RU2575425C2 - Code conversed cylinder - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: code conversed cylinder (1) containing a stator (2), having in essence a cylindrical hole (3) for rotor (4). In the rotor (4) and the stator (2) the channels (5) are made for at least one appropriate pin, made with possibility of movement such, that it can slide in them against the appropriate elastic device. Simultaneously the pins partial location in the rotor (4) and partially in the stator (2) determines the rotor (4) locking, and levelling of the final edge of pins with border between the stator (2) and the rotor (4) achieved by means of insertion of the appropriate key (7) with complex profile in the hole (6) of the rotor (4), that looks towards the channels (5), determines the free rotation of the rotor (4) relatively to the stator (2). At least one of the pins is made by the pair of virtually complementary valves (9, 11), that are equipped along at least one appropriate common connecting surface, over at least one appropriate profile (10) of the first valve (9), and by at least one appropriate counter-profile (12) of the second valve (11). The first valve (9) can make translational movement relatively to the stator (2) and the rotor (4), and the second valve (11) can make translational movement and rotation, along set angular motion, relatively to the stator (2) and the rotor (4). The second valve (11) contains a support device for the special device (13) connected with it by means of the secondary channel (14) of the rotor (4), that looks on the support device.

EFFECT: improved design.

7 cl, 23 dwg

Description

Technical field

The present invention relates to a transcoded cylinder.

Prior art

As you know, the cylinder is the main active component of the lock. It is formed by a stator, which is made for one with a lock, inside which, optionally, the rotor can rotate. The rotor is provided with a hole for inserting an encoded key. Between the rotor and the stator, suitable pins of a given length are installed that are elastically held in the obstruction position between the rotor and the stator, a key combination of keys that ensures the alignment of the end edge of each pin with the interface between the stator and the rotor, followed by free rotation of the rotor relative to the stator.

The key combination of the key consists in providing it with a complex profile, which has such a sequence that, after the key is fully inserted into the hole of the corresponding rotor, the edge of each pin pressed by the corresponding section of the complex profile of the key against the elastic means is aligned with the interface between the rotor and the stator.

The main disadvantage of this type of cylinder is the need to completely replace the cylinder if the key is lost (or stolen, or copied). In fact, it is impossible to change the length of the pins in order to change the characteristics of a complex key profile suitable for opening a cylinder.

Therefore, it is necessary to replace the cylinder to prevent the attacker from gaining access to the area protected by the lock, which is controlled by the cylinder by moving it with a key that was found, stolen or copied.

Therefore, it is obviously necessary to perform extremely expensive cylinder replacement operations each time a key is lost, stolen, or copied.

In particular, there are advanced cylinders that are supplied directly by the manufacturer with two or more additional sets of keys. If one of the keys from one of the set is lost, then after a number of coding and complex operations are performed with the cylinder, it is possible to change its code combination, thus adapting it to one of the keys from at least one other set.

The cost of these advanced cylinders is very high, and, moreover, they limit the capabilities of the user, since they generally provide only one code combination change (the cylinder is generally associated with only two sets of keys). Therefore, if the key from the second set is lost (after the first change of the code combination has been performed), it will be necessary to replace the entire cylinder.

Description of the invention

The aim of the present invention is to solve the above problems by providing a transcoded cylinder with greater flexibility.

For this purpose, the object of the invention is to provide a transcoded cylinder, which is configured to have an unlimited number of different encodings.

Another objective of the present invention is the provision of a transcoded cylinder, which has a low cost, is easy and practical to implement and reliable in use.

This goal and these and other objects, which will become clearer in the future, have been achieved by a transcoded cylinder of the type containing a stator provided with a substantially cylindrical hole for the rotor, and channels for at least one corresponding pin made with the ability to move, so that he could slide in them against the corresponding elastic means, moreover, the simultaneous placement of said pins partially in said rotor and partially in said st the atore determines the fixation of the said rotor, and alignment of the end edge of the said pins with the interface between the stator and the rotor, achieved by inserting a suitable key with a complex profile into the rotor hole that faces the channels, determines the free rotation of the said rotor relative to the said stator, characterized in that at least one of said pins is formed by a pair of substantially complementary valves that are provided along at least one corresponding common surface and connecting with at least one corresponding profile of the first valve and at least one corresponding counter profile of the second valve, the first valve being able to translate relative to the stator and rotor, the second valve being able to translate and rotate along a predetermined angular stroke relative to the stator and a rotor, and wherein the second valve comprises support means for a special device associated with it by means of an auxiliary channel of the rotor, which ory converted to said support means.

Brief Description of the Drawings

Additional characteristics and advantages of the invention will become clearer from the detailed description that follows a preferred, but not the only embodiment of a transcoded cylinder according to the invention, which is illustrated for the purposes of non-limiting example in the accompanying drawings, in which:

Figure 1 is a front view of the lock stator according to the invention;

Figure 2 is a view in longitudinal section of the stator in Figure 1;

Figure 3 is a side view of the rotor of the castle according to the invention;

Figure 4 is a view in longitudinal section of a rotor in Figure 3;

Figure 5 is a front view of the rotor in Figure 3;

Figure 6 is a view in section of a rotor in Figure 3;

Figure 7 is a perspective view of a device for changing a combination code of a lock according to the invention;

Figure 8 is a perspective view of a sliding component of a lock according to the invention;

Figure 9 is a side view of the component in Figure 8;

Figure 10 is a perspective view of a sliding and pivoting component of a lock according to the invention;

Figure 11 is a side view of the component in Figure 10;

Figure 12 is a schematic view of a first step a) changing a code combination in a lock according to the invention;

Figure 13 is a schematic view of a second step b) changing a code combination in a lock according to the invention;

Figure 14 is a schematic view, in cross section along the transverse plane, of the second step b) of changing the code combination in the lock according to the invention;

Figure 15 is a schematic view of a third step c) changing a code combination in a lock according to the invention;

Figure 16 is a schematic view, in cross section along a transverse plane, of the third step c) of changing a code combination in a lock according to the invention;

Figure 17 is a local schematic view, in section along a longitudinal plane, of the third step c) of changing a code combination in a lock according to the invention;

Figure 18 is a schematic view of the connection between the two valves making up the pin and the fixture in the third step c) changing the code combination in the lock according to the invention;

Figure 19 is a schematic view of the connection between the two valves making up the pin in the third step c) changing the code combination in the lock according to the invention;

Figure 20 is a schematic view, in cross section along a longitudinal plane, of a fourth step d) changing a code combination in a lock according to the invention;

Figure 21 is a schematic view of a fifth step e) changing a code combination in a lock according to the invention;

Figure 22 is a schematic view of a sixth step f) changing a code combination in a lock according to the invention;

Figure 23 is a schematic view of a seventh step g) changing a code combination in a lock according to the invention.

MODES FOR CARRYING OUT THE INVENTION

With reference to the figures, reference numeral 1 generally denotes a transcoded cylinder.

Specifically, the transcoded cylinder 1 comprises a stator 2 provided with a substantially cylindrical hole 3 for the rotor 4.

In the rotor 4 and stator 2 channels 5 are made for at least one corresponding pin, made with the possibility of movement, so that it can slide against the corresponding elastic means.

Specifically, in each channel there is a pin, a counter pin, with its end end resting on the pin head, and an axial spring, with its end end resting on the initial end of the counter pin and its initial end resting on the lower part of the channel.

The elastic action of the spring biases the pin to the position of simultaneously obstructing the rotor 4 and the stator 2. In practice, the pin is located simultaneously in the channel section formed inside the rotor 4 and in the channel section formed inside the stator 2, which prevents mutual rotation.

Naturally, in the cylinder 1 provided with a plurality of pins (which, in general, have different lengths depending on the combination of the cylinder 1 and the corresponding key 7), the rotor 4 cannot always rotate relative to the stator 2 when at least one of these pins is located simultaneously in the section of its channel formed in the rotor 4, and in the corresponding section formed in the stator 2.

However, if, due to the insertion of the key 7 in the rotor 4 hole 6 having the correct code combination (i.e., its profile shape corresponds to the sizes of the various pins available), the terminal edge of the pins aligns with the interface between the stator 2 and the rotor 4, then this determines free rotation the rotor 4 relative to the stator 2 with the subsequent possibility of the wedge 8 to control the movement of a possible spring latch / valve, available in the lock associated with the cylinder 1.

According to the invention, at least one of these pins is formed by a pair of substantially complementary valves 9, 11, which are provided with a profile along at least one corresponding common connecting surface.

In particular, the first valve 9 has a profile 10, and the second valve 11 has a corresponding counter profile 12.

The first valve 9 can translate relative to the stator 2 and rotor 4. This serves to ensure that the pin glides along the corresponding accommodating channel 5, in order to set mechanical properties similar to those of a traditional pin in a traditional cylinder (the second valve 11 is actually in the working the configuration of the cylinder 1 is made in one with the first valve 9 and, therefore, performs translational movement with it inside the corresponding channel 5).

The second valve 11 can perform translational (together with the first valve 9 during normal use of cylinder 1) and rotational movement, along a predetermined angular stroke, relative to the stator 2 and rotor 4 (rotation can also occur relative to the first valve 9, which, however, cannot rotate relative to the stator 2 and rotor 4).

The second valve 11 comprises support means for a special tool 13 connected with it by means of an auxiliary channel 14 of the rotor 4, the channel 14 facing the support means of the second valve 11.

The mutual connection of the first valve 9 and the second valve 11 can be carried out by different mutual engagement of the profile 10 with the counter profile 12. The different position of the engagement determines the different total height of the pin formed by the two valves 9 and 11 connected in this configuration.

This means that the pin formed by the two valves 9 and 11 may have a length that varies depending on the mutual engagement configuration.

According to a specific embodiment described for illustrative and non-limiting purposes, the first valve 9 may be formed by an internally hollow drum that does not have a portion of its lateral cylindrical surface 15.

In this case, a profile 10 is provided along one of the two end edges of the side cylindrical surface 15 for selectively connecting to the second valve 11.

With specific reference to the embodiment described previously, the first valve 9 may thus comprise along the side of the cylindrical surface 15 essentially on the side opposite the missing portion, a protruding tooth 16 that is slidable inside the corresponding groove 16a of the translational channel 5 moving the pin formed by the first valve 9 and the second valve 11.

The protruding tooth 16 is reliably configured to prevent rotation of the pin (especially the first valve 9 and, when they are mechanically connected, the second valve 11) relative to the rotor 4 and the stator 2.

With specific reference to an embodiment of undoubted applied interest, for the purpose of explaining the characteristics of a particular embodiment of the invention without limiting its scope, the second valve 11 is formed by an insert with a shape and size that substantially complements the shape and size of the drum forming the first valve 9.

Note that in this case, the angle limiting the outer protrusion 17 aligned with the lateral cylindrical surface 15 of the first valve 9 is less than the angular magnitude of the lateral cylindrical surface 15 of the first valve 9.

The difference between the two angular values of the lateral cylindrical surface 15 and the protrusion 17 determines the specified angle of the possible mutual rotation of the second valve 11 relative to the first valve 9.

In fact, the second valve 11 can rotate from the first configuration, in which its counter-profile 12 is engaged with the profile 10 of the first valve 9, into the second configuration, in which its supporting surface 18 rests on the corresponding supporting surface 19 of the first valve 9.

Along one end surface of the protrusion 17 (the surface opposite the abutment surface 18) there is a counter profile 12 for selectively connecting to the first valve 9 (specifically, for connecting to the profile 10 of the first valve 9).

The second valve 11 comprises along the outer part of the protrusion 17, essentially on the side opposite the area intended for connection with the first valve 9, the protrusion 20, which constitutes the support means for the device 13 mentioned earlier.

The operation of the device 13 on the protrusion 20 determines the rotation of the second valve 11 relative to the first valve 9 at a predetermined angle, followed by mutual spacing and uncoupling of the profile 10 and the counter profile 12.

According to a specific embodiment, with a specific practical and applied interest, the predetermined angle has a value of approximately 30 °. It is possible that various angles of rotation can be used according to specific application requirements.

Profile 10 and counterprofile 12 are preferably formed by special cut teeth, which are essentially in the form of a gear rack.

According to this particular embodiment, the cut teeth of the first valve 9 are selectively and releasably connected to the cut teeth of the second valve 11, just as the teeth of the two gear racks are mutually connected.

According to a particular embodiment shown in the accompanying figures for illustrative purposes only, without limiting the scope of the application of the present invention, the device 13 may be formed by an elongated element provided with at least one recess 21 with a size and shape substantially complementary to the size and shape of the protrusion 20. which protrudes from the second valve 11.

After inserting the device 13 into the auxiliary channel 14 of the rotor 4, the protrusion 20 engages in at least one recess 21, followed by rotation of the second valve 11 relative to the first valve 9 by a predetermined angle. This determines the mutual disengagement of the profile 10 and the counter profile 12.

A method for changing a code combination of a transcoded cylinder 1 consists of a plurality of sequential steps aimed at changing the length of at least one pin.

Firstly, at the first stage a) it is necessary to insert the initial key 7 into the hole 6 of the rotor 4 (key 7 with a profile configured to bring the pin formed by two valves 9 and 11 into the position of the rotor 4 to be released from the stator 2).

Further, in the second step b), it is necessary to turn the key 7, when it is inserted into the hole 6 of the rotor 4, by a certain angle in a certain direction of rotation. According to a possible application example, it can be rotated clockwise by an angle of 30 °.

In the third step c), the device 13 is inserted into the corresponding channel 14. This determines the rotation of the valve 11 relative to the valve 9, followed by the disengagement of the profile 10 from the counter profile 12.

Then, in step d), it will be possible to remove the original key 7 from the hole 6 of the rotor 4.

In the next step e), it is necessary to insert a new key 70 with a different code combination (key 70, which will have a thickness different from the corresponding thickness at least on the area that will be directed to at least one pin formed by two valves 9 and 11 initial key 7).

More specifically, another code combination of the new key 70 relative to the original key 7 will consist in a different sequence of its profile. Specifically, the difference in the profile will be located on its part, which is directed to the pin formed by a pair of valves 9 and 11, when the key 70 is fully inserted into the hole 6.

With the new key 70 inserted, step f) includes turning it when it is inserted into the hole 6 of the rotor 4, by a certain angle (having the same value as the angle of rotation described in step b)) in the direction of rotation opposite to the direction of step b) in order to position cylinder 1 in the initial configuration.

Thus, the valve 11 is installed at a height specified by the shape of the key 70 relative to the valve 9.

At this stage, the final step g) requires the removal of the device 13. Removing the device 13 determines the reverse rotation of the valve 11 until the profile 10 is fully connected to the counter profile 12, thus making the length of the pin formed by the two valves 9 and 11 connected in this configuration unchanged and fixed .

Preferably, the present invention solves the characteristic problems of cylinders of a known type by providing transcoded cylinder 1 with greater flexibility. In fact, it can be re-encoded an unlimited number of times by selecting each time new keys of type 70 corresponding to cylinder 1, but without the need to supply them as an auxiliary set when purchasing cylinder 1. Then, if it is necessary to re-code cylinder 1, the user only needs to buy a new key 70 and perform the steps indicated previously.

The invention thus proposed allows for numerous modifications and alterations that all fall within the scope of the appended claims. Moreover, all parts can be replaced by other, technically equivalent elements.

In the shown embodiments, the individual characteristics shown in relation to specific examples can in fact be replaced by other, different characteristics existing in other embodiments.

In practice, the materials used, as well as the dimensions, can be any according to the requirements and prior art.

Where the technical features mentioned in any clause are followed by reference numerals and / or marks, these reference numerals and / or marks were included solely for the purpose of increasing the clarity of the claims, and accordingly, such reference numerals and / or marks do not have any limiting effect on the interpretation of each element indicated as an example by such a reference position and / or sign.

Claims (7)

1. A recoded cylinder containing a stator (2), provided with a substantially cylindrical hole (3) for the rotor (4), and channels (5) for at least one corresponding pin made in the rotor (4) and stator (2) with the possibility of sliding movement in them under the action of the corresponding elastic means, and the simultaneous placement of the pins partially in the rotor (4) and partially in the stator (2) determines the fixation of the rotor (4), moreover, alignment of the terminal edge of the pins with the interface between the stator (2) and rotor (4), semi by inserting a suitable key (7) with a complex profile into the hole (6) of the rotor (4), which is facing the channels (5), determines the free rotation of the rotor (4) relative to the stator (2), at least one of the aforementioned the pins are formed by a pair of essentially complementary valves (9, 11), which are provided, along at least one corresponding common connecting surface, at least one corresponding profile (10) of the first valve (9) and at least one corresponding counter profile (12) the second valve (11), and p the first valve (9) is capable of translational movement relative to the aforementioned stator (2) and rotor (4), the second valve (11) is capable of translational and rotational movement, along a predetermined angular stroke, relative to the stator (2) and rotor (4) and moreover, the second valve (11) contains support means for a special device (13) associated with it by means of an auxiliary channel (14) of the rotor (4), which is facing the support means, characterized in that the first valve (9) is formed by an internal hollow drum, which about there is no portion of its lateral cylindrical surface (15), and said profile (10) for selectively connecting to the second valve (11) is provided along the end edge of the lateral cylindrical surface (15), while the second valve (11) is formed by an insert with shape and size, which substantially complement the shape and size of said drum constituting the first valve (9), the angle defining the outer protrusion (17) aligned with the lateral cylindrical surface (15) of said first valve (9) is less than the angular magnitude of the sides the cylindrical surface (15) of the first valve (9), and the difference between the two angular values of the lateral cylindrical surface (15) and said protrusion (17) determines the specified angle of the possible mutual rotation of the second valve (11) relative to the first valve (9). 2. A transcoded cylinder according to claim 1, characterized in that said first valve (9) comprises, along said lateral cylindrical surface (15), a protruding tooth (16), which is configured to sliding inside the corresponding groove (16a) of the channel (5) for translational movement of the pin formed by the first valve (9) and the second valve (11), and configured to prevent rotation of the pin relative to the rotor (4) and torus (2). 3. A recoded cylinder according to claim 1, characterized in that said profile (10) is provided along one end surface of the protrusion (17) for selectively connecting to the first valve (9). 4. The encoded cylinder according to claim 1, characterized in that the second valve (11) comprises, along the outer surface of said protrusion (17), essentially from the side opposite to the region intended for connection with the first valve (9), a protrusion (20 ), which constitutes said support means for said device (13), moreover, the operation of said device (13) on said protrusion (20) determines the rotation of the second valve (11) relative to the first valve (9) by a predetermined angle, followed by mutual separation and disengagement of the profile (10) and counter against splintering (12). 5. The encoded cylinder according to claim 1, characterized in that the profile (10) and the counter profile (12) are formed by special cut teeth, which are essentially in the form of a gear rack, and the cut teeth of the first valve (9) are selectively and releasably connected to the cut teeth second valve (11). 6. A recoded cylinder according to claim 4, characterized in that said device (13) is formed by an elongated element provided with at least one recess (21) with a size and shape substantially complementary to the size and shape of said protrusion (20) of the second valve ( 11), and after inserting the device (13) into the auxiliary channel (14) of the rotor (4), said protrusion (20) engages in said at least one recess (21), followed by rotation of the second valve (11) by a predetermined angle and mutual disengagement profile (10) and counterprofile (12). 7. A method of changing a code combination of a transcoded cylinder (1) according to claim 1, comprising the steps of:
a) inserting the initial key (7) into the hole (14) of the rotor (4);
b) turning the key (7) when it is inserted into the hole (14) of the rotor (4) by a certain angle in a certain direction of rotation;
c) inserting the tool (13) into the corresponding channel (14);
d) removing the original key (7) from the hole (6) of the rotor (4);
e) inserting a new key (70) with a different code combination, that is, an excellent sequence of its profile located on its part, which faces the said pin formed by a pair of valves (9, 11) when it is fully inserted into the aforementioned hole (6) ;
f) turning the new key (70) when it is inserted into the hole (6) of the rotor (4), at a certain angle in the direction of rotation, opposite to the direction of step b), in order to position the cylinder (1) in the initial configuration;
g) removing the tool (13).

Images