RU2237141C2 - Lock code mechanism - Google Patents

Abstract

FIELD: locksmith's work, concerns a lock mechanism.

SUBSTANCE: the mechanism has a body with a central hole, movable axle with a calibrated scale provided with spring-loaded pins and a catch installed in the body central hole, set of code disks installed on the movable axle, drive of the locking device provided with a spring-loaded key and a pusher installed on a rotary axle, latches, hinge-mounted on the body, and braking plates. The lock code mechanism is provided with a set of code disks instlled on the movable axle for rotary motion, separated from one another by braking plates fixed on the body from turning and spring-loaded in the axial direction, each code disk is made composite consisting of an outer and inner rings, interconnected for stepless turn relative to each other.

EFFECT: enhanced secrecy and more convenient in use.

4 cl, 6 dwg

Description

The invention relates to hardware, in particular to locks with a code system.

The secret castle is known by A.S. 1013620, comprising a beaker with a longitudinal groove for accommodating locking means, mounted in the beaker with a rotatable housing, an axis with a set of code disks mounted on it, on the surface of which recesses for the locking means are made, a valve and a control means. A disadvantage of the known secret lock is its low secrecy, due to the presence of a limited number of axial holes in the code disks that determine the secrecy of the castle. The second disadvantage of this lock is that changing the lock code requires complete disassembly and assembly of the lock, which creates great inconvenience when using the lock.

According to the achieved result, the closest similar technical solution is the code mechanism of the lock according to AS 1652494, comprising a shaft located in the housing with a type-setting disk fixed at the end, code rings located on the shaft with the possibility of rotation, each of which has a recess on the inner surface, and a tooth blocking the bar installed on the outer surface, which can be placed in the recesses of the code rings, a roller mounted parallel to the shaft with the possibility of discrete rotation by means of a ratchet connected with the shaft, and working stops distributed around the circle for interacting with the teeth of the code rings, the stop of the type dial and behind orny mechanism cooperating with the locking strap. A disadvantage of the known code mechanism of the lock is its low secrecy, due to the presence of a limited number of positions of a type-setting disk with a shaft bearing code rings that determine the security of the code mechanism of the lock. The second drawback of this lock code mechanism is that changing the code requires complete disassembly and assembly of the code mechanism, which creates great inconvenience when using a lock with this code mechanism.

The purpose of the invention is to increase the secrecy and convenience of using the castle. This goal is achieved in that the proposed lock code mechanism, comprising a housing with a central hole, a movable axis with a calibrated scale, equipped with spring fingers and a latch mounted in the central hole of the housing, a set of code disks mounted on the movable axis, a locking device drive equipped with a spring-loaded a key and a pusher mounted on a rotary axis, dogs mounted pivotally on the housing, and brake plates, equipped with a set of code disks mounted on p the movable axis with the possibility of rotational movement, separated between each other by brake plates and spring-loaded in the axial direction, fixed on the housing against rotation, each code disk is made integral, consisting of outer and inner rings interconnected with the possibility of stepless rotation of the rings relative to each other, and equipped with an asymmetric code groove made on the landing hole, and a locking groove made on the outer forming surface of the code disk, barn code discs mounted asymmetric steer code slots around the vertical axis by an angle of 180 °. The movable axis has two degrees of mobility and is equipped with spring-loaded fingers with teeth made on the protruding end of the fingers, mounted with a rotation of the teeth relative to each other around the vertical axis by an angle of 180 ° with the possibility of interaction of the teeth with asymmetric code grooves of the code disks, and on the cylindrical surface of the movable axis made a longitudinal groove and an annular prismatic groove for interaction with the drive locking device. The drive of the locking device is mounted on the movable axis with the possibility of limited rotation and is equipped with a spring-loaded key and a pusher installed in radial grooves on the front end of the rotary sleeve of the drive of the locking device, with the possibility of interaction, respectively, with a longitudinal groove and an annular prismatic groove of the movable axis, and on the front the end of the rotary sleeve is made of an annular groove intersecting with radial grooves to accommodate the protrusions made on the dogs. Dogs are pivotally mounted on the housing and are provided with two protrusions interacting with a spring-loaded key and a pusher of the drive of the locking device, and one dog is additionally equipped with a locking shelf interacting with the locking grooves of the code disks.

Compared with the closest similar solution, the claimed technical solution has the following distinctive features:

- code disks are made integral, consisting of outer and inner rings interconnected with the possibility of stepless rotation of the rings relative to each other, and are equipped with asymmetric code grooves made on the landing hole, and locking grooves made on the outer forming surface of the code disks;

- half of the code disks are installed with the rotation of the asymmetric code grooves around the vertical axis at an angle of 180 °;

- code disks are divided among themselves by brake plates and spring-loaded in axial direction;

- the movable axis has two degrees of mobility and is equipped with spring-loaded fingers with teeth interacting with asymmetric code grooves of the code disks;

- the drive of the locking device is mounted on the movable axis with the possibility of limited rotation and is equipped with a spring-loaded key and a pusher interacting with the rotary axis and the dogs;

- dogs are pivotally mounted on the lock case with the ability to interact with code disks and a locking device drive.

Therefore, the claimed technical solution meets the requirement of "NOVELTY."

When implementing the invention, the secrecy and convenience of using the lock are increased due to the use of code disks of a composite design equipped with code and lock grooves, which allow increasing the number of code combinations by continuously changing the position of the code and lock grooves relative to each other, which determine the security of the lock code mechanism. In the proposed embodiment, the design of the lock code mechanism when using a scale calibrated for 100 divisions, the number of combinations of one code disk corresponds to 10 ² , and in the presence of six code disks, the number of combinations reaches 10 ¹² . The use of spring-loaded fingers with teeth mounted on the movable axis with the possibility of interacting with the code grooves of the code disks, and a dog with a locking shelf interacting with the locking grooves of the code disks, allows you to change the lock code by turning the code groove relative to the locking groove of the code disks in accordance with the newly dialed code without disassembling the lock, which ensures ease of use of the lock.

Therefore, the claimed technical solution meets the requirement of “POSITIVE EFFECT”.

For each distinctive essential feature, a search is made for known technical solutions of the lock code mechanisms. In known designs of locks with a code mechanism, as a rule, the secrecy of locks is determined by the presence of a limited number of code grooves or holes located around the circumference of the code disks, which determine the number of code combinations, which limits the security of the code lock mechanism, and changing the code of the locks is associated with partial or complete disassembly castle, which creates significant inconvenience to use the castle. In the proposed technical solution, these drawbacks are eliminated through the use of a set of code disks of a composite structure, consisting of outer and inner rings interconnected with the possibility of stepless rotation relative to each other, equipped with code and locking grooves, which allow to increase the number of code combinations by continuously changing the position of the code and locking grooves relative to each other, determining the secrecy of the code mechanism of the lock.

The use of a movable axis equipped with spring-loaded fingers with teeth set to interact with the code grooves of the code disks, allowing the inner rings to rotate steplessly relative to the outer rings, which are locked from rotation by a dog equipped with a locking shelf and pivotally mounted on the lock case to interact with locking grooves code disks, which allows changing the lock code without disassembling it. The drive of the locking device is mounted on the movable axis with the possibility of limited rotation and is equipped with a spring-loaded key and a pusher interacting with the movable axis and the dogs of the lock.

Thus, the above characteristics ensure the proposed technical solution meets the requirement of "SIGNIFICANT DIFFERENCES".

The invention is illustrated by drawings.

Figure 1 shows the design of the code mechanism of the lock; figure 2 is a section aa in figure 1; figure 3 is a view along arrow B in figure 1; figure 4 is a section bb in figure 1; figure 5 shows the design of the code disk; in Fig.6 is a section GG in Fig.5.

The lock code mechanism comprises a housing 1 with a central hole, inside of which annular grooves 2 are made; a movable axis 3 installed in the central hole of the housing 1 with two degrees of mobility, equipped with a scale 4 calibrated for 100 divisions with a handle 5, two spring-loaded fingers 6 with teeth 7 mounted in the radial holes of the axis and fixed by a stopper 8 with the teeth 7 turned relative to each other at an angle of 180 ° with the possibility of limited movement in the radial direction, the latch 9 and the stop 10, and on the cylindrical surface of the axis a longitudinal groove 11 is made, the axis of which coincides with the zero mark of the scale 4, and the rings I groove 12 of prismatic shape; code disks 13 mounted on the movable axis 3 with the possibility of rotational movement, made up of outer 14 and inner 15 rings connected by two cheeks 16 by means of rivets 17 with the possibility of stepless rotation of the rings 14 and 15 relative to each other, moreover, in the mounting hole of the code disk is made asymmetric code groove 18, and a locking groove 19 is made on the forming outer surface; brake plates 20 mounted between the code disks 13 on the axles 21 mounted on the housing 1; an intermediate ring 22 mounted on the movable axis 3; a pressure ring 23 mounted on the axis 3 and spring-loaded with a cup spring 24, providing a fixation of the position of the code rings 13 from arbitrary rotation; a locking device drive, consisting of a rotary sleeve 25 with a stop 26, in the radial grooves of which there is a key 27 with a groove 28, spring-loaded with a spring 29, and a pusher 30 with a groove 31 that can interact with the groove 11 and the annular groove 12 of the movable axis 3, respectively at the front end of the sleeve there is an annular groove 32 intersecting with radial grooves; a supporting washer 33 with windows 34 and 35 installed inside the housing 1 and acting as a second support of the movable axis 3; a dog 36 pivotally mounted on an axis 37 fixed in the housing 1, provided with a locking shelf 38 cooperating with locking grooves 19 of the code disks 13, a protrusion 39 interacting with a groove 28 of the key 27, and a protrusion 40 interacting with the pusher 30; a dog 41, pivotally mounted on an axis 42, mounted in the housing 1, provided with a protrusion 43, interacting with the pusher 30, and a protrusion 44, interacting with the groove 28 of the key 27 and the annular groove 32 of the rotary sleeve 25; a cover 45 with stops 46 mounted on the rear end of the housing 1.

The code mechanism of the lock operates as follows.

To unlock the lock, the dial 5 dials the code by setting the locking grooves 19 of each code disk 13 opposite the locking shelf 38 of the dog 36, which corresponds to the position of the report point made on the housing 1. In this case, the code grooves 18 of each code disk 13 correspond to the numbers of the code dialed. In the proposed version of the lock code mechanism, the code consists of six numbers, which corresponds to the number of code disks. To enter the code, the handle 5 moves in the axial direction the movable axis 3 to the first level, which corresponds to the position of the latch 9 in the first groove 2 on the side of the handle. In this position, the spring fingers 6 occupy a position opposite the first and fourth code disks 13, and the pusher 30 from the annular groove 12 of the movable axis 3, interacting with the protrusion 40, raises the dog 36 and removes the locking shelf 38 from the locking grooves 19, providing a guaranteed gap between the forming outer surface of the code disks 13 and the locking conductive flange 38 and the protrusion 39 of the key 27 lifts the spring-loaded, bringing it out of the longitudinal groove 11, and blocks rotation of the drive sleeve 25 of the locking device. Turning the handle 5 with the movable axis 3 and the scale 4 clockwise, the first spring-loaded finger 6 engages the tooth 7 with the code groove 18 of the first code disk 13, rotates it to the position corresponding to the first code number, and is controlled on a scale of 4. In this the second spring-loaded finger 6 slides inside the hole of the fourth code disk 13. To dial the second number of the code, the handle 5 is rotated counterclockwise, while the second spring-loaded finger 6 engages the tooth 7 with the code groove 18 of the fourth code disk 1 3, turns it to the position corresponding to the second code number, and is controlled on a scale 4. After dialing two code numbers, the handle 5 moves the movable axis 3 in the axial direction to the second level, which corresponds to the position of the latch 9 in the second groove 2. In this position, the spring-loaded fingers 6 occupy a position opposite the second and fifth code disks 13. Having performed the actions with the handle 5 similarly to the actions at the first level, they dial the third and fourth number of the code. After dialing the third and fourth numbers of the code, the handle 5 moves in the axial direction the movable axis 3 to the third level, which corresponds to the position of the latch 9 in the third groove 2. In this position, the spring fingers 6 occupy a position opposite the third and sixth code rings 13. Performing actions with the handle 5 similarly to the actions at the first and second levels, the fifth and sixth numbers of the code are dialed. After typing the code, the handle 5 moves in the axial direction the movable axis 3 in the opposite direction until it stops. In this position, the spring-loaded fingers 6 go out of interaction with the code disks 13, the pusher 30 is aligned with the annular groove 12, rotating the movable axis 3 clockwise, the key 27 is aligned with the longitudinal groove 11, and under the action of the spring 29, the pusher 30 is lowered into the annular groove 12, the spring key 27 is lowered into the longitudinal groove 11, and the locking shelf 38 enters the locking grooves 19 of the code rings 13 and blocks them from turning. If the code is entered incorrectly, the locking shelf 38 will not enter the locking grooves 19 and will abut against the outer forming surface of the incorrectly set code disk 13, as a result of which the spring key 27 will freeze and will not enter the longitudinal groove 11, which will not provide the engagement of the movable axis 3 with the sleeve 25 locking device drive. With the correct code, by turning the knob 5 clockwise, the movable axis 3 through the key 27 rotates the sleeve 25 with the stop 26 of the drive of the locking device to the stop 46 and sets the locking device (not shown) in the open position. Together with the rotary sleeve 25, the pusher 30 and the key 27 rotate, and the code disks 13 remain locked by the dog 36, while the protrusion 44 of the dog 41 enters the groove 28 of the key 27. The current code is changed with the lock open. To do this, handle 5 moves the movable axis 3 in the axial direction to the first level, while the pusher 30 leaves the annular groove 12 of the rotary axis 3, interacting with the protrusion 43 of the dog 41, raises it, which in turn protrudes the tongue 27 with the protrusion 44, thereby disconnecting the most movable axis 3 with the sleeve 25 of the drive locking device. Next, by turning the knob 5, first, clockwise turn the inner ring 15 of the first code disk 13 and set on scale 4 the first number of the new code. Then, by turning the knob 5 counterclockwise, the inner ring 15 of the fourth code disk 13 is rotated and the second number of the new code is set on scale 4. Further, moving the movable axis 3 sequentially to the second and third levels, the remaining numbers of the new code are dialed in the same way.

To lock the lock, use the handle 5 to move the movable axis 3 along the axis in the opposite direction to the stop. In this position, under the action of the spring 29, the pusher 30 will enter the annular groove 12, and the key 27 will enter the longitudinal groove 11 and connect the drive of the locking device to the movable axis 3. By turning the handle 5 counterclockwise, the movable axis 3 through the key 27 rotates the drive sleeve of the locking device 25, which sets the locking device in the closed position. Then, with the handle 5, the movable axis 3 is moved in the axial direction sequentially to each level, and by turning the handle clockwise and counterclockwise, the dialed code is knocked down by turning the code disks at an arbitrary angle.

Claims (4)

1. The code mechanism of the lock, comprising a housing with a central hole, a movable axis with a calibrated scale, equipped with spring-loaded fingers and a latch installed in the central hole of the housing, a set of code disks mounted on a movable axis, a locking device drive equipped with a spring key and a pusher, installed on the rotary axis, dogs mounted pivotally on the housing and brake plates, characterized in that the lock code mechanism is equipped with a set of code disks mounted on a movable -th axis with the possibility of rotational movement, separated between each other by brake plates and spring-loaded in the axial direction, fixed on the housing against rotation, and each code disk is made integral, consisting of outer and inner rings, interconnected with the possibility of stepless rotation of the rings relative to each other and equipped an asymmetric code groove made on the landing hole and a locking groove made on the outer forming surface of the code disk, with half to Odov disks installed with a rotation of asymmetric code grooves around a vertical axis at an angle of 180 °. 2. The code mechanism according to claim 1, characterized in that the movable axis has two degrees of mobility and is equipped with spring-loaded fingers with teeth made on the protruding end of the fingers mounted with a rotation of the teeth relative to each other around the vertical axis at an angle of 180 ° with the possibility of teeth interaction with asymmetric code grooves of the code disks, and on the cylindrical surface of the movable axis, a longitudinal groove and an annular prismatic groove are made for interaction with the drive of the locking device. 3. The code mechanism according to claim 1, characterized in that the locking device drive is mounted on the movable axis with the possibility of limited rotation and is equipped with a spring-loaded key and pusher mounted in radial grooves on the front end of the rotary sleeve of the locking device drive, with the possibility of interaction with the longitudinal a groove and an annular prismatic groove of the movable axis, and at the front end of the rotary sleeve there is an annular groove intersecting with the radial grooves for placement in it ups made on dogs. 4. The code mechanism according to claim 1, characterized in that the dogs are pivotally mounted on the housing and provided with two protrusions interacting with a spring key and a pusher drive of the locking device, and one dog is additionally equipped with a locking shelf interacting with the locking grooves of the code disks.

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