FR2893063A1 - PUMP LOCK WITH PIN AND ASSOCIATED KEY. - Google Patents

Abstract

The pump lock comprises a tubular stator 1 receiving, in axial sliding and rotation, a rotor 2 provided with a head 17 having a key housing 3 of generally flat shape. The lock comprises a groove box 22 inside which are housed grooves 38 intended to cooperate with shapes 39 provided at the axial end of the key 40. The lock also comprises a pin 4 guided in translation in the rotor 2 along an axis transverse to the plane of the key housing. It comprises an elastic means 11 housed in the rotor and exerting a centripetal return force on the pin 4. Said pin has a first end 8 capable of protruding into the key housing 3, and a second end 9 adapted to penetrate into a stator strike 1.

Description

Pump lock with pin and associated key.

  The present invention relates to the field of security locks, and in particular the field of locks pump and grooved boxes and the keys associated with such locks. In this field, the patent application FR-2,760,774 (VAK PICARD) has described a key and a grooved lock, wherein grooves are pivotally mounted and wherein the actuation of the lock consists in particular to align these grooves. A flat key has at its end a set of alternating teeth and grooves arranged to come into contact and abut against the end of the respective grooves. The document describes a key containing a housing with an axially slidable element, to protect the key against fraudulent copies. Such a solution increases the cost of the key.

  Furthermore, it is important that the increase in the security of a lock is not done by degrading the size of the lock. In addition, it is desirable that a user, having several locks operated by the same key, can improve some of its locks without having to change all the locks corresponding. The key operating with an improved security lock must be able to operate the old locks. The invention proposes a lock of the pump and groove type and an associated key which have an additional safety means that is both cheap and does not generate an increase in the size of the lock. The associated key is compatible with locks not presenting the additional security means. According to one embodiment of the invention, the pump lock comprises a tubular stator receiving, in axial sliding and rotation, a rotor provided with a head having a key housing of substantially flat overall shape. The lock comprises a groove box inside which are housed grooves, intended to cooperate with shapes provided at the axial end of the key. The lock also comprises a pin guided in translation in the rotor along an axis transverse to the plane of the key housing. It comprises an elastic means housed in the rotor and exerting a centripetal return force on the pin. Said pin has a first end capable of protruding into the key housing, and a second end adapted to penetrate a stator strike. It is conceivable that such a lock, equipped with a pin in the rotor adapted to penetrate a striker of the stator, provides an additional lock. Moreover, the pin being able to protrude into the key housing, and being pushed by the resilient means in a centripetal direction, requires the presence of a key adapted to be actuated. The elastic means being located in the rotor, the contribution of the stator to this additional locking is limited to the presence of a striker. Thus the overall size of the lock is not affected. Advantageously, the groove box comprises a plurality of flat grooves movable around a shaft parallel to the plane of the key housing. Each of the grooves has, on one side, a notch and, on the other, a cam having an inclined profile to cooperate with one of the shapes of the key. Each of the grooves is able to rotate an unlocking angle. The notches of each of the grooves in the unlocked position are aligned and adapted to receive a tenon during an axial translation of the rotor. Advantageously, the axis of the pin is inclined relative to the normal to the plane of the key housing by an angle less than 50 degrees and preferably between 30 degrees and 40 degrees. The axis of the pin can be included in a plane perpendicular to the axis of the key housing. Advantageously, the pin has a rounded end. According to a variant, the lock comprises at least one groove whose cam is connected to the main part of said groove by a zone of weakness and has a profile of cooperation with the inverted key relative to the cooperation profile of the other grooves.

  According to another variant, the stator has at least one cooperating lug, on a translation travel of the rotor, with a conjugate shape of the head of the rotor, the lug having a substantially curved convex profile.

  According to another embodiment of the invention, the lock key of the type comprising a pump and a groove box, has a flat shank intended to penetrate into the lock along an axis of introduction of the key and a plurality of shapes. ends intended to cooperate in axial translation with the grooves. The key comprises on the flat part of the tail a recess placed so as not to cooperate with grooves of the lock. It is conceivable that such a key is provided to actuate a lock equipped with a device other than grooves, which gives the opportunity for additional locking. In addition the key can actuate a lock not having the additional lock. Advantageously, the recess is not through and has a concave shape. This helps to facilitate the extraction of the key. Advantageously, the recess has a connecting surface with at least a flat portion of the tail of the key, located on the side of the end of the key. Advantageously, the end shapes are teeth or grooves of substantially homogeneous width. The recess is located at an axial distance from the end shapes, twice the width of the end shapes. This reinforces the need to use a lock equipped with a device other than throats. According to a variant, the key comprises on a flat portion of the tail of the key, at least one female groove does not open at the end of the key. The distance between the flange of the female groove at the corresponding end of the key is less than twice the width of the groove. In this variant, the female groove can cooperate with a groove of a grooved lock. According to another variant, the key comprises at least one lateral support lug intended to penetrate into a radial notch of a stator of the lock.

  Other features and advantages of the invention will appear on reading the detailed description of some embodiments of the lock and the key taken as non-limiting examples and illustrated by the appended drawings, in which: FIG. 1 comprises a half-cut IA and a half-section IB of an embodiment of a lock according to the invention according to the transverse half-planes IA and IB of FIG. 2; FIG 2 is a section of an embodiment of the lock along the meridian plane II-II of Figure 1, and a section of the key at the beginning of introduction into the lock according to the section plane IIB of the Figure 3; - Figure 3 is a sectional view of the same embodiment of the lock according to the invention according to the sectional plane III-III of Figure 1 and a front view of the key according to the invention in extreme axial position; - Figure 4 is a partial section showing the position of the pin of the lock according to the same embodiment when the key is incompletely introduced into the lock; FIG 5 is a partial section of the lock according to the invention showing the position of the pin when the key is completely inserted into the lock; and FIG. 6 illustrates the cooperation between a key embodiment according to the invention and an inverted displacement groove. Figure 1 shows a lock in the state of rest in which no key is introduced. The lock comprises a stator 1 and a rotor 2 coaxial. The rotor 2 comprises at its center a key housing 3 and a pin 4 projecting into the key housing 3. The stator 1 comprises an orifice 5 facing the pin 4 and acting as a stator striker.

  The pin 4 has on one side a probing finger 8 terminated by a rounded end 8a and on the other a locking finger 9. The probing and locking fingers 8 are of coaxial cylindrical shape and are connected by a ring 10 extending radially. A spring 11 surrounds the locking finger 9 of the pin 4. The ring 10 is connected to the feeler finger 8 by a radial ring forming a stop 12a. The ring 10 is connected to the locking pin 6 by a radial ring acting as a stop 12b to the spring 11.

  The rotor 2 has two concentric bores 13 and 14. The bore 13 is adjusted to the outside diameter of the feeler finger 8 and serves as a guide pin 4. The bore 14 is larger in diameter than the outer diameter of the spring 11, allowing it to compress. The spring bore 14 is of greater diameter than the guide bore 13 and is connected to the bore 13 by a radial ring forming a stop 15a capable of receiving the stop 12a of the pin 4. The bore 14 opens at the outside of the rotor 2 by a narrowed shape 15b and an orifice 16. The assembly consisting of the pin 4 and the spring 11 is trapped inside the rotor 2.

  When the lock is at rest, the spring 11 is prestressed and the stop 12a bears on the abutment 15a of the rotor 2. In this position, the feeler finger 8 protrudes inside the key housing 3. The part the feeler finger 8 protruding inside the key housing 3 comprises the rounded end 8a and a cylindrical portion 8b. In this position, the locking finger 9 is slightly set back inside the rotor 2 with respect to the orifice 16. The axis of the pin 4 makes an angle of approximately 35 with respect to the normal plane of the housing key 3, the axis of the pin 4 being included in the transverse plane perpendicular to the common axis of the rotor 2 and the stator 1. In addition, the axis of the pin 4 is sequent with the axis of the rotor 2 The half-section IA illustrates in dotted line a head 17 of the rotor 2 guided in a bore 18 of the stator 1. The head 17 of the rotor 2 is guided in rotation and in translation in a head 25 of the stator 1, visible in FIGS. and 3. The key housing 3 is of substantially parallelepipedal shape, distributed symmetrically with respect to a meridian plane of the rotor 2 and comprising two small sides corresponding to the thickness of the key. Each of the two short sides of the key housing 3 has a female groove passing through the rotor 2 and the head 25 of the stator 1. For one of the sides, the female groove has a portion 6 in the rotor 2 and a portion 6a in the head 25 The cross section of the ribs 6 and 6a is identical and substantially square. For the other small side of the key housing 3, the female rib has a portion 7 in the rotor 2, of identical shape to the portion 6, and a portion 7a in the head 25, substantially twice as deep as wide. As illustrated in FIG. 1B, the stator 1 has a male parallelepiped pin 20 penetrating inside a corresponding groove 21 of the rotor 2. The parallelepipedal pin 20 has sides 20a facing with sides 21a of the groove 21 , preventing any relative movement of rotation between the rotor 2 and the stator 1 when the lock is in the axial position of rest. The stator 1 has a lug 19 of rounded shape projecting towards the inside of the stator 1. The rotor 2 has a complementary female shape. The lug 19 does not have a facing surface that also positively opposes the relative rotation of the rotor and the stator, such as the surfaces 20a and 31a of the parallelepipedal lug 20. This rounded shape of the lug 19 and the conjugate form in the rotor 2 has the effect of causing irreversible deformation of the rotor 2, in the case where the lock is forced. The deformation of the rotor 2 traps the key that was used to force the lock. The rotor 2 receives a grooved box 22 made of folded sheet steel in a substantially square cross-section around the axis of the rotor 2. A spring 23 surrounds the groove box 22 and is housed inside the stator 1. The grooved box 22 has two slots 22a in the extension of the grooves 6 and 7 of the rotor 2. As shown in Figures 2 and 3, the stator 1 comprises a tube 24 of inner diameter 24a. At the right end of Figures 2 and 3, the stator head 25 has a crown shape connected to the tube 24 and extending radially inside the tube 24. The two lugs 19 and 20 project inside. of the tube 24 and have an axial length 26. The stator 1 is provided at its end, to the left of Figures 2 and 3, a flange 27 in the form of a ring extending radially outside the tube 24.

  The rotor 2 comprises a rotor body 28 and the groove box 22. The rotor body 28 has a base 29 cut in FIG. 1 and the rotor head 17. The base 29 extends radially inside the tube 24 and has a surface 29a connecting the base 29 to the rotor head 17. This surface 29a is substantially perpendicular to the axis of the rotor 2. The stator head 25 has a bearing surface 25a substantially perpendicular to the axis of the stator 1 and connecting the inner diameter 24a to the bore 18. The groove box 22 is connected to the base 29 on a side opposite to the rotor head 17 and extends axially about the axis of the rotor 2. The lock also comprises a stop ring 30 bearing on the flange 27. The stop ring 30 is fixed on the flange 27 by means of a fixing means illustrated by center lines in FIG. 30 ring is provided with a skirt 31 fitted to the diameter 24a inside the tube 24. The skirt 31 has a the axial end 32 substantially perpendicular to the axis of the stator 1. A washer 33 has an outer diameter fitted to the diameter 24a and a central recess 34 adapted to the substantially square shape of the groove box 22. The spring 23 is supported, d one side on the washer 33 which rests on the end 32 of the washer 30, and the other on the base 29. The base 29 has an axial thickness greater than or substantially equal to the axial length 26 of the pins 19 and 20. A mechanism drive shaft 35 penetrates inside the skirt 31 of the stop ring 30 and is immobilized in translation relative to the stator 1 by means of not shown fastening means. The shaft 35 is intended in known manner to actuate a bolt, not shown, of the lock. The shaft 35 has a clearance surface 35a on the inner side of the stator 1 and substantially perpendicular to the axis of the stator 1. The shaft 35 is provided with a driving pin 36 projecting from the surface 35a towards the Inside the stator 1. The pin 36 has two drive faces 36a in two parallel and symmetrical planes of the common axis of the drive shaft 35, the stator 1 and the rotor 2.

  The groove box 22 comprises a pivot axis 37 extending perpendicular to the axis of the rotor 2 and located in the plane of the key housing 3. The pivot axis 37 is fixed at both ends in the groove box 22.

  A plurality of eight plates 38 are commonly referred to as grooves in the art. Each of the grooves 38 comprises a central orifice 38a intended to receive the pivot axis 37, a U-shaped slot 38b with an axis passing through the central orifice 38a and with a width greater than or substantially equal to the distance separating the surfaces from each other. 36a of the post 36. Each groove 38 also has a cam 38c located in a generally symmetrical zone of the notch 38b with respect to the central orifice 38a. The cam 38c has an inclined profile in the form of involute of a circle intended to cooperate with an end shape 39 of a key 40. Each groove 38 is also provided with a return spring 38d and a bearing surface 38th. The return spring 38d bears on one side of the groove box 22, so as to rotate the groove 38 until the bearing surface 38e is in contact with the opposite side of the groove box 22. This state of the lock corresponds to a rest position in which the key 40 is not introduced. In this position, the axis of the notch 38b is inclined relative to the axis of the stator 1, an unlocking angle 41 specific to each of the grooves 38. We will now describe the key 40 with the help of FIG. 3. The key 40 is of generally flat shape and has two lateral ribs 42, whose width is less than or substantially equal to the thickness of the sheet of the groove box 22. One of the lateral ribs 42 presents a lateral lug 43, of the same thickness as the lateral ribs 42 and of an upper height, so that the lateral lug 43 located in the plane of the key 40 protrudes outside the lateral ribs 42. The lug lateral 43 has a first axial bearing surface 43a located on the side of the end shapes 39 and a second bearing surface 43b located axially opposite the end shapes 39.

  The end shapes 39 corresponding to each of the grooves 38, comprise a plane inclined substantially 45 to the plane of the key 40, parallel to each other, and whose axial position corresponds to the unlocking angle 41 specific to Each of the grooves 38. The width of the end shapes 39 corresponds to the width of the plates of each of the grooves 38. The key 40 has on the flat part of the key a recess 44 intended to cooperate with the pin 4 of the lock. The recess 44 according to the illustrated embodiment, does not cross the thickness of the key 40 and has a concave shape 49. The center of the recess 44 is located at an axial distance from the end shapes 39 greater than two The key 40 also has a female groove 45 that does not open at the end of the key.

  With the aid of FIG. 3, the operation of the groove box 22 will now be described during the introduction of the key 40. When the key 40 is inserted into the key housing 3, the lateral ribs 42 penetrate in the grooves 6a and 7a of the stator, then in the small grooves 6 and 7 of the rotor, then in the slots 22a of the groove box 22. The lateral lug 43 of the key 40 enters the large groove 7a of the stator . In a second step of the introduction of the key 40, each of the end shapes 39 of the key 40 comes into contact in turn with the inclined profile of the cams 38c of each of the grooves 38.

  When each of the end shapes 39 has come into action, the key 40 continues its introduction until the first bearing surface 43a of the lug 43 comes into contact with the support surface 29a of the base 29. At the end of this step, each of the grooves has been pivoted by an angle equal to the unlocking angle 41 which is specific to it, so that, in this unlocking position, each of the grooves is aligned forming, strictly speaking, a single groove disposed in the plane of the key housing 3.

  D In a third step of the introduction of the key 40, the key 40 drives in translation the assembly of the rotor 2 by guiding the lateral ribs 42 in the slots 22a of the groove box 22 and thanks to the surface of support 43a of the lug 43. The single groove in the unlocked position is cap the drive lug 36 until the rotor 2 is in an axial unlocking position. The axial position of unlocking corresponds to the fact that the second bearing surface 43b has left the large groove 7a of the stator 1.

  The lateral ribs 42 and the lateral pin 43 are no longer guided by the grooves 6a and 7a of the stator and the base 29 of the rotor 2 is no longer guided by the lugs 19 and 20 of the stator 1. The axial translation stroke of the rotor 2 is at least equal to the axial distance between the first and second bearing surfaces of the lug 43. The distance between the first and the second bearing surfaces of the lug 43 is greater than or substantially equal to the axial length 26 of the pins 19 and 20. The extreme axial position corresponds either to the support of the groove box 22 on the release surface 35a of the shaft 35, or in support of the pin 36 on the bottom of the notches 38b. The axial length of the rotor head 17 and of the stator head 25 is greater than the maximum translation travel of the rotor 2. Thus, even in the extreme axial translation position, the rotor head 17 remains guided in the bore 18 of the stator 1. In a fourth step, the key 40 is pivoted about the axis of the stator 1 and rotates the rotor 2, as well as the drive shaft of the mechanisms 35. We will now describe, at the FIGS. 4 and 5 illustrate the operation of the pin 4. When the introduction of the key 40 into the key housing 3 begins, the end shapes 39 of the key 40 are located in the extension of the recess 44 come into contact with the rounded end 8a of the pin 4. Thanks to the profiled shapes 39 and 8a, the feeler finger 8 is pushed back inside the guide bore 13 and the spring 11 maintains contact between the rounded end 8a and a portion 46 of the surface In this configuration illustrated in FIG. 4, the end of the locking pin 9 penetrates inside the orifice 5 formed in the tube 24. The orifice 5 is located opposite the orifice 16 of the rotor 2 when the latter is in the rest position, that is to say when the bearing surface 29a of the base 29 is in contact with the bearing surface 25a of the stator 1. A key 40 , which would not be provided with a recess 44, could not operate the lock since no axial translation or rotation of the rotor 2 is possible. On the other hand, if a key 40 is provided with a recess 44 arriving in coincidence with the pin 4 when the first bearing surface 43a of the lug 43 comes into contact with the bearing surface 29a of the base 29, the feeler finger 8 enters the recess 44 through the action of the spring 11. If the recess 44 is of sufficient depth, the locking finger 9 withdraws sufficiently from the keeper 5 so that the continuation of the locking sequence continues as previously described. The pin 4 is an additional safety mechanism associated with an encoding mechanism of the lock consisting of the grooves 38 and the corresponding end shapes 39 of the key 40. The pin 4 does not really contribute to an additional coding, since any recess form having a sufficient depth is suitable, so that the cost of this additional security is very small. On the other hand, if a key 40 was copied by drilling a hole opening for example at the location provided for the recess 44, and the opening hole has smooth walls substantially perpendicular to the plane of the key 40, the finger probe 8 would penetrate inside such a perpendicular hole until the stop 12a of the pin bears on the rotor 2. The cylindrical portion 8b of the pin 4 prevent any removal of the key 40 which would remain trapped in the lock, and this despite the presence of the rounded end 8a of the finger probe. In a variant of the invention, the key 40 is provided with a recess 44 having a connecting surface 48 inclined relative to the plane of the key 40, and connecting the recess 44 to the portion 46 of the flat surface of the key 40 located between the recess 44 and the end of the key 40. We will now describe with the help of Figure 6, the operation of the groove 45 of the key 40. A groove 50, in the alignment of the groove 45 of the key, has a cam 51 connected to the main part of the groove 50 by a zone of weakness 52. The cam 51 has a first inclined profile 51a parallel to the inclined profile 38c of the other grooves and a second inclined profile 51b in a direction reversed from the first profile 51a, and located between the first profile 51a and the central orifice 38a of said groove. The key 40 has in the extension of the groove 50, a first inclined shape 53a located at the end of the key 40. The groove 45 does not open at the end of the key 40, has a second inclined shape 53b. When the key 40 is inserted in the key housing 3, the first inclined shape 53a of the key cooperates with the first profile 51a of the groove 50, and this latter pivots at an angle greater than the locking angle 41. wish. When further introduction of the key 40, the part of the key 40 located between the first and second inclined shapes 53a and 53b comes opposite the zone of weakness 52 of the groove 50 and the cam 51 enters the groove 45. The introduction of the key 40 in the lock results in two phases of pivoting of the groove 50. The first pivoting phase takes place in the same direction as the pivoting of the other grooves 38, but exceeds the angle of Unlocking 41. The second pivoting phase takes place in the opposite direction to bring the notch of the groove 50 in alignment with the other notches 38b of the other grooves 38, in a position 54 illustrated in a combined line in FIG. 50 operates a shearing movement with respect to the final shape of single groove obtained. Such a groove 50 has a first advantage of preventing the groove box from being actuated with a key 40 without lateral rib 42. This groove 50 also has a second advantage thanks to the zone of weakness 52. If the lock is forced by a key 40 not appropriate, the zone of frailty 52 is deformed and the lock becomes out of use.

  The recess 44 can take any female form and in particular a groove shape. However, a characteristic makes it possible to distinguish a recess 44 intended to cooperate with a pin 4 of a groove 45 intended to cooperate with a shear groove 50. The recess 44 is placed so as not to cooperate with the grooves of the lock. that is, it is located far enough that a groove functioning in a manner similar to the groove 50 is much too fragile. This condition is especially achieved when the recess 44 is located at an axial distance from the end shapes 39 twice the width of the end shapes 39. The axis of the pin 4 is transverse to the plane of the housing key 3, in that it is not parallel to the key housing 3 and that the axis of the pin 4 makes an acute angle with respect to the normal to the key housing plane 3. The ideal would be to have a pin 4 directly perpendicular to the plane of the key housing 3. However, this direction also corresponds to the ideal location for the pins 19 and 20. In a variant of the invention, the axis of the pin 4 is inclined relative to the normal to the plane of the key 40.

  According to another variant, the axis of the pin 4 may not be sequent with the axis of the rotor 2 and be offset angularly with respect to a plane perpendicular to the axis of the rotor 2, or be shifted laterally. In a particular embodiment, the pin is in a plane perpendicular to the axis of the key housing 3. In a variant, the angle that the pin 4 with the normal to the key housing 3, is less than 50 and preferably between 30 and 40. The invention relates in particular to a key intended to cooperate with a lock having a grooved mechanism and optionally having another mechanism, even if this other mechanism does not have the characteristics of the lock of the invention. Indeed, a key of the invention, with the end shapes 39 and the recess 44 can be used in a lock without pin system. The fact that the key is capable of actuating a lock provided with a mechanism other than the grooves is sufficient. Such a key can be used for example with a grooved lock equipped with a piston system where the spring would be in the stator, or equipped with a pin actuated by a magnetic return mechanism.

Claims (14)

  1-pump lock, comprising a tubular stator (1) receiving, in axial sliding and rotation, a rotor (2) provided with a head (17) having a key housing (3) of generally flat shape, and a grooved box (22) inside which grooves (38, 50) are housed, intended to cooperate with shapes (39, 53a) provided at the axial end of the key (40), characterized by the it comprises a pin (4) guided in translation in the rotor (2) along an axis transverse to the plane of the key housing (3), it comprises an elastic means (11) housed in the rotor ( 2) and exerting a centripetal return force on the pin (4), and said pin (4) has a first end (8) capable of protruding into the key housing (3), and a second end (9) adapted to penetrate a striker (5) of the stator (1).   A lock according to claim 1, wherein the groove box (22) comprises a plurality of flat grooves (22, 50) movable about a shaft (37) parallel to the key housing plane, each groove (38) ) having, on one side, a notch (38b) and, on the other, a cam (38c) having an inclined profile to cooperate with one of the shapes (39) of the key (40), each of the grooves (38) ) being able to pivot by an unlocking angle (41), the notches (38b) of each of the grooves (38) in the unlocking position being aligned and able to receive a tenon (36) during an axial translation of the rotor (2).   3-lock according to claim 1 or 2, wherein the axis of the pin (4) is inclined relative to the normal plane of the key housing (3) of an angle less than 50 degrees and preferably between 30 degrees and 40 degrees.   4-lock according to claim 3, wherein the axis of the pin (4) is in a plane perpendicular to the axis of the key housing (3).   5-lock according to any one of claims 1 to 4, wherein the pin (4) has a end (8a) of rounded shape.   6-Lock according to any one of the preceding claims, comprising at least one groove (50) whose cam (51) is connected to the main part of said groove (50) by a zone of weakness (52) and has a profile (51b) cooperating with the key (40), inverted with respect to the cooperation profile (38c) of the other grooves (38).   7-lock according to any one of the preceding claims, wherein the stator (1) has at least one lug (19) cooperating, on a translation travel of the rotor (2), with a conjugate form of the rotor head ( 28), the lug (19) having a substantially curved convex profile.   8-Lock key of the type comprising a pump and a groove box, the key (40) having a flat shank intended to penetrate into the lock along an insertion axis of the key (40) and a plurality of shapes (39). , 53a, 53b) of ends intended to cooperate in axial translation with the grooves (38, 50), characterized in that it comprises on the flat part of the tail a recess (44) placed so as not to cooperate with grooves (38, 50) of the lock.   9-key according to claim 8, wherein the recess (44) is not through and has a concave shape (49).   The key according to claim 8 or 9, wherein the recess (44) has a connecting surface with at least one flat portion (46) of the key shank (40) located on the end side of the key. the key (40).   The key according to any of claims 8 to 10, wherein the end shapes (39) are teeth or grooves of substantially homogeneous width, the recess (44) being located at an axial distance from the forms ends, twice as large as the width of the end shapes (39).   12-key according to any one of claims 8 to 11, comprising on a flat portion of the tail of the key, at least one female groove (45) does not open at the end of the key (40).   The key of claim 12, wherein the distance between the flange (53b) of the female groove (45) at the corresponding end of the key (40) is less than twice the width of the groove (45).   14-key according to any one of claims 8 to 13, comprising at least one lateral lug (43) support for penetrating into a radial notch (7a) of a stator (1) of the lock.