RU222391U1 - KEY - Google Patents

Abstract

The utility model relates to the design of a key designed to open door locks, anti-theft devices and other locked objects. The key consists of a head 1 and a working part made in the form of a cylindrical longitudinal rod 2 with a code thread, formed to interact with the code pins located in the rotor 3 of the lock. The cutting is formed by at least one row of code recesses 4, the geometric axes 5 of which intersect with the geometric axis 6 of the longitudinal rod 2. The longitudinal rod 2 is equipped with guide ribs 7 located on opposite sides. Between the code cutting and the head 1 of the key, a socket 10 is formed in the longitudinal rod 2 to interact with the locking element located in the lock rotor 3. The cross-sectional area of the longitudinal rod 2 in plane 15 passing through the geometric axis 13 of the socket and perpendicular to the geometric axis 6 of the longitudinal rod 2 is less than the cross-sectional area of the longitudinal rod 2 in any plane 16 passing through the geometric axis 5 of any code notch 4. 6 h. P. f-ly, 7 ill.

Description

The utility model relates to the design of a key designed to open door locks, anti-theft devices and other locked objects.

The key is known, described in the patent of the Russian Federation No. 68001 (published 16.108.2008) for an industrial design.

The key consists of a head and a working part. The key head is made flat in the shape of an oval with a wide side and a narrow side. The wide side of the head is connected to the working part of the key, and an oval hole is made near the narrow side. The working part of the key is made in the form of a cylindrical longitudinal rod with a code thread at the free end. The code groove on the cylindrical rod is formed by six rows of code radial non-through grooves, the axes of which intersect with the axis of the longitudinal rod. The cylindrical rod is equipped along its entire length in the diametrical plane with rectangular guide ribs, which form protrusions at the head.

From Japanese application No. 2002-213120 (published July 31, 2002) for the invention, a rod key consisting of a head and a working part is known.

The working part of the key is made in the form of a cylindrical longitudinal rod with a code cut. The code groove on the cylindrical rod is formed by six rows of coded radial non-through grooves, the geometric axes of which intersect with the geometric axis of the longitudinal rod. The code notches on the cylindrical rod interact with code pins located in the lock rotor, which are acted upon by spring-loaded balance pins installed in the lock stator. The cylindrical rod is equipped along its entire length, except for the end conical part, with rectangular guide ribs located in the diametrical plane, which form wider protrusions-stops at the head.

The technical problem of the considered solution is the insufficient resistance of the lock corresponding to the described key to hacking by means of a roll - a reinforced part used instead of a key for criminal destruction of the lock's security mechanism (in the formulation of the interstate standard GOST 5089-2011) when the lock rotor is turned with the destruction of the balance and combination pins.

This technical problem is solved by the design of a key consisting of a head and a working part, made in the form of a cylindrical longitudinal rod with a code cut, formed to interact with code pins located in the lock rotor and formed by at least one row of code recesses, the geometric axes of which intersect with the geometric one the axis of a longitudinal rod equipped with guide ribs located on opposite sides, while between the code thread and the key head a socket is formed in the longitudinal rod to interact with a locking element located in the lock rotor, and the cross-sectional area of the longitudinal rod is in a plane passing through the geometric axis of the socket and perpendicular geometric axis of the longitudinal rod, less than the cross-sectional area of the longitudinal rod in any plane passing through the geometric axis of any code notch.

The socket is preferably made with an internal conical surface merging into a smaller base of a cone formed in the longitudinal rod.

As a rule, the longitudinal rod contains more than one socket, the geometric axes of each of which are perpendicular to the geometric axis of the longitudinal rod. In this case, a pair of sockets are made symmetrically relative to the geometric axis of the longitudinal rod on which they are located.

The geometric axis of the socket is predominantly perpendicular to the longitudinal plane of symmetry of the guide ribs located on the longitudinal rod.

The guide ribs can be made rectangular and formed along the entire length of the longitudinal rod, except for the end conical part, with the formation of wider protrusions-stops at the key head.

Code recesses are made, as a rule, radial and not through.

The technical result of the utility model is the creation of a key with means for deliberately weakening the profile of its rod with code cutting, made to interact with elements that strengthen the resistance to rotation of the lock rotor in its stator.

The claimed technical solution of the key is presented in the following figures.

In fig. 1 shows the key in axonometry.

In fig. 2 shows the key, side view.

In fig. Figure 3 shows the key, front view.

In fig. Figure 4 shows a cross section of the key shaft along the socket axis.

In fig. Figure 5 shows a cross section of the key shaft along the axis of the code notch.

In fig. Figure 6 shows a lock with an inserted key, equipped with sockets that interact with the locking elements.

In fig. 7 shows a lock with an inserted unlocking product simulating a key shaft, without sockets for interaction with the locking elements.

The key consists of head 1 and a working part. The working part of the key is made in the form of a cylindrical longitudinal rod 2 with a code cut, formed to interact with the code pins located in the rotor 3 of the lock, as shown, for example, in Japanese application No. 2002-213120 (published on July 31, 2002) for the invention (page 6, fig. 1, fig. 2). The cutting is formed by at least one row of code grooves 4, usually radial non-through, the geometric axes 5 of which intersect with the geometric axis 6 of the longitudinal rod 2. The code groove on the cylindrical rod 2 is formed preferably by six rows of code radial blind grooves 4, made symmetrically with respect to the geometric axis 6 of the longitudinal rod, 2 on which they are located. The longitudinal rod 2 is equipped with guide ribs 7 located on opposite sides, usually rectangular, formed along the entire length of the longitudinal rod 2, except for the end conical part 8, which form wider protrusions-stops 9 at the head 1.

Between the code cutting and the head 1 of the key, a socket 10 is formed in the longitudinal rod 2 to interact with the locking element located in the rotor 3 of the lock. The socket 10 is made, as a rule, with an internal conical surface 11, which passes into a smaller base 12 of a cone formed in the longitudinal rod 2. The geometric axis 13 of the socket 10 is preferably perpendicular to the longitudinal plane 14 of symmetry of the rectangular guide ribs 7 located on the longitudinal rod 2. Sectional area longitudinal rod 2 in plane 15 passing through the geometric axis 13 of socket 10 and perpendicular to the geometric axis 6 of the longitudinal rod 2 is less than the cross-sectional area of the longitudinal rod 2 in any plane 16 passing through the geometric axis 5 of any code notch 4.

So, for example, the cross-sectional area of the longitudinal rod of a key is rounded equal to 15 mm ² in the case of a rod diameter of 4 mm, the width of each guide rib is 1.8 mm and the total width of the rod and guide ribs is 5.3 mm.

The cross-sectional area of the longitudinal rod and the ribs of the key along a plane passing through the geometric axis of the socket and perpendicular to the geometric axis of the longitudinal rod (Fig. 4) with the specified dimensions of the rod and guide ribs is equal to rounded 8.5 mm ² .

The cross-sectional area of the longitudinal rod and key ribs along a plane passing through the geometric axis of the code recess and perpendicular to the geometric axis of the longitudinal rod of the sockets (Fig. 5) with the indicated dimensions of the rod and guide ribs is equal to rounded 10.4 mm ² .

Thus, by weakening the profile of the longitudinal rod 2 with code cutting, means are formed for interacting with the elements to strengthen the resistance to rotation of the lock rotor 3 in its stator 17.

In the longitudinal rod 2 of the key, there is preferably more than one socket 10, for example, two sockets 10, the geometric axes 13 of each of which are perpendicular to the geometric axis 6 of the longitudinal rod 2. In this case, a pair of sockets 10 are made symmetrically relative to the geometric axis 6 of the longitudinal rod 2, on which they located.

It is also possible to make one or two nests 10 in rectangular guide ribs 7.

The key interacts with a cylinder lock (Fig. 6) containing a stator 17, a rotor 3 rotating in the stator 17 under the action of the key, and a rotor locking device 3 containing locking pins and code pins (not shown) installed, respectively, in the radial channels stator 17 and rotor 3. The rotor locking device 3 contains additional means of increasing resistance to rotation of the lock rotor 3 in its stator 17, including at least one through channel 18 in the rotor 3 with exits to the internal recess 19 of the stator 17 and the key slot 20, as well as a blocking element installed in the through channel 18 with the possibility of partial exit into the key slot 20 for interaction with the socket 10 on the longitudinal rod 2 of the key and partial exit into the internal recess 19 of the stator 17. The blocking element is formed, as a rule, by a ball 21 installed in through channel 18 in rotor 3 with the possibility of free movement.

An additional channel 22 can be formed in the rotor 3 with a blocking element in the form of an additional ball 23, with exits to an additional internal recess 24 of the stator 17 and a key slot 20.

Socket 10 in the longitudinal rod 2 of the original key, designed to unlock this cylinder lock, coincides when the key is fully inserted into the key slot 20 in the rotor 3 with a through channel 18 in the rotor 3 under the ball 21. When the longitudinal rod 2 of the original key with socket 10 is inserted key slot 20 in rotor 3, ball 21 fits into slot 10 without protruding beyond the inner diameter of stator 17, and, if the code cutting on the key and the code of the lock's security mechanism match, it allows you to freely open the security mechanism, that is, rotate rotor 3 in stator 17.

In the case of inserting a key core with a ball socket, but if the code cut on the key and the lock security mechanism code do not match, as well as other unlocking products with a ball socket that imitate the key core (master key, roll, etc.), two sockets 10 under the ball 21 and the ball 23 reduce the cross-sectional area of the longitudinal rod 2 and prevent the application of sufficient torque to forcefully rotate the rotor 3 in the stator 17.

When inserting a key shaft without a socket under the ball, as well as other unlocking products 25 that imitate the key shaft (master key, roll, etc.), ball 21 (and ball 23) protrudes from the rotor 3, falls into recess 19 (respectively, into recess 24) of the stator 17 and prevent rotation of the rotor 3 in the stator 17 of the cylinder lock (Fig. 7).

It should be noted that the above embodiments are illustrative and not limiting of the utility model, and that those skilled in the art will be able to develop many alternative embodiments without departing from the scope of the appended claims. The mere fact that certain criteria are listed in mutually different dependent claims of a utility model does not indicate that a combination of these criteria cannot be used to obtain a positive effect.

Claims (7)

1. A key consisting of a head and a working part made in the form of a cylindrical longitudinal rod with a code cut, formed to interact with code pins located in the lock rotor and formed by at least one row of code recesses, the geometric axes of which intersect with the geometric axis of the longitudinal rod , equipped with guide ribs located on opposite sides, characterized in that between the code cutting and the head of the key, a socket is formed in the longitudinal rod for interaction with a locking element located in the lock rotor, and the cross-sectional area of the longitudinal rod in a plane passing through the geometric axis of the socket and perpendicular to the geometric axis of the longitudinal rod, less than the cross-sectional area of the longitudinal rod in any plane passing through the geometric axis of any code notch. 2. The key according to claim 1, characterized in that the socket is made with an internal conical surface that turns into a smaller base of a cone formed in the longitudinal rod. 3. The key according to claim 1, characterized in that more than one socket is made in the longitudinal rod, the geometric axes of each of which are perpendicular to the geometric axis of the longitudinal rod. 4. The key according to claim 3, characterized in that the pair of sockets are made symmetrically relative to the geometric axis of the longitudinal rod on which they are located. 5. The key according to claim 1, characterized in that the geometric axis of the socket is perpendicular to the longitudinal plane of symmetry of the guide ribs located on the longitudinal rod. 6. The key according to claim 1, characterized in that the guide ribs are made rectangular and formed along the entire length of the longitudinal rod, except for the end conical part, with the formation of wider protrusions-stops at the head of the key. 7. The key according to claim 1, characterized in that the code recesses are made radial and not through.