RU96158U1 - CYLINDER LOCK - Google Patents

Abstract

 1. A cylinder lock in which there is at least one pair of movable spring-loaded pin elements, one of which is external and the other internal and located inside the external pin element, characterized in that one of the pair of pin elements (10, 11) has a figured shape (16) and can deviate from the axis of symmetry of another pin element from a pair of movable pin elements (10, 11). ! 2. A cylinder lock according to claim 1, characterized in that the figured shape (16) has the upper part of the internal pin element (11) adjacent to the edge of the channel (3) in the core (100), inside which there are gripping elements (5 and 6 ), and a guide region (18) is provided at the bottom of the inner pin member (11) to guide the inner pin member (11) inside the outer pin member (10). ! 3. A cylinder lock according to claim 1, characterized in that the external pin element (10) is made in a figured shape (16). ! 4. A cylinder lock according to claims 1 and 2 or 1 and 3, characterized in that the curved shape (16) has the form of an annular V-shaped groove.

Description

Technical area

This technical solution relates to a cylinder lock in which there is at least one pair of movable pin elements, which consists of an external spring-loaded pin element and an internal spring-loaded pin element sliding inside it.

The current state of this technical field

A large number of types of locks are known, including cylinder locks, in which a pair of pin elements are used; one of which is inserted into the other. For example, the following design is well known: in the external pin element there is a hole inside which the internal spring-loaded pin element can slide (patents: US 4,142,389, publ. 06.03.1979; US 3,494,158, publ. 10.02.1970; EP 0396492, publ. 07.11. 1990; EP 0238442, publ. 23.09.87; EP 0297929, publ. 04.01.89). A drawback of such pin locks, including cylinder locks, is that the internal pin element can slide in the external pin element even when trying to break the cylinder lock with a master key. If you move the pin elements to a position in which their ends are flush (flush) with the surface separating the core (cylinder) and the lock case, and then slightly rotate the core, then the edge of the channel in which the stopper pins are located is flush with the inner end pin element. In this position, you can move the inner pin member further, rotate the core and open the lock.

The basis of the technical solution

The purpose of this technical solution is to make it difficult for attackers to non-destructively break into existing cylinder locks. This technical solution is intended for cylinder locks in which there is at least one pair of movable spring-loaded pin elements, one of which is external and the other internal and located inside the external pin element. The basis of this technical solution is the fact that one of the movable pin elements of such a pair has a mushroom shape and can tilt at an angle relative to the axis of symmetry of the other movable pin element.

From the point of view of resistance to non-destructive breaking, such a mushroom shape should have an internal pin element, which with its upper end (“mushroom” head) can enter the channel in which the core pins are located. The lower part of the inner pin element serves to guide its movement inside the external pin element.

If you want to simplify the design without compromising safety, it is advisable to give the mushroom shape to the external pin element.

The mushroom shape of the pin element is the best option, although the shape of the element may be different.

Figures

This technical solution is illustrated using the drawings. Figure 1 shows the initial position of a pair of movable pin elements. A section of a cylinder lock is shown in a plane perpendicular to the axis of the castle. Figure 2 also shows a section of a cylinder lock, but the movable pin elements are shown in the position when a break-in attempt is made. In figures 3, 4 and 5, pairs of movable pins are shown in more detail.

Utility Model Description

As shown in figures 1 and 2, the cylinder lock consists of a housing 1 and a rotating core (cylinder) 100, in which there is a hole 2 for the key. Channel 3 in the core 100 goes into the well 2. In this channel there is a pair of coaxially mounted gripping pins 4 and 5 with conical upper ends 6 and 7 extending into the well 2. In the initial, i.e. closed position of the cylinder lock, shown in FIG. 1 , the lower ends 8 and 9 of these pins are in contact with one of a pair of movable pin elements 10 and 11, which slide in the channel 12, made in the housing 1 of the cylinder lock. A pair of movable pin elements 10 and 11 consists of an external pin element 10 guided by a return spring 13 into the channel 3, and an internal pin element 11, which can not only move inside the external pin 10 and along the axis of symmetry 0, but also deviate from this axis. The inner pin element 11 is supported by a spring 14 located between the lower end of this element and the bottom of the external pin element 10. In this embodiment, as shown in FIGS. 1 and 3, the internal pin element 11. is not cylindrical, but has a figured V-shaped profile 16 under top end 15. Ideally, the inner pin member 11 has a mushroom-shaped V-shape. The other end of the pin member has a protrusion 17 on which the spring 14 is worn. The protruding rim 18 of the inner pin member 11 guides this member inside the outer pin member 10, the inner member being inclined relative to the axis.

Figure 4 shows a variant in which the inclinations of the inner pin member 11 with the end face in the form of a mushroom head are simplified 16. In this embodiment, the spring 14 is worn on the middle part 19 of the inner pin member 11 and is located between the outer pin member 10 and the inner pin member 11. At the end of the portion 19 of the inner pin 11, there is a guide region 18 and an additional guide region 20. The channel 21 in the outer pin member 10 is shaped to correspond to the inner pin member 11.

The mushroom-shaped V-shape 16 need not have an internal pin member 11. FIG. 5 shows an annular wedge-shaped V-shaped groove 16 on the external pin 10. There is sufficient clearance in the channel of the lock case in which the external pin element 10 moves. the pin member could tilt.

When you try to break the lock, that is, when you try to open the lock without a genuine key, the core (cylinder) 100 rotates, as shown in figure 2. When the core 100 is rotated, the cap 16, in this case on the internal pin member 11, abuts against the edge of the channel 3 in the core, in which the capturing pins 5 and 6 move, so further rotation of the core 100 is not possible, and the cylinder lock remains closed.

Application area

This technical solution is mainly applicable to mechanical protection systems for automobiles.

Claims (4)

1. A cylinder lock in which there is at least one pair of movable spring-loaded pin elements, one of which is external and the other internal and located inside the external pin element, characterized in that one of the pair of pin elements (10, 11) has a figured shape (16) and can deviate from the axis of symmetry of another pin element from a pair of movable pin elements (10, 11). 2. A cylinder lock according to claim 1, characterized in that the figured shape (16) has the upper part of the internal pin element (11) adjacent to the edge of the channel (3) in the core (100), inside which there are gripping elements (5 and 6 ), and a guide region (18) is provided at the bottom of the inner pin member (11) to guide the inner pin member (11) inside the outer pin member (10). 3. A cylinder lock according to claim 1, characterized in that the external pin element (10) is made in a figured shape (16). 4. A cylinder lock according to claims 1 and 2 or 1 and 3, characterized in that the curved shape (16) has the form of an annular V-shaped groove.