 5 is an example of the implementation of the levers of the safe lock;

figure 6 is an example of a rotary cylinder safe lock (three projections);

Fig.7 is a diagram explaining the relative position of the main elements of the safe lock in the position corresponding to the beginning of the first phase of unlocking the lock, as well as the end of the fourth phase of locking the lock (on a conditional example of one levers);

on Fig - the same, in the position corresponding to the end of the second phase of unlocking the lock, as well as the beginning of the third phase of locking the lock;

figure 9 is the same, in a position corresponding to the end of the third phase of unlocking the lock, as well as the beginning of the second phase of locking the lock;

figure 10 is the same, in the position corresponding to the end of the fourth phase of unlocking the lock, as well as the beginning of the first phase of locking the lock;

11 is a schematic drawing of a household door lock explaining the composition of its main elements (section from the side of the levers, bolt in the extended position);

Fig.12 is the same, a section in the transverse plane along the key groove;

on Fig - an example of the execution of the bolt household door lock;

on Fig - an example of the implementation of the levers household door lock;

on Fig - an example of a rotary leash household door lock;

on Fig - an example of the execution of the rotary cylinder of a household door lock (two projections, without a gear);

on Fig - an example of a sleeve for placing a rotary cylinder of a household door lock (two projections);

on Fig is a diagram explaining the relative position of the main elements of the household door lock in the position corresponding to the beginning of the first phase of unlocking the lock, as well as the end of the last (fifth) phase of locking the lock (on a conditional example of one levers);

on Fig - the same, in the position corresponding to the end of the second phase of unlocking the lock;

in Fig.20 - the same, in a position corresponding to the beginning of the fourth phase of unlocking the lock;

on Fig - the same, in the position corresponding to the end of the last (fifth) phase of unlocking the lock and the beginning of the first phase of locking the lock.

The safe lock (Figs. 1-6) comprises a box-shaped case 1 with side walls 2 and a cover 3 (Figs. 1, 2, 3). A key hole 4 is made in the lid 3 for installing a key 5 with a beard. In the housing 1 there is a deadbolt 6 with a thrust stand 7 (Fig. 1, 2, 4), mounted with the possibility of reciprocating movement in the process of unlocking and locking the lock, and a set of plate levers 8, for example, six levers 8 (Fig. 1, 2, 5) mounted on a common axis 9 with the possibility of rotation around it and longitudinal movement along it.

The lock is also equipped with a mechanism for moving and mechanically locking the bolt 6 and setting the levers 8 in the initial position, made in the form of a rotary cylinder 10 with a key groove 11 for placing the key 5, a stop 12 for interacting with levers 8 and a leash 13 for interacting with the bolt 6 (Fig. .1, 2, 6). The rotary cylinder 10 is installed in the figured slots 14 of the levers 8 (figure 5) and the figured hole 15 of the bolt 6 (figure 4) with the possibility of rotation about its axis, while its lower part is located in a cylindrical recess 16, made in the bottom of the housing 1, and the upper part is located in a cylindrical recess 17, made in the cover 3 (Fig.1, 3).

The figured hole 15 in the bolt 6 (Fig. 4) has thrust portions 18 and 19 for applying forces from the side of the leash 13, under the action of which the bolt 6 moves into the housing 1 when the lock is unlocked and is pulled out of it when locking the lock, as well as section 20, interacting with the leash 13 in the implementation of the mechanical locking of the deadbolt 6 in the locked lock (figure 2, 7).

Curly slots 14 in the levers 8 have a passage 21, intended for the passage of the thrust rack 7, as well as thrust sections 22 and 23 (figure 5). The stop section 23 is designed to exert force from the stop 12 when installing the levers 8 in the initial position, in which the position of the passages 21 in the levers 8 does not coincide with the position of the stop rack 7, which provides code blocking of the deadbolt 6 (2, 7). The thrust portion 22 is designed to exert a displacement force from the side of the beard of the key 5 during the installation of the suvald 7 in the working position corresponding to the lock code, which makes it possible for the thrust stand 7 to pass through the levers 8 (Figs. 8, 9, 10).

The levers 8 are separated from each other and the housing 1 by friction elements 24, ensuring independence of their movement, in particular when they are installed in the working position when applying the moving force from the side of the key 5, and maintaining the set position when removing the moving force.

Friction elements 24 are made in the form of wear-resistant spacers, for example, made of bronze mounted on the axis 9 (Fig.1, 2). The friction elements 24 are blocked from rotation around the axis 9 due to the abutment against the wall 2 of the housing 1, while the possibility of free movement of the friction elements 24 along the axis 9 is preserved.

The levers 8 and the friction elements 24 are pressed against each other by the force created by the coil spring 25 mounted on the axis 9 (figure 1), which ensures the creation of the necessary friction forces.

In this example, the thrust stand 7 (Figs. 1, 2, 4) is made in the form of a set of plates mounted on top of each other with the formation of a figured profile corresponding to the lock code, while the levers 8 are made the same (with the same curly slots 14).

The lock is also equipped with a protective shield 26, made in the form of a segment of a hollow cylinder, mounted on the cover 3 (figure 2, 3) and blocking access to the levers 8 from the side of the key groove 11 in the latter, when unlocking, the angular sector of rotation of the rotary cylinder 10 ( 10), in which there is no mechanical blocking of the bolt 6 by the leash 13.

The profile of the leash 13, the relative angular position of the key groove 11, the leash 13 and the abutment 12 of the rotary cylinder 10, as well as the configuration of the figured hole 15 of the bolt 6 and the figured slots 14 of the levers 8 are made so that in the process of unlocking and subsequent locking of the lock, the key 5 and, accordingly, the rotary cylinder 10 passes in its angular movement through the four angular sectors of rotation corresponding to the four characteristic phases of unlocking and locking the lock, as illustrated by the schemes shown in Fig.7-10.

In the initial position - the position corresponding to the locked lock (Fig. 2, 7), the bolt 6 is in the extended position and is mechanically blocked from moving by a leash 13 located opposite the stop portion 20 of the figured hole 15 of the bolt 6, and the levers 8 are in the initial position, forcedly installed under the influence of the stop 12 on the stop section 23 of the figured slots 14 of the level 8.

Unlock the lock as follows. Through the key hole 4 of the cover 3, the key 5 is inserted into the key groove 11 of the rotary cylinder 10 and the key 5 and, accordingly, the rotary cylinder 10 are turned to the side corresponding to the unlocking of the lock (in this example, clockwise).

In the first phase of unlocking the lock - phase withdrawal of the stop 12 from the interaction with the levers 8, corresponding to the first angular sector of rotation of the key 5 and the rotary cylinder 10 (in this example, this phase corresponds to the angle of rotation in the range from 0 ° to 30 °), the bolt 6 is in extended position and blocked from movement by the leash 13, as well as levers 8, located in the initial position. In the process of implementing the first phase of unlocking the lock, the emphasis 12 is removed from contact with the levers 8, and the beard of the key 5 is brought to the thrust sections 22 of the figured slots 14 of the levers 8.

In the second phase of unlocking the lock — the phase of setting the lever 8 in the working position corresponding to the second corner sector of rotation of the key 5 and the rotary cylinder 10 (in this example, this phase corresponds to the angle of rotation in the range from 30 ° to 100 °), the levers 8 are in interaction with a key 5, acting with his beard on the thrust sections 22 of the curly slots 14 of the suvald 8, and the bolt 6 is blocked from moving by the leash 13 (Fig. 8). Under the action of the movement force created by the key 5, the levers 8 are set to the working position corresponding to the lock code, thereby allowing the thrust stand 7 to pass through the passages 21 in the levers 8. Thus, in the process of implementing the second phase of unlocking the lock, an operation is made to transfer the levers 8 from the initial position to the working position, and this operation is carried out with a mechanically locked deadbolt 6 by the leash 13.

The third phase of unlocking the lock - the phase of withdrawal of the key 5 from the interaction with the levers 8 - corresponds to the third angular sector of rotation of the key 5 and the rotary cylinder 10 (in this example, this phase corresponds to the angle of rotation in the range from 100 ° to 120 °). In the process of implementing this phase, the key 5 is removed from interaction with the levers 8 while maintaining the mechanical locking of the deadbolt 6 by the leash 13, which is brought to the stop portion 18 of the figured hole 15 of the deadbolt 8, and at the same time, the leveling lever set by the key 5 is fixed 8 due to the action of the friction elements 24. Thus, at the end of the third phase of unlocking the lock, the deadbolt 6 remains blocked by a leash 13, which is brought up to the stop portion 18 of the figured hole 15 of the deadbolt 6, and uvaldy 8 are in the operating position, a fixed friction elements 24 and their offline interaction with the key 5 (Figure 9).

In the fourth phase of unlocking the lock - the phase of unlocking and moving the bolt 6, corresponding to the fourth angular sector of rotation of the key 5 and the rotary cylinder 10 (in this example, this phase corresponds to the angle of rotation in the range from 120 ° to 160 °), the levers 8 are in the working position, fixed by the friction elements 24 and the thrust stand 7, which entered the aisles 21 of the figured slots 14 of the suvald 8, and the bolt 6 is unlocked and interacts with the leash 13, which moves it inside the housing 1 due to the force, of the bolt 6 which is fitted to the abutting portion 18 of the bolt 6. A feature of the indicated movement of the bolt 6 is that it is carried out in the absence of the possibility of direct access to the levers 8 from the side of the key groove 11 due to the protective screen 26. The presence of a protective screen 26 in this corner sector prevents the possibility of direct access to the levers 8 from the outside, which makes it impossible to control (uniquely determined by the applied impact) the change in their position using any master keys.

The end of the fourth phase of unlocking the lock corresponds to the unlocked lock. In the position corresponding to the unlocked lock, the bolt 6 is pushed inside the housing 1, the stop portion 19 of its figured hole 15 is opposite the lead 13, the levers 8 are in the working position, fixed by the friction elements 24 and the stop rack 7, which entered the passages 21 of the figured slots 14 of the levers 8, and the key 5 is located in the key groove 11 of the rotary cylinder 10 (figure 10).

Lock the lock by turning the key 5 and, accordingly, the rotary cylinder 10 in the opposite direction.

In the first phase of locking, corresponding to the reverse rotation of the key 5 and the rotary cylinder 10 in the fourth angular sector, the levers 8 are in the working position, fixed by the friction elements 24 and the thrust stand 7 located in the passages 21 of the figured slots 14 of the levers 8, and the bolt 6 is in cooperation with the leash 13, which extends from the housing 1 due to the force applied to the thrust section 19 of the figured hole 15 of the bolt 6.

In the second phase of locking, corresponding to the reverse rotation of the rotary key 5 and the cylinder 10 in the third angular sector, the extended bolt 6 is blocked by a leash 13, which entered the contact zone with the stop portion 20 of its curly slot 15, and the levers 8 are in the working position, fixed by friction elements 24 (Fig.9).

In the third phase of locking, corresponding to the reverse rotation of the key 5 and the rotary cylinder 10 in the second angular sector, the extended bolt 6 is blocked by the leash 13, and the levers 8 are in the working position (Fig. 8).

In the fourth phase of locking, corresponding to the reverse rotation of the key 5 and the rotary cylinder 10 in the first angular sector, the extended bolt 6 is blocked by the leash 13, and the levers 8 are in interaction with the stop 12 of the rotary cylinder 10, which transfers the levers 8 from the working position to the initial due to the impact on the thrust portions 23 of the curly slots 14 of the suvald 8 (Fig. 7). At the end of this phase, key 5 is removed from the lock.

Thus, unlike the prototype, when unlocking the lock under consideration, the operation of transferring the lever 8 from the initial position to the working position corresponding to the lock code is separated in time from the operation of moving the bolt 6. Moreover, in the phase of transferring the lever 8 from the initial position to the working it is impossible to move the bolt 6 due to its mechanical blocking by the leash 13, and in the unlocking and moving phase of the bolt 6, access to the levers 8 is blocked by a protective shield 26, which makes it impossible to use any master keys for opening digging of the castle due to the inability to simultaneously carry out a controlled (unambiguously determined by the applied effect) change in the position of the suvald 8 and the bolt 6. All this significantly increases, compared with the prototype, the resistance of the considered castle to criminal opening.

The household door lock (Figs. 11-17) comprises a box-shaped case 27 closed by a lid 28. In the case 27 there is a deadbolt 29 with an abutment stand 30, mounted with the possibility of reciprocating movement in the process of unlocking and locking the lock by turning the double-sided key 31 by one revolution, as well as a set of plate levers 32, for example, eight levers 32, mounted for movement relative to the bolt 29 and its thrust post 30 in the direction perpendicular to the direction of movement of the bolt 29 (fi D.11, 12).

In this example, the thrust post 30 of the bolt 29 is made in the form of a set of plates mounted on top of each other with the formation of a shaped profile corresponding to the lock code (Fig.13), while the levers 32 are made the same (Fig.14). The thrust post 30 is located in the figured holes 33 of the leveling 32, in which there is a passage 34 for the passage of the thrust post 30 (11, 14).

The lock also contains a rotary cylinder 35 with a key groove 36 for the key 31 and a drive gear 37 fixed thereon, connected to the driven gear 38 of the drive of the rotary roller 39, designed to reset the levers 32 to the initial position (11, 12), and with the driven gear 40 of the drive of the rotary leash 41, designed to move the bolt 29 (11, 12, 15).

In this example, the first gear transmission connecting the rotary cylinder 35 to the rotary roller 39 has a gear ratio of 1: 1, and the second gear transmission connecting the rotary cylinder 35 to the rotary leash 41 is a reduction gear with a gear ratio of 2: 1.

The rotary cylinder 35 (Fig. 12, 16) is fixed on the inner side of the cover 28 in the sleeve 42 (Fig. 12, 17), which also carries a protective shield 43, made in the form of a segment of a circular cylinder, blocking access to the levers 32 from the key the groove 36 in all angular sectors of rotation of the key 31 and the rotary cylinder 35, with the exception of the sectors of interaction of the key 31 with the levers 32.

The protective screen 43 and the rotary cylinder 35 are located in the figured holes 44 of the suvald 32 (11, 14). In the figured holes 44 there is a stop portion 45 (Fig. 14) for applying efforts of movement from the side of the beard of the key 31 during installation of the levers 32 to the working position corresponding to the lock code, in which the stop pillar 30 can pass through the passage 34 in the figured holes 33 suvald 32. The protective screen 43, located in the figured holes 44 of the suvald 32, also performs an additional function of the guide for the levers 32 (11, 14).

The rotary cylinder 35 intersects the bolt 29 through the corresponding groove 46 (Fig.11, 13).

A rotary lead 41 with a gear wheel 40 (Fig. 15) is mounted on a cylindrical strut 47 (Fig. 11, 12) serving as the axis of rotation of the rotary leash 41. The strut 47 is located in the grooves 48 of the leveling 32 (Fig. 11, 14), performing this is the function of the second guide for the levers 32. The rotary lead 41 is located in the figured hole 49 of the bolt 29 (11, 13), in which there are two thrust sections 50 (right and left), designed to exert force from the side of the rotary lead 41, under the action of which the bolt 29 moves into the inside of the housing 27 when unlocking the lock and flies out of it when locking the lock, as well as the stop portion 51, designed to mechanically lock the deadbolt 29 in the locked lock, due to the interaction of the rotary leash 41 with the stop portion 51.

The rotary roller 39 is located in the groove 52 of the bolt 29 (Fig. 11, 13) and in the figured holes 53 of the leveling 32 (Fig. 11, 14) having a thrust portion 54 for engaging with the rotary roller 39.

The levers 32 are separated from each other and the housing 27 by friction elements 55 (Fig. 11, 12), ensuring independence of movement of the levers 32, in particular, when they are installed in the working position under the influence of the movement force created by the key 31, and maintaining the established position when removing moving effort.

Friction elements 55 are made in the form of wear-resistant washers, for example made of bronze, mounted on a cylindrical stand 47 with the possibility of free movement along it. The necessary friction force between the levers 32 and the friction elements 55 is provided by a cylindrical spring 56 compressing them, mounted on a cylindrical strut 47 (Fig. 12).

The configuration of the figured holes 33, 44, 53 of the suvald 32 and the figured hole 49 of the bolt 29, the profile of the rotary leash 41 and the rotary roller 39, their angular position relative to the key groove 36 of the rotary cylinder 35 are made in such a way that five are unlocked and locked characteristic phases of unlocking the lock and five characteristic phases of locking the lock (see diagrams shown in Figs. 18-21).

In the initial position - the position corresponding to the locked lock (Fig. 11, 18), the bolt 29 is in the extended position and is mechanically blocked from movement by a rotary leash 41 located opposite the stop portion 51 of the figured hole 49 of the bolt 29, and the levers 32 are in the initial position forcedly installed under the influence of the rotary roller 39 on the thrust portion 54 of the figured holes 53 of the suvald 32, in which the deadlock 29 is coded by blocking its thrust stand 30 in the figured holes Yach 33 Suvald 32.

To unlock the lock, insert the key 31 into the key groove 36 of the rotary cylinder 35 and turn the key 31 clockwise.

In the first phase of unlocking the lock — the phase of withdrawing the rotary roller 39 from interaction with the levers 32, corresponding to the first angular sector of turning the key 31 to the unlocking side (in this example, this phase corresponds to a rotation angle in the range from 0 ° to 45 °), the bolt 29 is locked from movement of the rotary leash 41, as well as levers 32, located in the initial position (11, 18). In the process of implementing the first phase of unlocking the lock, the rotary roller 39 is brought out of contact with the thrust portions 54 of the suvald 32, and the beard of the key 31 is brought to the abutment portion 45 of the figured slots 44 of the suvald 32.

In the second phase of unlocking the lock - the phase of setting the suvald 32 in the working position corresponding to the second angular sector of turning the key 31 towards the unlocking side (in this example, this phase corresponds to the angle of rotation in the range from 45 ° to 90 °), the levers 32 are in interaction with the key 31, acting with its first beard on the stop portion 45 of the figured holes 44 of the suvald 32, and the bolt 29 is blocked from moving by the rotary leash 41 (Fig. 19). Under the action of the movement force created by the key 31, the levers 32 are set to the working position corresponding to the lock code, thereby allowing the thrust post 30 to pass through the passage 34 in the figured holes 33 of the levers 32. Thus, in the process of the second phase of unlocking the lock, the operation to transfer the suvald 32 from the initial position to the working position, and this operation is carried out with a mechanically locked deadbolt 29 with a rotary leash 41.

The third phase of unlocking the lock — the phase of withdrawing the key 31 from the interaction with the levers 32 — corresponds to the third angular sector of turning the key 31 towards the unlocking side (in this example, this phase corresponds to a rotation angle ranging from 90 ° to 180 °). In the process of this phase, the key 31 is removed from interaction with the levers 32 while retaining the mechanical locking of the deadbolt 29 by a rotary lead 41, which is then brought to the right thrust portion 50 of the figured hole 49 of the deadbolt 29, and at the same time, the working set by the key 31 is fixed the position of the levers 32 due to the action of the friction elements 55. Thus, the third phase is characterized by the fact that the bolt 29 is blocked from moving by the rotary leash 41, and the levers 32 are in the set key 31 the working position fixed by the friction elements 55.

In the fourth phase of unlocking the lock — the unlocking phase and the beginning of the movement of the bolt 29, corresponding to the fourth angular sector of turning the key 31 towards the unlocking side (in this example, this phase corresponds to a rotation angle ranging from 180 ° to 315), the levers 32 are in the working position, locked friction elements 55, and the bolt 29 is unlocked and is in interaction with the rotary leash 41, which carries out its movement inside the housing 27 due to the force applied to the right thrust section 50 of the figure from verst 49 (Fig.20). A feature of this movement of the bolt 29 is that it is carried out in the absence of the possibility of direct access to the levers 32 from the side of the key groove 36 due to the protective shield 43. The presence of a protective shield 43 prevents the direct access to the levers 32 from the outside, which makes it impossible to control (definitely determined by the applied effect) a change in their position using any master keys.

The fifth phase of unlocking the lock — the phase of the end of the movement of the bolt 29 and the installation of the suvald 32 in the initial position — corresponds to the fifth angular sector of turning the key 31 to the unlocking side (in this example, this phase corresponds to a rotation angle ranging from 315 ° to 360 °). During this phase, the bolt 29 moves inside the housing 27 due to the force exerted by the rotary leash 41 to the right thrust portion 50 of the figured hole 49 of the bolt 29, and the levers 32 are moved from the working position to the initial position due to the force exerted from the rotary side the roller 39 to the thrust sections 54 of the figured holes 53 of the suvald 32.

The end of the fifth phase of unlocking the lock (Fig.21) corresponds to the unlocked lock. In the position corresponding to the unlocked lock, the bolt 29 is pushed inside the housing 27, the rotary leash 41 is in contact with the right stop portion 50 of the figured hole 49 of the bolt 29, and the levers 32 are in the initial position, while in contact with the rotary roller 39. In this position, the key 31 removed from the key groove 36 of the rotary cylinder 35.

To lock the lock, insert the key 31 into the key groove 36 of the rotary cylinder 35 and turn the key 31 counterclockwise.

The first phase of locking the lock - the phase of withdrawal of the rotary roller 39 from interacting with the levers 32, corresponds to the first angular sector of turning the key 31 towards the locking direction (in this example, this phase corresponds to a rotation angle ranging from 360 ° to 315 °). In the process of this phase, the swivel roller 39 is brought out of interaction with the levers 32, which maintain the established initial position due to the action of the friction elements 55, and the swivel lead 41 is rotated in the direction of the left stop portion 50 of the figured hole 49 of the bolt 29, leaving the contact with the right stop section 50.

In the second phase of locking the lock - the phase of setting the suvald 32 in the working position and the beginning of the movement of the bolt 29, corresponding to the second angular sector of turning the key in the direction of locking (in this example, this phase corresponds to the angle of rotation in the range from 360 ° to 270), the levers 32 are in interacting with the key (with its second beard), and the deadbolt 29 is in interaction with the rotary leash 41, which extends it from the housing 27 by applying force to the left thrust portion 50 of the figured hole 49 of the deadbolt 29. Under the action tviem displacement force generated by the key 31, levers 32 are installed in working position, corresponding to the code lock, thereby allowing the passage of the thrust strut 30 extending through holes 34 in the braces 33 of levers 32 during extension of the bolt 29 from the housing 27.

In the third phase of locking the lock - the phase of movement of the bolt 29, corresponding to the third angular sector of turning the key 31 towards the locking side (in this example, this phase corresponds to the angle of rotation in the range from 270 ° to 90 °), the levers 32 are in the working position set by the key 31, fixed by the friction elements 55, and the bolt 29 is in interaction with the rotary leash 41, which carries out its movement from the housing 27 due to the force applied to the left thrust section 50 of the figured hole 49 of the bolt 29.

In the fourth phase of locking the lock - the phase of the beginning of the locking of the bolt 29, corresponding to the fourth angular sector of turning the key 31 to the locking side (in this example, this phase corresponds to the angle of rotation from 90 ° to 45 °), the extended bolt 29 is in contact with the rotary lead 41 in the area of its thrust section 51, thereby carrying out mechanical locking, and the levers 32 are in the working position, fixed by the friction elements 55.

The fifth phase of locking the lock - the phase of installing the suvald 32 in the initial position - corresponds to the fifth angular sector of turning the key 31 towards the locking side (in this example, this phase corresponds to the angle of rotation in the range from 45 ° to 0 °). During the implementation of this phase, the levers 32 are moved from the working position to the initial position due to the force exerted by the rotary roller 39 to the thrust portions 54 of the curved holes 53 of the levers 32, while the extended bolt 29 is blocked from movement by the rotary leash 41.

The end of the fifth phase of locking the lock corresponds to the locked lock (Fig. 18). At the end of this phase, the bolt 29 is in the extended position and is mechanically blocked from moving by a pivoting lead 41 located opposite the stop portion 51 of the figured hole 49 of the bolt 29, and the levers 32 are in the initial position, forcibly set under the influence of the rotary roller 39 on the stop sections 54 of the figured the slots 53 of the suvald 32, thereby locking the deadbolt 29 by blocking the thrust post 30 in its figured holes 33. At the end of this phase, the key 31 is removed from the lock .

Thus, when unlocking the lock considered, the operation of transferring the suvald 32 from the initial position to the working position corresponding to the lock code is separated in time from the operation of moving the bolt 29. In this case, in the phase of moving the suvald 32 from the initial position to the working position during unlocking it is impossible to move the bolt 29 due to its mechanical blocking by the rotary leash 41, and in other phases of unlocking the lock, including in the unlocking and moving phase of the bolt 29, access to the levers 32 is blocked by a protective screen m 43, which makes it unsuccessful to use any master keys to open the lock due to the inability to simultaneously carry out a controlled (unambiguously determined by the applied impact) change in the position of the suvald 32 and the bolt 29. All this significantly increases the resistance of the considered lock to criminal opening.

The above shows that the claimed inventions are feasible and ensure the achievement of a technical result, which consists in increasing the resistance of locks to criminal opening by non-destructive methods.

Information sources

1. SU 168141 A1, E05B 25/02, publ. 01/01/1965.

2. SU 370329 A1, E05B 21/02, publ. 02/15/1973.

3. SU 1227784 A1, E05B 25/06, publ. 04/30/1986.

4. SU 1481364 A1, E05B 25/00, publ. 05/23/1989.

5. RU 2034973 C1, E05B 35/08, publ. 05/10/1995.

6. RU 2174177 C1, E05B 25/00, publ. 09/27/2001.

7. US 4462230, E05B 25/00, publ. 07/31/1984.

8. US 5502990, E05B 25/00, publ. 04/02/1996.

9. US 1935225, U.S. C1.70-75, publ. 11/14/1933.

10. US 3884058, E05B 21/00, publ. 05/20/1975.

Claims (7)

1. The method of unlocking the lock, which consists in the fact that in the lock containing the deadbolt, the levers and a key with a beard act as a key on the levers, moving them from the initial position to the working position corresponding to the lock code, which makes it possible to pass persistent deadbolt stands through the corresponding passages in the levers, and also apply the force created by the key to the deadbolt, moving it, characterized in that the transfer of the levers from the initial position to the working one is completed by fixing the levers to the mouth a new working position, and the suvald is moved to the working position and the suvald is fixed in this position in a certain angular sector of key rotation under conditions of mechanical locking of the deadbolt movement, and the unlocking of the deadbolt and its movement are carried out in another angular key rotation sector, where access to the levers is blocked . 2. A lock comprising a bolt housed in a housing with a thrust stand installed with the possibility of reciprocating movement in the process of unlocking and locking the lock by turning the key and levers mounted to move relative to the thrust stand of the bolt, the bolt having a figured hole with thrust sections intended for application of forces, under the action of which the bolt moves into the case when the lock is unlocked and moves out of the case when the lock is locked, and the suvald s have a passage for a deadbolt stop and a thrust portion for applying a displacement force from the key barb during the installation of the levers into the working position corresponding to the lock code, which makes it possible for the deadbolt to pass through the levers, characterized in that the lock contains a movement mechanism and mechanical locking of the deadbolt and installation of the suvald in the initial position, made in the form of a rotary cylinder with a key pa installed in the curly hole of the deadbolt and curly slots a key for placing the key, an emphasis for interacting with levers and a leash for interacting with the deadbolt, as well as a protective screen that blocks access to the levers from the side of the key groove in the latter when the lock is unlocked in the corner sector of the key rotation, while the levers are separated from each other and the body by friction elements that ensure independence of their movement and preservation of the established position when removing the movement force, curly slots of the levers having a passage for a deadbolt stand and a thrust section for application The forces of movement from the side of the key beard also have a thrust portion designed to apply force from the thrust side of the rotary cylinder when the levers are set to the initial position, and the figured bolt hole has a thrust portion designed to interact with the lead of the rotary cylinder when mechanically locking the bolt, moreover, the relative angular location of the key groove, the lead and the stop of the rotary cylinder, as well as the profile of the lead of the rotary cylinder and the configuration of the figured hole the bolt and the figured slots of the levers are made in such a way that in the first phase of unlocking the lock — the phase of withdrawing the stop of the rotary cylinder from interacting with the levers corresponding to the first angular sector of turning the key, the bolt is blocked from moving by the leash of the rotary cylinder, as well as levers in the initial position, in the second phase of unlocking the lock - the phase of setting the suvald to the working position corresponding to the second angular sector of key rotation, the levers are in interaction with the key, and the deadbolt it is secured from moving the rotary cylinder by the leash, in the third phase of unlocking the lock - the phase of removing the key from interaction with the levers corresponding to the third angular sector of turning the key, the deadbolt is blocked from moving by the leash of the rotary cylinder, and the levers are in the working position set by the key, fixed by the friction elements, in the fourth phase of unlocking the lock - the phase of unlocking and moving the bolt corresponding to the fourth angular sector of key rotation, the levers are in working position and fixed by frictional elements and an abutment stand located in the passages of the figured slots of the suvald, and the bolt is in interaction with the leash of the rotary cylinder, which moves it inside the case, in the first phase of locking the lock corresponding to the reverse rotation of the key in the fourth angular sector, the levers are in the working position, fixed by friction elements and a thrust stand located in the passages of the figured slots of the suvald, and the deadbolt is in interaction with the lead of the turn of the cylinder in the second phase of locking, corresponding to the reverse rotation of the key in the third angular sector, the extended deadbolt is locked by the leash of the rotary cylinder, and the levers are in the working position, fixed by the friction elements, in the third phase of locking the lock, corresponding to the reverse turning the key in the second angular sector, the extended bolt is blocked by the leash of the rotary cylinder, and the levers are in the working position, in the fourth phase of locking the lock, corresponding to the reverse rotation of the key in the first angular sector, the extended deadbolt is blocked by the leash of the rotary cylinder, and the levers are in interaction with the stop of the rotary cylinder, which sets the levers to the initial position. 3. The lock according to claim 2, characterized in that the first angular sector corresponds to the angle of rotation of the key and the rotary cylinder in the range from 0 to 30 °, the second angular sector corresponds to the angle of rotation of the key and the rotary cylinder in the range from 30 to 100 °, the third angular the sector corresponds to the angle of rotation of the key and the rotary cylinder in the range from 100 to 120 °, and the fourth corner sector corresponds to the angle of rotation of the key and the rotary cylinder in the range from 120 to 160 °. 4. A lock comprising a bolt housed in a housing with a thrust stand installed with the possibility of reciprocating movement in the process of unlocking and locking the lock by turning the key, and levers mounted to move relative to the thrust stand of the bolt, the bolt having a figured hole with thrust sections intended for application of forces, under the action of which the bolt moves into the case when the lock is unlocked and moves out of the case when the lock is locked, and the suvald They have a passage for a deadbolt stop and a thrust portion for applying a displacement force from the key barb during the installation of the leveling lever in the working position corresponding to the lock code, which allows the deadbolt to pass through the leveling blocks, characterized in that the lock contains a rotary cylinder with a key groove for a double-wrench, connected by a first gear with a swivel roller designed to reset the suvald to its initial position, and a second gear with a swivel vodka designed to move the bolt, as well as a protective screen that blocks access to the levers from the side of the key groove in all angular sectors of the key rotation, except for the sectors of interaction of the key with the levers, while the rotary leash is located in the figured hole of the bolt, the stop sections of which are designed for interaction with a rotary leash, the rotary roller is located in the corresponding figured holes of the suvald having a thrust portion for interaction with the rotary roller, and the rotary the cylinder is located in the corresponding figured holes of the suvald with a thrust section for interacting with the beard of the key, while the levers are separated from each other and the body by friction elements that ensure independence of their movement and maintaining the established position when removing the movement force, and the configuration of the figured holes of the suvald and deadbolt, profile rotary leash and rotary roller, their angular position relative to the key groove of the rotary cylinder, as well as gear ratios of gears made in such a way that in the first phase of unlocking the lock — the phase of withdrawing the rotary roller from interacting with the levers corresponding to the first angular sector of turning the key in the unlocking direction, the deadbolt is blocked from moving by the rotary leash, as well as the levers in the initial position in the second unlocking phase lock - the phase of setting the suvald in the working position corresponding to the second angular sector of turning the key towards unlocking, the levers are in interaction with the key, and the deadbolt is locked from with a rotary leash, in the third phase of unlocking the lock — the phase of removing the key from interaction with the levers corresponding to the third angular sector of turning the key to the unlocked side, the bolt is blocked from moving by the rotary leash, and the levers are in the working position set by the key, fixed by the friction elements, in the fourth the unlocking phase - the unlocking phase and the beginning of the movement of the deadbolt, corresponding to the fourth angular sector of turning the key in the unlocking direction, the levers are in in the same position, fixed by friction elements, and the bolt is in interaction with a rotary leash that moves it inside the case, in the fifth phase of unlocking the lock - the phase of the end of the bolt movement and setting the levers to the initial position, corresponding to the fifth angular sector of turning the key towards unlocking, ending its full revolution, the bolt interacts with the rotary leash, and the levers with a rotary roller, moving the levers from the working position to the initial one, in the first locking phase the lock - the phase of withdrawal of the rotary roller from the interaction with the levers corresponding to the first angular sector of turning the key in the direction of locking, the levers are in the initial position fixed by the friction elements, in the second phase of locking the lock - the phase of setting the levers in working position and the beginning of the movement of the bolt corresponding to the second the angular sector of turning the key in the direction of locking, the levers are in interaction with the key, and the deadbolt is in interaction with the rotary leash carrying it in moving out of the case, in the third phase of locking the lock - the phase of moving the bolt corresponding to the third angular sector of turning the key to the unlocked side, the levers are in the working position set by the key, fixed by the friction elements, and the bolt is in interaction with the rotary leash moving from the case , in the fourth phase of locking the lock - the phase of the start of locking the deadbolt, corresponding to the fourth angular sector of turning the key in the direction of locking, the extended deadbolt contacts a rotary leash, which mechanically locks it, and the levers are in the working position, fixed by friction elements, in the fifth phase of locking the lock - the phase of setting the levers in the initial position, corresponding to the fifth angular sector of turning the key in the locking direction, completing its complete revolution in the opposite direction, the levers are in interaction with the rotary roller, moving the levers from the working position to the initial one, and the extended bolt is blocked from moving by the rotary leash ohm 5. The lock according to claim 4, characterized in that the first angular sector of turning the key in the unlocked direction is in the range from 0 to 45 °, the second angular sector of turning the key in the unlocking direction is in the range from 45 to 90 °, the third angular sector of rotation of the key in the unlocking direction is in the range of 90 to 180 °, the fourth angular sector of turning the key in the unlocking direction is in the range of 180 to 315 °, the fifth angular sector of turning the key in the unlocking direction is in the range of 315 to 360 °, the first angular sector turn the key in the direction of locking ranges from 360 to 315 °, the second angular sector of turning the key to the locking side is in the range from 315 to 270 °, the third angular sector of turning the key to the locking side is in the range from 270 to 90 °, the fourth angular sector of turning the key to the side locking is in the range from 90 to 45 °, the fifth angular sector of turning the key in the direction of locking is in the range from 45 to 0 °. 6. The lock according to claim 4, characterized in that the first gear transmission connecting the rotary cylinder to the rotary roller has a gear ratio of 1: 1, and the second gear transmission connecting the rotary cylinder to the rotary leash is a reduction gear with a gear ratio of 2: one. 7. The lock according to claim 4, characterized in that the levers are installed so that they can be moved in a direction perpendicular to the direction of movement of the bolt, while the guides for the levers perform the function of the guards and a cylindrical stand serving as the axis of rotation of the rotary leash.

Images