FR3032218A1 - DISC TYPE LOCK AND KEY FOR ACTUATING THE BARREL OF THIS LOCK - Google Patents

Abstract

The invention relates to a disk lock, comprising a cylindrical barrel (1) and its key (2), the barrel comprising a stator (3), a rotor (5), a locking member (21) which passes through the interface (23) between the stator (3) and the rotor (5) and thereby locks the lock, the rotor comprising a set of coded rings (7) movable in rotation, the rod (20) of the key being cylindrical and provided with coded means cooperating with the codes of rings (7), the key when rotated driving the rotor (5), the member (21) having then eclipsed. The lock is characterized in that the body (6) of the rotor (5) is pierced at the right of each ring (7) of at least one through-light (30), at least two rings each having a projection (31) which penetrates the light (30) and emerges inside the path (16) of the key (2), the rod (20) of which has at least one groove (32) capable of receiving the projection (31) on the surface, the rings (7) having at least one notch (41) whose width is greater than that of the locking member (21), the notches (41) being aligned and forming a straight trench after the key has been inserted thoroughly in the passageway (16) of the rotor (5), the member (21) being received in the trench from the beginning of the rotation of the key so as to disengage the interface (23) and to disengage the rotor (5) of the stator (3).

Description

BACKGROUND OF THE INVENTION The present invention relates to a lock of the disc type, comprising a barrel and a key intended to actuate the locking mechanism. locking / unlocking of said lock, 10 barrel comprising a stack of coded cylindrical rings suitable for being decoded either by a key specific to this lock, or by a master key, partial or general. The present invention obviously also for objects each of the components, key and barrel, of such a lock. BACKGROUND OF THE INVENTION In assemblies consisting of a cylinder lock and its key, each barrel comprises a stator (or cage) in which a rotor can rotate under the action of the key. When the key is disengaged from the lock, locking members are in the active position, that is to say they mechanically couple the rotor and the stator, preventing the rotation of the first inside the second, and thus preventing the opening of the lock. When the key is engaged in the lock, and as far as of course this key decodes the codes of all the locking members, the latter are then retracted into an inactive position for which the mechanical coupling between the rotor and the stator ceases and the rotor-stator interface is thus released. Under the action of the key, the rotor can then rotate freely inside the stator and control, for example via a driver associated with a bit, the locking / unlocking device of the lock. . In the most common locks, the barrels are either pins or discs. -2- For barrels with pins, obtaining a different coding for the use of a partial master or a general master is acquired by stacking pins of different heights corresponding to codes. different. A large number of codes are therefore consumed. For disc cylinders, obtaining a different codification for the use of a partial master or general master is acquired by widening the passage of the locking member, which member is most often a mint. Such an enlargement, necessary for the free passage of the lug, has the effect of causing this time again a significant loss of codes. This significant loss of codes is characteristic of the 15 disc barrels. It is known on this subject that, while the barrel may have several hundred thousand possible individual codes, the fact of wanting to associate a master key with several locks discs will require an enlargement of the slot for receiving the latch as 20 that this enlargement will "eat" a lot of codes and that, to a boilerplate, it can therefore only be associated with a few hundred individual keys. A first object of the present invention is to eliminate such code losses when it is necessary, in large installations, to use specific locks, individual, and to associate with each of these individual locks to less a master key, whether it is general or, if necessary, only partial. In addition, for both pin drums and for disc drums, each code of a pin or disk corresponds to a precise decoding point on the key adapted to the drum. This decoding point is generally located either in a hollow of a cam path alternating hollow and reliefs, or at the bottom of a blind hole. It is also known that many doors, in particular of apartment, do not have a handle or any gripping member on their side disposed towards the outside. Confronted with this construction, the user, when he must close the door to pull it from the outside, has no other solution than to pull the key while it is in the unlocked position, but still stowed with the barrel. Because of repeated shocks and rubs as a result of a multiplicity of door closures, it is understood that the key wears at each of its decoding points, so that, over time, these points will no longer be located in front of the pins or disks they must decode and the key will then no longer exert its function of unlocking the lock. It is therefore necessary in such cases to proceed to the complete change of the lock. A second object of the present invention is to eliminate this other disadvantage. SUMMARY OF THE INVENTION The subject of the present invention is therefore a lock of the type known as discs, comprising a cylindrical barrel and its key for actuating a locking / unlocking mechanism of said lock, the barrel comprising a stator whose body generally has the shape of a hollow cylinder and a rotor rotating in the stator and whose body also generally has the shape of a hollow cylinder, a locking member actuated by magnetic means placed in the stator and permanently reminding said member in the direction of the stator so that it passes through the interface formed between the stator body and the rotor body and thus locks the lock, the rotor comprising a cylindrical set of coded rings stacked around its body, each said coded rings being rotatable about said body, said rotor further comprising an inlet opening for insertion key and an exit opening which is opposed to the entrance opening and which is provided with a bit driving means controlling the actuation of the lock bolt, said rotor also comprising a path of axial passage of the key which extends between the two openings and a pin disposed in the vicinity of the inlet opening, projecting into the passageway and serving to guide the movement of advance or withdrawal of the key, the stem of said key being cylindrical and provided with a longitudinal groove, cooperating with the stud, and coded means co-operating with the codes of the crowns, the key when it is introduced into the passageway of the rotor thus being able to be driven longitudinally, guided by the nipple, until it comes to couple with the driver of the bit, and to be then turned freely by driving in the same rotational movement the rotor and its stack of crowns as well as the driver of the bit, the locking member which, in working position, that is to say locking, through the interface between the rotor and the stator having then eclipsed, said lock being characterized in that that the rotor body is pierced at the right of each ring of at least one through-light, at least two rings each having a finger-shaped projection which penetrates the pierced light at the right of this ring so as to emerge inside the path of passage, the key shaft having at least one sinuous groove on the surface adapted to receive the ring finger, the progressive advance of the key inside the rotor causing the rotation and thus the decoding of the crowns, and their gradual transition from an initial locking position to their final unlocking position, all the crowns having over their entire thickness at least one notch whose width is slightly greater than c it of the locking member, the notches crowns being in perfect alignment and thus forming a straight trench under the control of the key after the latter has been fully inserted into the path of the rotor, the organ latch being received in the trench from the beginning of the rotation of the key so as to clear the interface and cause the disengagement of the rotor relative to the stator, and thus allow the rotation of the key, the rotor and that of the coach. According to a particularly advantageous construction, each ring is constantly biased by a spring towards its initial locking position, a position in which its notch is not placed opposite the locking member, thus making it impossible to form the ring. trench. In particular to allow the use of master key, the body of the rotor is pierced, at the right of each ring, two through lights and the key shank has two sinuous grooves on the surface. Preferably, in this variant of construction, a sinuous groove cooperates with a part of the crowns, by means of emerging fingers which are provided with these crowns, while the second sinuous groove cooperates with the other part of the crowns. Still in the hypothesis of having to use at least one master key in addition to the key specific to the lock, at least one crown has at least two notches throughout its thickness, conferring at least two possible positions in it. organization of the trench. According to another preferred construction, the bit driver is provided with a pin which extends along the central axis of the barrel, the cylindrical rod of the key then being hollowed in order to receive this pin. In this case, advantageously, the length of the recess of the shank of the key is such that the bottom of this recess abuts the free end of the spindle of the driver, which has the effect of causing the recoil of the coach up to 25 the release of its housing and allow its stowage on the bit of the lock. According to yet another preferred construction, a lug secured to the locking member enters the key from the beginning of the rotation of the latter, thereby preventing the key from being removed during any locking / unlocking operation. Very advantageously, each light is hollowed out along an arc of the order of 1200, the proximal ends of the two lumens being separated from a solid sector extending along an arc of the order of 60 °. In the latter case, the lights are preferably then symmetrical two by two with respect to the vertical plane of symmetry of the cylinder and the starting points of the two sinuous grooves of the key are also symmetrical with respect to this vertical plane of symmetry. . The detailed specifications of the invention are given in the following description in conjunction with the accompanying drawings. It should be noted that these drawings have no other purpose than to illustrate the text of the description and that they do not constitute in any way a limitation of the scope of the invention. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a longitudinal vertical sectional view along I-I of a first variant of the lock according to the invention, the key of this lock being engaged in its barrel just before docking.

Figure 2 is a cross-sectional vertical sectional view along II-II of the lock shown in Figure 1. Figure 3 is a transverse vertical sectional view according to a construction variant of the cylinder shown here without its key.

FIG. 4 is a transverse vertical sectional view along IV-IV of the barrel illustrated in FIG. 3. FIG. 5 is a top view of the rotor of the barrel shown in FIG. 3. FIG. 6 is a cross-sectional view according to FIG. VI-VI 25 of the rotor shown in Figure 5. Figure 7 is a longitudinal vertical sectional view along VII-VII of the barrel stator. Figure 8 is a front view of the stator of Figure 7. Figure 9 illustrates two adjacent crowns which, to reach their unlocking position, rotate one in the forward direction and the other in the retrograde direction. the respective positions of the point of attachment of the spring constantly reminding the crown to its initial locking position and that of the finger which penetrates the light of the crown and emerges inside the pathway. Figure 10 is a schematic view of the two grooves of the key, said key cooperating accordingly with a barrel receiving a stack of crowns suitable for some, to turn in the forward direction and for others, to rotate in the retrograde direction to unlock the lock.

DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION The lock according to the invention comprising a cylindrical barrel 1 and its key 2 for actuating the locking / unlocking mechanism of said lock is of the type 10 referred to as disks. In the example shown, its barrel is of the type commonly called "European", easily recognizable by its appearance. The European cylinder shown is simple, that is to say a single key entry, but it is clear in this respect that the invention also applies to double European cylinders, two key-in, but also to any other lock cylinder whose two essential constituents, rotor and stator, are cylindrical. In known manner, its barrel 1 consists essentially of a stator 3 whose body generally has the shape of a hollow cylinder extended by an appendage 4, usually vertical and facing downwards, and a rotating rotor 5 in the stator and whose body 6 also has the overall shape of a hollow cylinder. In the case of a so-called disc lock, the cylindrical body 6 of the rotor receives a stack of coded cylindrical rings 7 which are rotatably mounted around said body 6. For this purpose, the diameter of the central orifice pierced in Each ring 7 is very slightly greater than the outside diameter of the body 6 of the rotor. If each of the rings 7 of the stack can turn around the body 6 of the rotor 5 by an angle which will be detailed below, conversely each ring 7, and the resulting crown stack, is 35 locked in translation on the body of the rotor between a head 8 formed integrally with the body of the rotor 5, located on the side of the entry 9 of the lock, and a bearing ring 10 located on the output side 11 the lock, that is to say close to the -8- lock / unlock mechanism of the lock consisting of bit 12 and its driver 13. In the example shown, such a driver 13 is inside the body 5 of the rotor and is mounted mobile in translation opposite the outlet 11 of the lock. After the coded rings 7 have been arranged around the rotor body, the ring 10, which prevents any possibility of translation for the stack of rings, is thus also locked in translation on the end portion of the body 6 of the rotor 5, either by screwing, or by means of screws 14 whose rods each pass radially through the ring 10 until they penetrate into a blind hole 15 drilled in the body 6 of the rotor (FIG. 1), or because of the translational support exerted by an end sleeve 33 locked at the end of the body 6 of the rotor, on the output side 11, this locking being ensured either by a clip 34 (FIG. 1) or by screwing around said end of the rotor body ( Figure 3). The body 6 of the rotor is further pierced longitudinally, from the front face of its inlet head 8 to its outlet face, with a cylindrical hole 16 so as to form an axial passageway of the key 2 which extends between the inlet opening 9, for the introduction of said key, and the outlet opening 11 which is opposite the inlet opening 9 and which is provided with the means 13 d driving the bit 12 25 controlling the actuation of the bolt of the lock. In order to guide the movements in translation of advance and withdrawal of the key 2 in this passageway 16 of the body 6 of the rotor 5, there is provided in the vicinity of the inlet opening 9 a fixed stud 17 which protrudes 18 in said passageway and which is adapted to cooperate with a longitudinal groove 19 formed over the entire length of the rod 20 of the key 2. The rod 20 is itself cylindrical and, close to the game, congruent rotor , therefore of an outer diameter very slightly less than the diameter of the longitudinal hole 16 of the body 6 of the rotor. Thanks to the pin 17, which may be for example a keyed piece forcibly in the head 8 of the rotor, and the longitudinal groove 19 of the key, the latter is exactly -9- guided in all its movements in translation inside. of the rotor 5 of the barrel 1 and it is however locked in rotation relative to said rotor, the rotation of the key 2 is accordingly permitted only on the condition that the rotor 5 rotates with it by driving the same movement. Still in known manner, the barrel 1 comprises a member 21 locking the rotation of the rotor 5 inside the stator 3, this locking member being actuated by magnetic means 22 which are placed in the stator 3 and which permanently recall said locking member 21 towards the stator so that it passes through the interface 23 formed between the stator 3 and the rotor 5 and thus locks the lock. These magnetic means, advantageously centered relative to the member 21, are held in the stator by means of a plug 24. In the present case, a magnet 22 is embedded in the appendix 4 of the stator 3, in the zone connection of this appendix with the hollow cylindrical body of the stator, and the locking member is a latch 21 of steel on which the magnet permanently exerts its attraction, which has the shape of a very elongated U of which the core is parallel to the longitudinal axis of symmetry 40 of the body of the rotor 5 and is of a length slightly greater than the height of the stack of coded washers 7. The end flanges 36 and 37 of the lug 21, perpendicular to this soul, facing the longitudinal axis of symmetry 40, thus frame the stack of washers. In the locking position, the core of the lug is the part of this member which overlaps the rotor / stator interface 23 of the barrel.

In the case where the key 2 corresponds to the coding of the rings 7 of the rotor, the latch 21 must release this interface 23 and consequently allow the rotation of the key and that of the rotor and, as a result, the rotation of the bit 12 which , in engagement with its trainer 13, will thus cause the unlocking of the lock. To this end, the top 25 of the core of the lug 21 is beveled V-shaped so, when the lock is locked, to be able to penetrate a groove 26 also in V formed in the body of the stator 3 by two symmetrical flanks which originate at the interface 23, which are at an angle of the order of 90 ° and which converge towards the free end of the appendix 4 of the stator 3, near the magnet 22 .

Thus, provided of course that the key 2 decodes all the codes of the stack of crowns 7, the least effort exerted on the head 27 of the key to turn it in the barrel will cause a gradual release of the beveled portion of the core 21 relative to its groove 26 and, consequently, the release of the rotor / stator interface 23. The force applied mechanically on the head of the key, multiplied at the rod 20, will indeed be significantly greater than the force of attraction exerted continuously by the magnet 22 on the lug 21. The user will thus be in a situation allowing him to unlock the lock. In a construction shown in FIG. 1, the two wings 36 and 37 of the lug 21 are of a height such that, in the unlocked position of the lock, the interface 23 thus being completely released, they only flush out the outer surface of the rotor body 6. In this construction, the wing 37 of the lug 21 located on the side of the entry 9 of the lock can then be advantageously extended by a lug 28 which passes through the body 6 of the rotor 5 so that, still in the unlocking position of the lock, it can emerge in the way of passage 16. In this particular construction, the key 2 will accordingly be provided at the base of its rod 20 with a mortise 29 in which penetrate the end of the lug 28 of the latch .

This will secure the key on the rotor as long as the latch 21 release the interface 23. The consequence of this construction is that it will be impossible to remove the key 2 from its path 16 when, after entering to the bottom of the pathway and thus decoded the code of each of the rings 7 of the stack, said key will rotate with the rotor and the driver 13 of the bit 12. -11- Finally, the body 6 of the rotor is pierced at the right of each coded crown 7 of at least one through-light 30 and at least two rings 7 each have a finger-shaped projection 31 which penetrates the pierced light in line with the crown concerned, and which is of such a length as it passes through said light and emerges inside the passage path 16. The rod 20 of the key has on the surface at least one and preferably two sinuous groove (s) 32 whose design and realization go be explained below, lad ite (or said) groove (s) sinuous (s) being adapted (s) to receive the free ends of the fingers 31 which emerge inside the pathway. In a preferred construction shown in Figure 2, the body 6 of the rotor is pierced at the right of each ring 7 of two diametrically opposed through holes 30 which each extend over a circular arc of 120 °. The proximal ends of the two lumens 30 made in line with the same crown 7 are thus separated from an arc which extends over 60 °. As for the crowns 7, which are made of a non-magnetic material of the brass, zamak or nickel silver type in order to be insensitive to the force of attraction exerted by the magnet 22, they are each provided at their periphery, and over their entire thickness, at least one notch 41 (in fact two notches 41 for some of the crowns of a specific lock to which it will be necessary to associate a master key and three notches 41 for some of the crowns of a specific lock to which it will be necessary to associate two passe-partout, the one partial and the other general). Advantageously, in order to avoid any friction between two adjacent crowns during the rotation, for the purposes of its decoding, of at least one of these two neighboring crowns and to be thus certain that, as a result of the progressive advance of the rod 20 of the key 2 in its path 16, each crown will finally occupy the correct position provided by construction, it will always be disposed between two adjacent rings an annular cylindrical clip 38, for example hardened steel . Thus, the stack of crowns will consist in fact of a stack alternating crowns 7 and clips 38. It may even be envisaged that, as represented in FIG. 1, the clips cooperate with circular grooves 39 of V section formed. on the surface of the rotor body. Each groove receives a clip, and the pitch separating two adjacent grooves is slightly greater than the thickness of a ring 7 increased by that of a clip 38. Regardless of the construction envisaged, the outer diameter of the clips 38 is much less than that of the crowns 7 so as not to hinder the formation of the trench which, as will be explained, is essential to decode the lock. As will be described below, the or each notch 41 placed on the periphery (hereinafter "peripheral notch") of a crown 7 is its code or one of its codes that the key 2 associated with the barrel 1 must decode to achieve the unlocking of the lock. If the lock is unique, personal, and is not intended to cooperate with a mat, it will be sufficient that each ring 7 of the inner stack to its barrel has one and only one peripheral notch 41. However, if the lock is only one of a substantial installation that includes several tens, several hundreds or thousands of locks, some of the crowns, or even all the crowns of the inner stack to its barrel will then have two peripheral notches, allowing thus the use of a passe-partout in addition to the personal key, even three peripheral notches if it is necessary to authorize the use of two passe-partout, one general and the other partial.

The role of the various notches 41 present peripherally on the rings 7 is to receive the core of the lug (by the non-chamfered portion thereof) when said crowns are simultaneously decoded. From the foregoing, it is understood that the lug 21 can not completely release the rotor / stator interface 23 and thus allow the rotation of the rotor inside the stator, under the control of the rotation of the key, that the provided that the notches of the various crowns are perfectly aligned and thus form a trench in which the core of the core penetrates, wings 36 and 37 of said latch then simultaneously flush with the outer surface of the rotor. In the case of single, individual locks, it suffices therefore 5 that each of the rings 7 of a particular cylinder has a notch 41 and that this cylinder is associated with a precise key capable of decoding the different codes corresponding to these notches, c that is, to ensure that, in the end, all the notches 41 of the stack of its crowns 7 10 align perfectly under the action of the key introduced into the passageway and that the trench obtained because of this alignment of notches 41 is formed exactly opposite the soul of the latch 21. However, if the lock must be able to be decoded by the individual key, but also by a master key, it is essential that this passe-partout leads to the formation of a trench different from that formed under the action of the individual key. It is therefore understood that at least one of the crowns 7 of the stack must have a second notch 41, the second notch that only the mat can decode by bringing it into the desired alignment for the formation of a trench "Bis", replacing the first notch of the same crown, which it will be shifted from this trench "bis". To create a master key, it is therefore necessary that at least one crown of the stack, or even several crowns, or even all the crowns of this stack, present (s) at least two notches. In case of multiplicities of master key, it will even be necessary to provide three notches on one or some of the crowns of the stack so as to be able to form in at least three different ways an alignment of notches 41, each time forming a perfect trench In order to facilitate the understanding of the invention, the dimensions which have been verified as suitable for any lock construction using a European cylinder, but which are only illustrative and are therefore in no way limiting. These dimensions, chosen as examples for example, are: 6 mm for the diameter of the shank of the key, -14- 12 mm for the outer diameter of each ring, 1.5 mm for the width of the core of the 2 mm for the thickness of each crown and 0.5 mm for the thickness of each clip. In this construction, the pitch between two successive grooves 39 is then 2.5 mm. Each through lumen thus has an opening of 6.28 mm at its base facing the key shank of 6 mm diameter (6 x 3.14159: 3). A rotation of 10 therefore corresponds to a transverse stroke of 0.05 mm (6.28 mm: 120) on the surface of the shank of the wrench, transverse stroke which can be used in the definition of the drawing of the sinuous groove 32 on the shank key 2 as well as in the corresponding position of the free end of the finger 31 which protrudes inside the crown and which emerges in the path of passage of the key. To any finger of the stack of crowns will correspond a decoding bearing of a length of 1 mm for example on the sinuous groove or on one of the two sinuous grooves dug along the shaft of the key. For safety, the successive decoding steps provided on any sinuous groove will advantageously be chosen from 100 to 100, that is to say separated by approximately 0.0523 mm × 10, ie about 0.52 mm at the periphery of the groove. stem of the key, this to prevent a code is too close to another code. In a sufficiently strong construction from a mechanical point of view, in which a through-light 30 or each of the two through-lights extends over a circular arc of 120 °, the finger 21 of each ring 7 can thus occupy twelve possible positions and, on the shank of the key, opposite this finger, the corresponding decoding bearing disposed in the sinuous groove can therefore also occupy twelve possible positions. In other words, in the simplest construction in which two rings are stacked on the rotor body and a single groove with two decoding steps is drawn by following sinuosities on the stem of the key, there are then twelve combinations. possible because of the first ring and twelve possible combinations because of the second ring, 144 combinations possible with respect to this elementary construction. This value is however only theoretical since, in the case finally sought where the key decodes all the codes of the crowns, it is necessary that the latch 21 can simultaneously penetrate into the trench formed by an alignment of the notches 41 of the crowns and thus releases the 23 rotor / stator interface. Since the thickness of the lug core is 1.5 mm, it is reasonable to provide that the notches will each have a width of 1.9 mm in order to facilitate penetration of the lug core into the trench which will reproduce this same width of 1.9 mm. It is understood that it is necessary to avoid that an individual key or a partial passkey decodes a coding of crowns close to the coding corresponding to the individual key, a situation which could arise in particular when two codings are distinguished from one another. other than by one of their respective bearings traced transversely opposite the same ring of their stacks, their two bearings constituting their only difference being separated from each other by only the minimum distance of 100, that is to say 0, 52 mm at the periphery of the key shank, distance corresponding to 1.04 mm at the rotor / stator interface. The thickness of the core of the shaft being 1.5 mm and the trench to be formed having a width of 1.9 mm, it must substitute a space of approximately 0.2 mm on each side of the core after penetration of the latter into the trench formed by an alignment of notches, which space is therefore significantly less than the offset of 1.04 mm which must exist between their respective trenches. It is therefore deduced from these data that it is impossible for even for two as possible neighboring codings that it is impossible for an individual key reserved for one of these two codings to be able to decode the other coding. .

In a construction that includes five crowns that can be decoded by a key whose stem is endowed with a single sinuous groove, the amount of possible combinations is therefore 125, or 248,832. With a key whose stem is provided with two sinuous grooves, disposed on either side of the longitudinal plane of symmetry 42 of the key, the crowns being in such a case susceptible, according to their relative provisions, to be 5 decoded after a forward direction rotation or after a retrograde direction rotation, the amount of possible combinations is increased to 497,664, which explains the primary interest of this invention in the very large number of partial and all-purpose passwords. that it is possible to predict and combine. As has been explained in the preceding paragraphs, the decoding of the notches of the washers stacked on the body of the rotor must lead to forming a trench of a nature to receive the soul of the latch after rotation, either in the forward direction, 15 or in the retrograde sense, of all the crowns of the stack. In the case where the through-light (s) pierced in the rotor body extend over an arc of 120 °, it has been seen that the fingers associated with the crowns passing through these lights can occupy twelve different positions, spaced apart from each other. 100 in 10 °. Identically, the bearings 54 formed in the sinuous groove or grooves, in line with the aforementioned crowns, can occupy twelve different positions, spaced by 10 ° in 100. To achieve such a decoding of the crowns, decoding which must be provoked on each crown 7, from the first located closer to the entry 9 of the lock to the last located closer to the exit 11 of the lock, it is therefore necessary that under the control of the key, because of the penetration 30 progressive of the latter in the axial passageway 16, the overall rotation of each ring is effected in the desired direction at an angle such that, ultimately, this overall rotation causes the notch or one of the notches placed at the periphery of said crown opposite the sill. In the construction chosen by way of example, the initial locking position of each ring is at 30 ° with respect to the longitudinal plane of symmetry 42 of the barrel, which coincides with the longitudinal plane of symmetry of the rotor and that of the key. By initial locking position, it should be understood here that the finger 31 projecting from the ring is in abutment on the lower end of the through hole 30 pierced in the body 6 of the rotor 5 which is opposite said ring. This lower end is at 30 ° of the longitudinal plane of symmetry 42. If, on a certain ring, the notch 41 has been formed at 40 ° of this initial locking position, that is to say at 40 ° above the finger 31 associated with this ring, it is necessary that, under the control of the key, the crown is moved in rotation by an angle equal to (180 - 30 - 40) = 110 °. It is, opposite the crown concerned, the same value of 110 ° that the bearing 54 of the sinuous groove 32 of the stem of the decoding key must meet when it has been fully inserted into the path 16 We have seen that the crowns succeed one another in a pitch of 2.5 mm, a distance which would not allow the bearings 54 provided successively along the sinuous groove to be separated by more than 70 °, otherwise the risk would appear. that the key blocks at a certain moment of its advance. It will therefore be ensured that, ideally, the values of the bearings occurring successively along the sinuous groove have, in pairs, differences which do not exceed 70 °.

According to a preferred construction, it will further be provided that the inlet 43 of each sinuous groove 32 has a mouth 44 open at an angle of about 120 ° (60 ° on either side of the horizontality) so as to facilitate, crown after ring, the taking of the free end of the finger 31 by the profile of the sinuous groove 32. It has been shown in Figure 10 four examples of key adapted to cooperate with the barrels comprising a stack of five crowns, the first, third and fifth rings being controlled by the sinuous groove in the right half of the key shank and the second and fourth rings being controlled by the sinuous groove in the left half of the shank of said key. In this construction, the rotation of three rings is thus controlled by the key in a particular direction to build a part of the trench corresponding to the decoding of these rings and the rotation of the two other rings is controlled by said key according to the direction. contrary, still for the purpose of constructing the other indispensable part of the trench in which can thus integrate the soul of the latch 21. The first bearing 54 of a groove 32 is located 4 mm from the end of the key (3mm for the mouth and the primer of the groove and 1 mm under the half-thickness of the crown), and the bearings are then separated 2.5 mm in 2.5 mm from a groove to the other. Thus, in the example where the rotational directions of the rings are alternated, the first bearing of the other groove is located 6.5 mm from the end of the key and the bearings will then be separated by 5 mm along each two grooves. The length of the bearings is ideally 1 mm but it could be less, for example 0.6 mm to 0.7 mm. In FIG. 10, various angular values have been given to form the successive bearings on either of the two sinuous grooves of the key, these values also determining the respective final positions to be occupied by the fingers 31 of the crowns. 7 which pass through the lights pierced in the body of the rotor 5. It will be easy to construct a mat capable of opening the locks corresponding to these four keys, for example by providing an additional notch at 65 ° and 110 ° on, respectively, the second and fourth crowns of the key number 4, two additional slots at 85 ° and 115 ° respectively on the third and fifth rings of the key number 1, an additional notch at 115 ° on the fifth ring of the key number 2 and an additional notch 85 ° on the third ring of the key number 3. 35 A variant of construction can be considered taking into account the very large number number of possible combinations that the invention provides (nearly five hundred thousand). In the twelve positions that each finger 31 of a ring 7 thus encoded can occupy relative to the initial locking position, about one half of these positions, for example seven, can be used to code individual locks and the another half, for example five in the present case, can be used for partial or general master keys. This construction results in 75 x 2, that is to say 33,614 individual locks possible.

After unlocking the lock and removing the key that has decoded the codes of all the crowns 7, the latter must resume all their initial locking positions, that is to say that their fingers 31 are found at 30 ° of verticality.

However, according to a particularly advantageous construction, it can be provided that each ring is constantly recalled by a very fine helical spring 45 towards its initial locking position, position in which its finger 31 is at 30 ° of verticality and its notch is not placed opposite the locking member, thus making it impossible to form the trench. Each helical spring 45 is for example attached at one end to a stud 46 screwed into the thickness of a ring 7 and attached at its other end to a bar 47 which extends parallel to the longitudinal axis of symmetry 40, the level of the rotor / stator interface 23, between a tie-down point 48 formed in the head 8 of the rotor and another tie-down point 49 formed in the bearing ring 10. The stud 46 will advantageously be diametrically opposed To the finger 31 and each bar 47 will extend parallel to the longitudinal axis of symmetry 40 at about 30 ° of verticality, that is to say that it will extend facing the finger or the series of fingers 31 which, on one side of the cylinder, represents the initial locking position of the lock.

In order to be certain that after locking or unlocking the lock according to the invention, the key 2 can be removed without risk of catching a finger 31 in a sinuous groove or hooking of the latch 21 while the one It does not return in the perfect alignment of the groove 26 of the stator 3, there is provided at the right of this groove a device comprising a metal ball 50 constantly pushed towards said groove by a helical spring 51. This set ball 50 helical spring 51 is disposed in an axial conduit pierced in the bearing ring 10 of the stack of rings 7, the spring 51 being supported by its other end on the outer wall of the body 6 of the rotor 5. If the key occupies a position corresponding to perfect verticality after locking or unlocking the lock, the metal ball 50 will then be violently projected against the flanks of the groove 26, due to the extension of the spring 51, which is will result in a perceptible click by the user's ear. The latter can then safely remove his key from the lock. In the construction shown by way of example in FIG. 1, the driver 13 of the bit 12 is advantageously provided with a pin 52 which extends along the longitudinal axis of symmetry 40 of the rotor and the cylindrical rod 20 of the key 2 is then excavated axially from a recess intended to receive this pin 52. By construction, the length of the shank of the key is provided, such that the bottom 53 of this recess abuts on the free end of the spindle of the coach, which has the effect of causing the retreat of the coach to free him from his home and allow its stowage on the bit of the lock. If the key decodes the crowns of this lock, it will then be possible to rotate the rotor and the key which is integral therewith, and consequently to rotate the bit 12, which will control the unlocking or, according to locking the lock. It goes without saying that the invention is not limited to the only preferred embodiments described above. On the contrary, it embraces all the possible embodiments, provided that these do not go beyond the scope defined by the appended claims which define the present invention.

Claims (11)

CLAIMS1) Lock type disc type, comprising a cylindrical barrel (1) and its key (2) for actuating a mechanism (12) for locking / unlocking said lock, the barrel comprising a stator (3) whose body has globally the shape of a hollow cylinder and a rotor (5) rotating in the stator (3) and whose body (6) also has generally the shape of a hollow cylinder, a locking member (21) actuated by magnetic means (22) placed in the stator and constantly reminding said member towards the stator so that it passes through the interface (21) formed between the stator body (3) and the body (6) of the rotor (5) and it thus locks the lock, the rotor comprising a cylindrical set of coded rings (7) stacked around its body (6), each of said coded rings being rotatable around said body, said rotor further comprising an opening of entry (9) for the introduction of the key and an exit opening (11) which is opposite to the inlet opening and which is provided with a means (13) for driving the bit (12) controlling the actuation of the bolt of the lock, said rotor (5) also comprising a path (16) for axial passage of the key which extends between the two openings (9, 11) and a stud (17) arranged in the vicinity of the inlet opening (9), protruding (18) in the passageway (16) and for guiding the forward or backward movement of the key (2), the stem (20) of said key being cylindrical and provided with a longitudinal groove ( 19), cooperating with the stud (17), and coded means cooperating with the crown codes (7), the key when introduced into the passageway (16) of the rotor (5) being thus adapted to be longitudinally driven, guided by the stud (17), until it comes to mate with the driver (13) of the bit (12), and then to be freely rotated by driving into the same rotational movement the rotor (5) and its stack of rings (7) and the driver (13) of the bit (12), the locking member-22- (21) which, in working position, that is to say locking, passes through the interface (23) between the rotor (5) and the stator (3) having then eclipsed, characterized in that the body (6) of the rotor (5) is pierced at the right of each ring (7) with at least one through-hole (30), at least two rings each having a projection (31) in the form of a finger which penetrates the light (30) pierced at the right of this ring so that to emerge inside the passageway (16), the shank (20) of the wrench (2) having on the surface at least one sinuous groove (32) adapted to receive the finger (31) of the crown, the progressive advance of the key inside the rotor (5) causing the rotation and thus the decoding of the rings (7), and their gradual transition from an initial locking position to their final position the unlocking device, all the crowns (7) having over their entire thickness at least one notch (41) whose width is slightly greater than that of the locking member (21), the notches (41) of the rings (7). ) lying in a perfect alignment and thus forming a straight trench under the control of the key after the latter has been fully inserted into the passageway (16) of the rotor (5), the locking member (21) being received in the trench from the beginning of the rotation of the key so as to disengage the interface (23) and cause the rotor (5) to disengage relative to the stator (3), and thus allow the rotation of the key (2), that of the rotor (5) and that of the driver (13). 2) A lock according to claim 1, characterized in that each ring (7) is constantly biased by a spring (45) to its initial locking position, in which position its notch (41) is not placed opposite the locking member (21), thus making it impossible to form the trench. 3) A lock according to any one of claims 1 and 2, characterized in that, in line with each ring (7), the body (6) of the rotor (5) is pierced with two through-holes-23- (30) and in that the rod (20) of the key (2) has two sinuous grooves (32) at the surface. 4) A lock according to claim 3, characterized in that a sinuous groove (32) cooperates with a portion of the rings (7), through the emerging fingers (31) which are provided with these rings, while the second groove sinuous (32) cooperates with the other part of the rings (7). 5) Lock according to any one of claims 1 to 4, characterized in that at least one ring (7) has at least two notches (41) over its entire thickness, giving it at least two possible positions in the organization of the trench. 6) Lock according to any one of claims 1 to 5, characterized in that the driver (13) of the bit (12) is provided with a pin (52) which extends along the central axis (40) barrel (1), the cylindrical rod (20) of the key (2) is then hollow to receive this pin. 7) A lock according to claim 6, characterized in that the length of the recess of the rod (20) of the key (2) is such that the bottom (53) of this recess abuts on the free end of the spindle (52) of the coach (13), which has the effect of causing the recoil of the coach to the clear of its housing and thus allow its docking on the bit (12) of the lock. 8) Lock according to any one of claims 1 to 7, characterized in that a lug (28) integral with the locking member (21) enters the key (2) from the beginning of the rotation of the latter , thus preventing the key from being removed during any locking / unlocking operation. 9) A lock according to any one of claims 3 to 8, characterized in that each lumen (30) is hollowed in a circular arc of the order of 120 °, the proximal ends of the two lights being separated from each other. a solid sector extending in a circular arc of the order of 60 °. 10) A lock according to claim 9, characterized in that the slots (30) are symmetrical two by two with respect to the vertical plane of symmetry (42) of the cylinder and in that the starting points of the two sinuous grooves (32) of the key are also symmetrical with respect to this plane of vertical symmetry. 11) Key for locking / unlocking the lock object of any one of claims 1 to 10, characterized in that its rod (20) is cylindrical and is provided with at least one sinuous groove (32) adapted to receive fingers (21) protruding into the path (16) provided for the passage of the key shaft between the inlet opening (9) and the outlet opening (11) of the lock.