RU52059U1 - LOCKING MECHANISM OF CYLINDER LOCK - Google Patents

Abstract

The locking mechanism of a cylinder lock refers to locks with special keys, namely, push-buttons, and can be used both in mechanical locks and in special-purpose combination electromechanical locks, which exclude unauthorized access to electronic circuits of devices and special-purpose systems. The locking mechanism of the lock comprises a housing, a rotary axis with pressure pins located on its surface, the ends of which are inserted into the grooves of the pressure key, a flange with spring-loaded locking pins located in its holes, the ends of which are inserted into the holes of the rotary axis and rest on the ends of the pressure pins. The locking pins are spring-loaded with a leaf spring with the number of petals equal to the number of pins. The pressure wrench is made in the form of a thin-walled sleeve with blind longitudinal end grooves interacting with the corresponding support areas of the pressure pins. The central hole of the sleeve of the pressure wrench is designed for concentric alignment with the rotary axis. The pressure wrench is provided with a plate that has a leash protruding beyond the external and internal diameters of the key sleeve. The sum of the lengths of the end groove of the sleeve of the key and the lengths of the corresponding pressure pin are the same for each pair of "groove - pressure pin".

Description

The alleged invention relates to locks with special keys, namely, with push keys and can be used in various designs of locks:

- in code electromechanical locks, which exclude unauthorized access to electronic circuits of devices and systems (complexes) for special purposes, converting the rotational movement of the rotary axis into a code electric signal, depending on the angle of rotation;

- in locking locks that convert the rotational movement of the rotary axis into the linear movement of the bolt (rod).

Various locking mechanisms with push wrenches are known (see, for example, RF patents No. 2061820, MKI E 05 B 35/04, No. 2105120 MKI E 05 B 35/04) comprising a housing, a rotary drum, spring-loaded locking pins and a pressure key.

In the locking mechanism of the patent No. 2061820, the pressure wrench is made in the form of a rod with longitudinal recesses interacting with the corresponding supporting platforms of the locking pins. The mechanism is equipped with a cover mounted from the rear end of the rotary drum. Grooves are made in the lid opposite the locking pins. The sum of the lengths of the recesses of each locking pin and the lengths of the corresponding recesses of the pressure key are equal to each other.

The specified locking mechanism is structurally complex and unprotected from penetration of moisture and dust through its moving parts. The absence of guide parts makes it difficult to align the key grooves with

corresponding spring pins. The key is not fixed in the lock and is pushed out by a spring when releasing the pressure in any working position. The use of cylindrical compression springs increases the depth of the lock. The torque to the rotary drum is transmitted through the locking pins, which reduces the reliability of the lock.

The locking mechanism according to the patent of the Russian Federation No. 2105120 is also not reliable enough and has significant dimensions, because the design contains a large number of different springs (brake springs, main spring, locking pin springs).

The closest in technical essence and adopted for the prototype is a cylinder lock with a key according to the patent of the Russian Federation No. 2068927 MKI E 05 B 35/04, comprising a housing, a rotary step axis, spring-loaded locking pins, push pins located in the through holes of the rotary axis, and a key.

In the known device, the locking pins are spring-loaded with coil springs and are located in the blind holes of the housing, and the key has a head with different sized end pins for interacting with the pressure pins.

The specified mechanism has the same disadvantages as the locks according to the patents of the Russian Federation No. 2061820 and No. 2105120. In addition, the locking mechanism is located outside the locked product and cannot be used in combination electromechanical locks.

The technical problem solved in the claimed device is to increase reliability, reduce the size and expand the scope.

This problem is solved due to the fact that in the locking mechanism of the cylinder lock containing the housing, the rotary step axis, the spring-loaded locking pins, the pressure pins placed in the through holes of the rotary axis, and the key, the locking pins are located in the through holes of the flange rigidly connected to the housing ,

and spring-loaded with a leaf spring pressed against the flange by means of a washer mounted on the shank of the rotary axis, the housing is provided with a shoulder with a groove, a half-segment groove is made in the rotary axis, and the key is made in the form of a sleeve with end grooves on its outer surface and is equipped with a handle in the form of a plate with the lead, while the end grooves of the sleeve are concentric with the pressure pins, and the lead is made with the possibility of interaction with the groove of the flange of the housing and the half-segment groove of the rotary axis. In this case, the leaf spring is made of sheet material with the number of petals equal to the number of locking pins, and an o-ring is placed in the end groove of the housing washer.

This design has a minimum size in depth, because does not contain coil springs. Torque is transmitted to the rotary axis from the key and does not load the locking pins. The locking device is located behind the panel of the locked product and can be used both for mechanical locks and for electromechanical combination locks, which provide the ability to insert and remove the key only in one neutral inoperative position, and also when turning it 360 ° × n. In addition, the design allows the use of a sealing ring for the shank of the rotary axis, which does not limit the possibility of its rotation, which ensures the protection of devices and locks from dust and moisture both inoperative and in working condition.

Fig. 1 shows a sectional locking mechanism of a cylinder lock, Fig. 2 shows a cylinder locking mechanism with a key at the time of unlocking in a section, Fig. 3 shows a section A-A with variants of uniform and uneven arrangement of pressure pins, Fig. 2. 5 is an example of a petal spring.

The locking mechanism of the lock comprises a housing 1 made in the form of a multi-stage cylindrical sleeve with a shoulder 2 on the inner annular groove 3. The housing 1 is fixed on the inside of the panel 4 by screws 5. An axis 6 of a step shape is rotatably mounted inside the housing. Through holes on the cylindrical protrusion of the rotary axis 6 are eccentrically arranged uniformly or unevenly around the circumference of the pins 7. The flange 8 is located behind the cylindrical protrusion of the rotary axis 6 and the locking pins are located in the eccentric through holes of the diameters 9. Diameters and arrangement of holes in the flange 8 completely coincide with the diameters and location of the holes in the cylindrical protrusion of the rotary axis 6. The flange 8 is screwed to the housing 1, fixing the rotation from axial movement the axis 6. The flap spring 10 is located behind the flange 8. The number and placement of the spring blades of the spring 10 corresponds to the number and location of the locking pins 9. The petals of the spring 10 press the locking pins 9 so that they enter the holes of the cylindrical protrusion of the rotary axis 6 and lock it . The spring 10 is pressed against the flange 8 by the washer 11 and fixed by a pin 12. The washer 11 has a central hole with an end groove of a conical shape through which the shank of the rotary axis 6 passes. A sealing ring 13 of a toroidal shape is placed in the end groove. The washer 11 and the o-ring 13 are fixed by a cover 14, which is fastened with screws 15 to the housing 1, while an additional sealing ring gasket 16 can be placed between the housing 1 and the cover 14. Various locking parts and devices can be attached to the shank of the rotary axis 6, as well as simple electromechanical (microswitches, wired switches) or more complex optoelectronic code devices. The housing 1 has a groove 17, and the rotary axis 6 is semi-segmented

groove 18. The pressure wrench 19 (FIGS. 2, 4) is made in the form of a thin-walled sleeve 20 on which the plate 21 is fixed. The plate 21 serves as a handle for conveniently turning the key at a given angle and for determining the working position of the rotary axis 6 and the code device, which can be mounted on the shank of the rotary axis 6. The plate 21 has a leash 22, for example, L-shaped, protruding beyond the outer and inner diameters of the sleeve 20. The protrusion 23 (shelf L-shaped leash), located outside the outer diameter of the sleeve 20, has a width equal to the width of the groove 17 on the shoulder 2 of the case 1, and the protrusion depth is equal to the width of the annular groove 3. The part of the leash 22, protruding beyond the inner diameter of the sleeve 20, has a width equal to the width of the half-segment groove 18 of the rotary axis 6. On the outer surface of the sleeve 20, blind end grooves 24 are made along its circumference, location which corresponds to the location of the pressure pins 7. The total length of the groove 24 and the corresponding pressure pin 7 is constant for all pairs of "groove - pressure pin".

The locking mechanism operates as follows. The key 19 is inserted into the Central hole of the housing 1 (see figure 2), while the leash 22 enters the groove 18 on the rotary axis 6, and the protrusion 23 of the leash 22 coincides with the groove 17 on the housing 1 (grooves 17 and 18 are located in the same plane ) The key 19 is fed all the way forward, and while the axial movement of the key, the supporting end platforms of the grooves 24 of the key 19, interacting with the corresponding supporting platforms of the pressure pins 7, move them to different distances depending on the length of the end grooves 24. The pressure pins 7, in turn, move the locking pins 9, which exit from the holes of the cylindrical protrusion of the rotary axis 6, releasing it. When turning the key 19, the protrusion 22, which has entered the half-segment groove 18 of the rotary axis 6, rotates the axis 6 with the part or device fixed to its shank by the required angle.

When a foreign key is inserted into the locking mechanism, several locking pins 9 do not completely exit the holes of the cylindrical protrusion of the rotary axis 6, and some pressure pins 7 enter the holes of the flange 8, further blocking the rotary axis 6.

Compared to the prototype, the proposed locking mechanisms are more difficult to pick up a key, because the use of a large number of locking pins along with a wide variety of lengths of the end grooves 24 on the sleeve 20 of the key 19 significantly increases the number of different non-repeating key-lock combinations, increasing the security of the lock. At the same time, the depth of the lock remains constant, independent of the number of locking pins.

In the inventive mechanism, the key is inserted and removed in only one position. The torque is transmitted from the key to the rotary axis 6 due to the shape of the lead 22, which is included in the half-segment groove 18, protruding beyond the inner diameter of the sleeve 20 and does not load the locking pins when turning. When turning the key, not a multiple of 360 °, the key remains in the lock in the desired position, which is especially important for combination electromechanical locks, and is fixed in it, because the spring 10 through the locking pins 9 and pressure pins 7 presses the protrusion 23 of the key 19 to the shoulder 2 of the housing 1, and does not push it, as in the prototype device.

In any operating position of the key located in the lock, moisture and dust do not enter the device and the lock through the locking mechanism, as the sealing ring 13, through which the axis 6 shank passes, does not pass moisture and dust and at the same time does not limit the possibility of its rotation. The use of the leaf spring 16 reduces the depth of the lock and increases the reliability. In order to eliminate corrosion, all parts of the lock are made of anti-corrosion materials. The key for the lock is easy and convenient to use.

Claims (3)

1. The locking mechanism of the cylinder lock, comprising a housing, a rotary step axis, spring-loaded locking pins, pressure pins located in the through holes of the rotary axis and a key, characterized in that the locking pins are located in the through holes of a flange rigidly connected to the housing and spring-loaded a spring pressed to the flange by means of a washer mounted on the shank of the rotary axis, the housing is provided with a shoulder with a groove, a half-segment groove is made in the rotary axis, and the key is made in the form of a sleeve with a torus evymi grooves on its outer surface and is provided with a handle in the form of a plate with a lead, the sleeve end grooves concentric pressure pin, and the lead is adapted to cooperate with the groove and the bead housing groove polusegmentnym pivot axis. 2. The locking mechanism according to claim 1, characterized in that the leaf spring is made of sheet material with the number of petals equal to the number of locking pins. 3. The locking mechanism according to claim 1, characterized in that it is equipped with a sealing ring located in the end groove of the washer through which the shank of the rotary axis passes.