RU2049894C1 - Lock cylinder mechanism - Google Patents

Abstract

FIELD: locks. SUBSTANCE: lock cylinder mechanism has body with axial channel accommodating core with system of pins with mechanical code members and system of pins with magnetic code members. Made in body channel is longitudinal trapezoidal recess. EFFECT: higher efficiency. 4 cl, 11 dwg

Description

 The invention relates to locking devices, namely to cylinder mechanisms of door locks, unlocked on both sides of the door.

 A cylinder mechanism is known, comprising a housing with spring-loaded pushers radially mounted in it, a rotary core of the external part of the mechanism located in the housing with pins installed therein, in contact with the pushers and a keyway, a locking unit of the internal part of the mechanism connected to the core by means of spring-loaded elements, the mechanism is equipped with at least one additional key and one interchangeable washer for switching to an interchangeable key (ed. certificate of the USSR N 1059108, class E 05 B 13/00, 1982).

 However, the known castle has a complex structure that complicates its manufacture and operation.

 Closest to the proposed one is a cylinder lock mechanism comprising a housing with an axial channel, spring-loaded pushers radially mounted in the housing, rotary cores located in the housing channel of the outer and inner parts of the mechanism, each of which is provided with pins radially mounted therein in contact with the pushers and a groove under a key, a leash located between the cores and rigidly connected with them, as well as an additional key to lock the lock (ed. certificate of the USSR N 1209811, class E 05 B 27/02, 1986).

 The disadvantage of this lock is its low secrecy and low reliability against tampering with a master key or other key due to the limited number of pins and direct access to them from the side of the key channel.

 The aim of the invention is to create a lock design that combines reliable protection against tampering with a master key or other key with its small dimensions.

 In FIG. 1 shows a cylinder mechanism, a General view with a longitudinal section; figure 2 section aa; figure 3 cylinder mechanism with a longitudinal section with a key General view; figure 4 cylinder mechanism in the open state; in FIG. 5,6,7 schemes of blocking the lock mechanism during forced opening; on Fig cylinder mechanism in the closed state; Fig.9 is the same in the open state (key inserted); figure 10 key for the magnetic mechanism; figure 11 protection circuit of the lock from forced opening.

 The cylinder lock mechanism comprises a housing 1 with an axial channel 2, pushers 5 radially located in the channels 3 of the housing 1, pushers 5, rotary cores 6 of the outer and inner parts of the mechanism located in the axial channel 2 of the housing 1, each of which is equipped with pins 7 radially mounted in it in contact with the pushers 5, and the turnkey channel 8, the barbs of which have a secret part. On the pusher 5 and the pin 7, annular grooves 10 and 11 are made. The channel 8 has a circular shape and two longitudinal grooves 12 and 13. Under the grooves 12 and 13 on the key 9, two protrusions 14 and 15 are made. On the protrusion 14 there is a mechanical thread 16 for the pins 7. In the housing 1, a trapezoidal groove 17 is made, and in the core 6 are the channels 18. The diameter of the channels 18 is equal to the diameter of the channels 3. In the channels 18 there are pins of two sizes: a long length 19 and a shorter length 20. On the protrusion 15 of the key, they are mechanically cut 21. Channel 18 is located in the same plane with channels 3, i.e. coaxially.

According to one embodiment of the mechanism, two trapezoidal slots 22 are additionally made in the housing. Opposite them, channels 23 are made in the core 6 at an angle to the channels 3. They are equipped with mechanical locking pins of two sizes: a long length 24 and a shorter length 25. On the surface of the key 9 mechanical cutting 26 was performed under them. Channels 23 can be made both at right angles to channels 3, and at other angles, for example 45 ^about . In the same plane with the channels 23 in the housing 1, channels 27 are made in which spring-loaded pins 28 are installed, the lower face of which is beveled. From the rotation in the channel 23, a recess 29 is made on the pin 28, into which the fixed pin 30 enters, placed in the housing 1.

 According to another embodiment of the mechanism with magnetic code elements, two rectangular grooves 31 are made in the housing 1. Opposite them, in the core 6, channels 32 are separated in the core 6 from channels 3, separated from the key channel 8 by a thin partition 33. Pins 34 of non-magnetic material having inserts 35 of a permanent magnet and spring-loaded with springs 36, as well as pins 37 of steel with high magnetic permeability. On the key 9 under the pins 34 there is an insert 38 of a permanent magnet and an insert 39 of steel with high magnetic permeability. The pins 34 and 37 can be made in other versions: 1) the pins 34 and 37 are made of non-magnetic material with inserts from a permanent magnet, and on the key under them are made of inserts from a permanent magnet of different polarity and steel; 2) the pins 34 and 37 are made of steel with high magnetic permeability, and on the key under them are inserts of a permanent magnet.

 The cylinder mechanism operates as follows.

 In the closed state, the core 6 is blocked from turning by the pins 7. In the mechanism with magnetic code elements, additional locking is provided by spring-loaded pins 34 and 37.

 The mechanical pins 19 and 20, 24 and 25 are free and do not block the core 6 from turning. After entering the key 9 into the channel 8, the mechanical cutting 16 of the protrusion 14 exposes the coding pins 7 on the separation line of the core 6 and the housing 1.

 In the mechanism with mechanical code elements, the locking pins 19, 20, 24 and 25, when turning the key 9, fall into the corresponding recesses of the mechanical threads 16 and 21 and do not interfere with the rotation of the core 6. If the corresponding recesses are not made on the key 9 for the pins of long lengths 19 and 24 , then when you try to rotate the key 9, the upper part of the pins 19 and 24 will abut against the wall of the corresponding groove 17 or 22 and the rotation of the core 6 will be blocked. If the key 9 for the pins of short lengths 20 and 25 will make recesses of a larger size, as under pins 19 and 24, then p When the core 6 is rotated, there is a dropping into the channels 19 and 23 corresponding to these pins. Pushers 5 and pins 29 will block further rotation of the core 6 and will not allow you to remove the key 9 from the key channel 8. The key 9 can only be removed after it is destroyed.

 In a mechanism with magnetic code elements, pins 19 and 24 function in the same way as in a mechanism with mechanical code elements. Magnetic code elements work as follows. After the key 9 is inserted into the channel 8, a magnetic interaction occurs between the inserts 38 of the permanent magnet and 39 of the steel of the key 9 and the corresponding spring-loaded pins 34 having the inserts 35 of the permanent magnet and the pins 37 of steel. The pins 34 and 37 move towards the key 9 and unlock the core 2.

 The mechanism is operable if the polarities of the magnetic inserts 38 of the key 9 and the inserts 35 of the pins 34 have opposite values or the inserts 39 made of steel of the key 9 interact with the magnetic inserts 35 of the pins 34 and, conversely, the steel pins 37 interact with the magnetic inserts 38 of the key 9. Otherwise spring pins 34 and 37 do not unlock core 2.

 When you try to open the cylinder mechanism using the master keys, the pushers 5 and pins 7 are jammed on the annular grooves 10 and 11 after applying an external moment to the core 6.

 Spring-loaded magnetic 34 and steel 37 pins provide protection of the cylinder mechanism from opening by means of a master key. After entering the key channel 8 of the magnetic or steel elements 40, providing movement of the pins 34 and 37, they overlap the area of the master key 41 moving the code pins 7 of the core.

 The key 9 of the cylinder mechanism with magnetic code elements is reliably protected from copying on a print on a plastic material. This is due to the fact that for its manufacture it is necessary to know not only the location, but also the polarity of the magnetic insert 38.

 In a cylinder mechanism with magnetic elements, as a rule, a combination of magnetic and steel elements of the core 6 and key 9 is used. This makes it possible to increase the reliability of the mechanism against tampering with master keys and polarity meters, force breaking and simplify the manufacturing technology of the mechanism and key. The magnetic element of the mechanism or key can be decoded using any magnetic induction meter having a sensor dimension sufficient to be placed inside the key channel 8. The steel element located behind the protective partition cannot be detected with any tool. At the same time, it can be easily circumvented, knowing its location by the exemplary mechanism, it is necessary to install a magnet of any polarity on the key. The steel pin 37 has a simpler manufacturing technology compared to brass 34 having a permanent magnet insert 35 fixed with glue.

The proposed cylinder mechanisms have the following advantages:
increased number of code combinations, in the case of mechanical code elements 2 ^K times, magnetic 2 ^M x 2 ^K times, where K is the number of blocking additional mechanical elements, M is the number of magnetic code elements;
increased reliability against tampering with master keys;
increased reliability against tampering using key selection;
protection against copying a key with magnetic elements on an impression on plasticine;
the possibility of creating locks on their base with a "general key" system, that is, when one key can open a series of locks with individual keys. This is achieved due to the increased number of code and blocking elements.

Claims (4)

 1. CYLINDER LOCK MECHANISM, comprising a housing with an axial channel, spring-loaded pushers radially mounted in the housing, rotatable cores of the external and internal parts of the mechanism located in the housing channel, each of which is provided with fonts radially mounted in it, in contact with the plungers and a turnkey channel having a secret part in the form of barbs, characterized in that a trapezoidal groove is made in the channel of the housing along the longitudinal axis, and the rotary core has additional pins located coaxially and having the same diameter as the latter, while the key has an additional thread for additional pins.  2. The mechanism according to claim 1, characterized in that two additional trapezoidal grooves are made in the housing channel, spring-loaded locking pins with beveled lower edges and fixed against rotation are installed in the housing, and the core has pins located at an angle to the pushers and in the same plane with spring-loaded locking pins for interaction with additional trapezoidal grooves, and the key has a thread for core pins located in the same plane with the locking pins.  3. The mechanism according to claim 2, characterized in that the core pins installed in the same plane with the locking pins are located at right angles to the pushers.  4. The mechanism according to claim 1, characterized in that two rectangular grooves are made in the channel of the housing, the core has pins for interacting with them made of at least partially magnetic material and separated by a partition from the channel under the key, and these pins are angled to the body pushers, and the key is made of an insert of magnetic material.

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