FR2755173A1 - Automatically coded vehicle lock - Google Patents

Abstract

The lock has a rotor (12), which can be fixed in a barrel (10) and is prevented from rotating around its longitudinal axis (A1) by at least one bit (14), which is slidably mounted in a direction transverse to the rotor. The bit has a locking plate (28), which is at least partially received in a recess (18) of the barrel, and a coding plate (30), which co-operates with a shaft of a key. The coding plate has an integral claw (40), which is fixed transverse to the sliding direction of the bit. When the plates are fitted in the rotor and the bit is not assembled, the claw is movable perpendicularly to the slide movement and against the locking plate. When the bit is finally assembled, the claw is movable towards a locking position, in which it co-operates with the locking plate to slide in the direction of the bit.

Description

 The invention relates to a self-coding lock comprising transversely movable flakes.

 The invention relates more particularly to a rotary barrel lock, of the type comprising a rotor capable of being immobilized in rotation about its longitudinal axis in a socket by at least one flake mounted slidingly in a transverse direction in the rotor, of the type in which the glitter comprises a locking member, intended to be received at least partially in a recess of the socket, and a coding member which cooperates with a key, of the type in which the coding and locking members are put in place the lock before assembling the flakes and are locked with respect to each other, in the sliding direction of the flake, in a particular coding position during the assembly of the flake.

 Self-coding locks make it possible to dispense with the need to produce specific flakes, each characterized by the position of an internal light relative to the flake. On the other hand, the existence of different flakes requires, when mounting the lock, to anticipate in advance what will be the coding of the key associated with the lock so as to mount in the lock the appropriate flakes in a well-determined order.

 It follows that, very early in the manufacture of the lock, it is individualized and it is a question of following throughout the manufacture the specific identity of this lock in order to associate it at the end of manufacture with a compliant key. When this lock is intended to be used on a motor vehicle, this problem persists throughout the manufacture of the vehicle after the lock has been mounted thereon.

 Furthermore, the self-coding locks known up to now only made it possible to carry out the coding operation once.

 Thus, when one of the vehicle keys is lost by its owner, he has the choice either to redo a key using the same coding, or to replace the lock, or even all the vehicle locks when those - these are identical. Indeed, this measure may be deemed necessary in the event that the keys were stolen in order to steal the vehicle subsequently.

It was described in the German patent application
No. 19544840.5 a self-coding lock comprising two-part flakes provided with a coding member and a locking member, movable relative to each other in the transverse direction of sliding of the flake, and intended to be assembled relative to each other by axial displacement of the coding member relative to the locking member, after the introduction of the conforming key carrying out the coding.

 However, such a type of lock has the drawback that, when the key is introduced into the rotor of the lock to code it, the direction of the insertion force coincides with the direction of the force that it is necessary to apply to the coding members to cause the final assembly of the glitter.

 Thus, it happens that, during the introduction of the key, a coding member is pushed by this key rod in the axial direction before the key is fully engaged in the rotor.

 This generally results in poor coding of the lock which prevents it from being opened with the key which should nevertheless be in conformity.

 In such a case, it is then particularly difficult, if not impossible, to re-code the lock and it turns out to be unusable.

 The object of the invention is therefore to propose an autocoding lock whose operation is particularly reliable both during the coding operation and during normal use of the lock.

 Furthermore, it is necessary that such a lock comprises a minimum of moving parts at the same time in order to reduce the cost and increase reliability.

 For this purpose, the invention proposes a lock of the type described above, characterized in that a first of the two members carries a claw which is integral with this member in the transverse direction of sliding of the straw, in that, when the organs are arranged in the rotor without the straw being assembled, the claw is movable in translation relative to the second member in the transverse direction perpendicular to the sliding direction, and in that for the final assembly of the chaff, the claw is moved to an assembly position in which it cooperates with the second member to link the two members in translation in the sliding direction of the straw.

According to other features of the invention
- the claw is moved to its glitter assembly position by cooperation with a cam track relative to which it is moved for the final assembly of the glitter
the locking and coding members consist of two plate elements which are slidably mounted in a transverse plane in a housing of the rotor and which are joined in the axial direction, the members each include a lumen through which s extends the key rod when it is inserted into the rotor, the lumen of the coding member cooperates by at least one of its edges with the key rod, and the key rod is not capable of cooperating with the lock member light
the claw is carried by the coding member, it extends over an edge of the member which is parallel to the sliding direction, in a plane offset axially with respect to the plane of the coding member, and it is intended to cooperate with a corresponding edge of the locking member to ensure the assembly of the straw
- According to the direction of movement of the claw towards its position for assembling the glitter, the lumen of the coding member is of width greater than the width of the key rod
the rotor is capable of being pivoted about its axis with respect to the bushing between two angular positions of coding and of service, and the cam path which urges the claw towards its assembly position is formed on an internal surface of the socket
- before assembly of the straw, when the coding and locking members are arranged in their housing in the rotor, the claw has a control surface which protrudes radially outside the rotor, when the rotor is in its position coding in the lock, the claw control surface extends inside the recess of the socket intended to receive the straw, and when the rotor is brought to its operating position, the control surface the claw cooperates with the cam track to move the claw to its position for assembling the straw
- Means are provided to prevent the return of the rotor from its service position to its coding position
- the rotor is capable of pivoting an angular service stroke around its service position to which it is returned by an angular action spring, and the spring prevents the rotor from returning to its service position
- the angular action spring is a cylindrical spring received axially inside a cylindrical wall of the rotor and comprising two end strands which extend radially outwards through a window of the rotor and through a window of the sleeve, the two strands of the spring are angularly supported each against a longitudinal edge of the window of the sleeve, the window of the rotor has two extreme longitudinal edges and an intermediate longitudinal edge, in the service position of the rotor , the two strands of the spring cooperate respectively, a first with a first extreme longitudinal edge and the second with the intermediate longitudinal edge of the rotor, the second extreme longitudinal edge is spaced from the intermediate edge by an angle at least substantially equal to the deviation angular between the mounting and service positions of the rotor;
- The second strand of the spring is pressed axially against a substantially transverse edge of the rotor window which comprises, between the two extreme longitudinal edges a longitudinal recess forming the intermediate longitudinal edge of the rotor window, the substantially transverse edge comprises a ramp against which rests axially on the second strand when the rotor is brought from its coding position to its operating position, and when the rotor reaches its operating position, the second strand comes into angular abutment against the intermediate edge
- It is possible to release the second strand of the angular spring out of the recess forming the intermediate edge to force the rotor back to its coding position.

Other characteristics and advantages of the invention will appear on reading the following detailed description for the understanding of which reference will be made to the accompanying drawings in which
- Figure 1 is a partial exploded perspective view illustrating the stator, the rotor and a flake of a lock according to the teachings of the invention;
- Figure 2 is a perspective view with cutaway of the elements of Figure 1 which are shown assembled
- Figure 3 is a longitudinal sectional view of the lock rotor according to the invention as well as a return spring and its retaining washer
- Figure 4 is a top view of the rotor of Figure 3.

Figures 5 to 12 illustrate more particularly the coding of the lock according to the invention and in particular
- Figures 5 and 6 are sectional views, respectively transverse and longitudinal, of the lock after its assembly but before its coding
- Figures 7 and 8 are views similar to those of Figures 5 and 6 in which the coding key is inserted into the rotor
- Figures 9 and 10 are views similar to Figures 5 and 6 in which the rotor has been rotated in rotation about its axis towards its service position to carry out the assembly of the flakes
- Figures 11 and 12 are views similar to those of Figures 5 and 6 in which the lock is shown after its coding in its locked state
- Figure 13 is a schematic cross-sectional view illustrating the mounting of the rotor in the stator when the rotor is in the coding position
- Figure 14 is a top view of Figure 13 in which the stator is partially broken away
- Figures 15 and 16 are views similar to Figures 13 and 14 in which the rotor is in the service position relative to the stator.

 FIG. 1 shows a stator 10 of a motor vehicle lock which is produced in the form of a substantially cylindrical and tubular socket of axis Al and which is intended to receive in rotation a substantially cylindrical rotor 12 in which flakes 14 are slidably mounted in a transverse direction, each flake 14 being received inside a housing 16 in the rotor 12.

 In a known manner, the flakes 14 are movable between two positions: a retracted position in which they are entirely received inside the corresponding housing 16 of the rotor 12, and a projecting position in which a transverse end of the flake 14 is received in a recess 18 formed in an internal cylindrical surface 20 of the stator 10 for immobilizing in rotation the rotor 12 in the stator 10, the lock then being in its locked state.

 In the embodiment shown in the figures, the stator 10 has two recesses 18 which are diametrically opposite, which extend longitudinally so as to open out at the rear end of the stator 10 by which the rotor 12 is introduced into the stator 10.

 As can be seen more particularly in FIG. 2, each straw 14 is urged by a compression spring 22 towards its projecting position so that in the absence of a key in the lock, the latter is locked.

 In known manner, the rotor 12 has an axial key passage 24 which allows the introduction into the latter of a key rod 26 more particularly shown in FIGS. 7 to 10.

 The key rod 26 is intended to urge the flakes 14 towards their retracted position, against their return spring 22 to unlock the lock.

 In accordance with the teachings of the invention, the flakes 14 of the lock are produced in the form of two plate elements arranged in a transverse plane and which are intended to be joined to one another, face to face. Thus, each straw 14 comprises a locking member 28 and a coding member 30 which are each provided with a light 32, 34 intended to allow the passage of the key rod 26 in the axial direction.

 The ends of the two members 28 and 30 of the flakes 14 are curved in an arc of a circle of substantially the same radius of curvature as the internal cylindrical surface 20.

 More particularly, the locking member 28 of the straw 14 has an upper end 36 which is intended to be received in the recess 18 of the stator 10 when the straw 14 is in its projecting position, and the lumen 34 of the member. coding 30 has a lower transverse edge 38 which is intended to cooperate with the key rod 26 when the latter is inserted inside the rotor 12 so as to bring the straw 14 to its retracted position.

 The terms "lower" and "upper" are used here as a function of the direction of sliding of the straw 14, the latter being considered as being urged vertically upwards by its compression spring 22.

 According to the principle of the self-coding lock, the members 28, 30 of the flakes 14 are intended to be assembled only after the mounting of the lock, after having been positioned relative to each other using a conforming key.

 As can be seen in the figures, the coding member 30 also comprises a claw 40 which extends in a transverse plane offset axially with respect to the transverse plane of the coding member 30, which extends along a vertical edge 42 of the coding member 30 and which is intended to cooperate with a corresponding vertical edge 44 of the locking member 28 to make the two members 28, 30 of the straw 14 integral in translation in the direction sliding the straw 14.

 FIGS. 3 and 4 show more precisely the rotor 12 of the lock according to the invention. We therefore see in these figures that the housings 16 of the rotor in which the flakes 14 are received open transversely on both sides in the vertical direction of sliding of the flakes 14. As can be seen more particularly in Figures 2 and 4, the housings 16 have at their lower end two substantially parallel lateral surfaces 46 which allow the locking member 28 of the straw 14 to be guided in sliding in the vertical direction. On the contrary, the vertical lateral edge 42 of the coding member 30, which carries the claw 40, and this same claw 40 are received in a transverse clearance 48 which extends in a horizontal direction perpendicular to the vertical direction of sliding of the straw 14 and which opens into an external cylindrical surface of the rotor.

 This clearance 48 is substantially L-shaped when viewed in section along a substantially horizontal longitudinal plane so that its thickness in the axial direction decreases towards the outside of the rotor 12. The clearance 48 is delimited by a lower face 50 substantially horizontal in which is arranged a cylindrical receptacle 52 intended to receive and guide the lower end of the compression spring 22 for returning the straw 14 to its projecting position.

 FIGS. 5 to 12 show the different stages of mounting the lock according to the invention which make it possible to code it.

 When mounting the lock, the locking members 28 and coding 30 of the flakes 14 are mounted in the corresponding housings 16 of the rotor 12, after the introduction of the compression springs 22 for returning the flakes 14 and the assembly thus formed is introduced axially into the stator 10 which is oriented so that the rotor 12 and the stator 10 are in a relative coding position offset by 90 "relative to their relative service position (shown in FIGS. 9 to 12) when the lock is in its locked state.

 Thus, when the rotor is in the coding position, the housings 16 do not open opposite the recesses 18 of the stator 10.

As can be seen in FIGS. 5 and 6, the locking member 28 of the straw 14 is dimensioned so as to be exactly received in the internal cylindrical surface 20 of the stator 10 in the direction of sliding of the straws. On the contrary ,
The coding member 30 is of substantially smaller dimension in this direction so that, when the rotor 12 is mounted in the coding position in the stator 10, The coding member 30 is capable of moving in the vertical sliding direction glitter relative to the stator 10, inside its housing 16 in the rotor 12.

 However, as can be seen in FIGS. 5 and 6, the locking member 30 is then biased by the compression spring 22 bearing vertically upwards against the internal cylindrical surface 20 of the stator 10.

As we can see more particularly in Figure 5,
The coding member 30 is capable of moving transversely in a direction perpendicular to the direction of sliding of the straw 14 in the housing 16 of the rotor, while the locking member 28 is perfectly guided in this direction.

 In this way, it can be seen that the transverse width of the lumen 32 of the locking member 28 in the direction perpendicular to the sliding direction is substantially equivalent to that of the key passage 24 of the rotor 12 and therefore substantially the same as that of the key rod 26. On the contrary, the lumen 34 of the coding member 30 is of greater transverse width to allow this coding member 30 to be moved perpendicular to its sliding direction even after the introduction of the key rod 26 in the rotor 12.

 During the mounting of the rotor 12, provided with the flakes 14, in the rotor 10, the coding member is biased in the direction perpendicular to the sliding direction so that an external lateral edge 54 of the claw 40 protrudes towards outside the rotor 12 through the clearance 48.

 This outer edge 54 is then received in the recess 18 of the stator, which is made possible by the relative angular orientation of the rotor 12 relative to the stator 10 in the coding position.

 This preferred position of the locking member 30, wedged to the right by looking at FIG. 5, is obtained by virtue of the compression spring 22. In fact, the latter is retained in the receptacle 52 of the clearance 48 by its lower end, and its upper end is engaged around a lower pin 56 formed on the claw 40 so that, when the spring 22 is in the axis of the cylindrical receptacle 52, which is its natural position in the free state, the locking member 30 is locked to the right by considering FIG. 5.

 As can be seen in Figures 7 and 8, the key rod 26 is then capable of being inserted axially into the key passage 24 of the rotor 12 and it is intended to cooperate with the lower transverse edge 38 of the light 34 of the coding member 30 to urge it downwards, against its return spring 22. When the key 26 is fully inserted into the orifice 24, the coding member 30 is then arranged in a particular position relative to the locking member 28, a particular position which is determined by the profile of the key rod 26 and which corresponds to a coding of the straw 14 considered. Indeed, during this time, the locking member 28 is not moved by the key rod 26, which is due in particular to the fact that the light 32 is of dimension greater than that of the key passage 24 in the direction sliding the straw 14.

 Depending on the profile of the key rod 26, each flake 14 of the rotor 12 is thus coded differently.

 To cause the assembly of the straw 14, that is to say to obtain a relative blocking of the two locking members 28 and coding 30 of this straw 14 in the sliding direction thereof, it suffices to rotate the rotor 12 a quarter turn relative to the stator 10 to bring it to its service position which is shown in FIGS. 9 to 12.

 For the convenience of reading and interpreting the drawings, in FIGS. 9 to 12, it is the stator 10 which has been pivoted 90 "relative to the rotor 12.

 When the rotor 12 and the stator 10 are in the relative service position around their axis A1 so that the recesses 18 of the stator 10 are facing the open ends of the housings 16 of the rotor 12 in which the flakes 14 are mounted.

 Passing from its coding position to its operating position relative to the stator 10, the rotor 12 carries with it the flakes 14 so that the outer edge 54 of the claw 40 of the locking member 28 is pushed towards the inside the rotor 12 by the internal cylindrical surface 20. This cam effect results in the displacement of the coding member 30 in the direction perpendicular to the sliding direction of the straw 14 towards an assembly position. In its assembly position, the claw 40, which is carried by the coding member 30 is engaged so as to cooperate with a striated portion 58 of the vertical edge 44 of the locking member 28 so as to carry out the assembly of the straw 14 by blocking any relative movement of the two members 28 and 30.

 Thus, when the rotor 12 is in the service position and the user withdraws the key, the assembly of the two members 28 and 30 forming the assembled straw 14 is biased towards the projecting position by the spring 22 which, in FIGS. 9 and 11, is then slightly bent towards the inside of the rotor 12.

 If the recesses 18 are in good agreement with the through ends of the housings 16 of the rotor 12, the straw 14 thus assembled is therefore capable of being received inside the recess 18 of the stator 10, thus preventing any relative rotation of the rotor 12 relative to stator 10.

 As can be seen in particular in FIGS. 9 and 11, the internal cylindrical surface 20 of the stator 10 is provided with a notch 60 which, when the rotor 12 is in the service position, allows the external edge 54 of the claw 40 to do not prevent the free sliding of the straw 14 between its retracted and projecting positions.

 Advantageously, the lock coding system according to the invention makes it possible to easily carry out a new coding of the lock.

 Indeed, it suffices to return the stator 12 to its coding position relative to the stator 10, that is to say its position in which the clearance 48 of the housings 16 of the flakes 14 opens facing the recesses 18 of the stator 10 .

 Then, under the effect of the spring 22 which tends to return to its unreflected free position, the claw 40 tends to disengage from the vertical edge 44 of the locking member 28 so as to make their possibility of movement relative to the two members 28 and 30.

 We then find ourselves in the configuration shown in Figure 1 and it is possible to re-code the lock using a new key.

 However, this possibility of re-coding must be prohibited when the lock is mounted on the vehicle. However, the rotor 12 must be able to be pivoted around the stator 10, at least by a certain angle, to control the lock mechanism. It is therefore necessary to provide a mechanism making it possible to limit the angular movement of the rotor 12 around its service position and the limiting mechanism must be disengageable to allow possible new coding of the lock.

 FIG. 3 shows an angular return spring 62 of the rotor 12 to its nominal operating position in which the housings 16 of the rotor 12 open facing the recesses 18 of the stator 10.

 This spring 62 is in the form of a helical spring with angular action and it is intended to be introduced axially into an annular groove 64 which opens axially forwards at a front axial end 65 of the rotor 12. The spring 62 comprises two radial end strands 82, 84 which extend radially outwards and which are intended to cooperate on the one hand with abutment surfaces of the rotor 12 and on the other hand with abutment surfaces of the stator 10.

 The annular groove 64 of the rotor 12 is therefore delimited towards the outside by a cylindrical wall 66 which comprises a window 68 which opens axially towards the front and which is delimited angularly around the axis A1 by two extreme longitudinal edges 70, 72 .

 As can be seen in FIGS. 13 and 15, the stator 10 also includes a window 74 delimited by two longitudinal edges 76, 78 which are angularly spaced 40 around the axis Al.

 When the rotor 12 is mounted in the stator 10, their respective windows 68, 74 are arranged substantially axially in the same plane. In this way, the end strands 82, 84 of the angular action spring 62 are capable of extending radially outwards through the two windows 68, 74 and therefore come to bear against the edges of the window 74 stator 10.

 As can be seen in FIGS. 13 and 15, the extreme edges 70, 72 of the window 68 of the rotor 12 are angularly spaced apart from one another by about 1300.

 Furthermore, as can be seen more particularly in FIGS. 4, 14 and 16, the window 68 of the rotor 12 is delimited axially towards the rear by a rear transverse orientation edge 81A, 81B which has a longitudinal recess forming an intermediate edge 80 which is angularly offset by about 40 relative to a first 70 of the two extreme edges of the window 68 and which is turned opposite this first edge 70.

 As can be seen in FIGS. 14 and 16, in which the stator 10 is partially torn off, the spring 62 is pressed axially towards the rear at the bottom of the annular groove 64 by a support washer 86 which is intended to be fixed to the front axial end 65 of the rotor 12. Thus, one of the strands, called second strand 84, of the spring 62 is substantially pressed against the rear transverse edge 81A, 81B of the window 68 of the rotor 12. This second strand 84 is intended to be pressed against a second 72 of the extreme edges of the window of the rotor 12 when the latter is in the coding position as can be seen in FIGS. 13 and 14.

 When the rotor 12 is pivoted from its coding position to its operating position, this second strand 84 is caused to move along the rear transverse edge which is divided into two portions 81A, 81B by the longitudinal offset 80. The portion 81A in the form of a ramp causes the strand 84 of the spring 62 to move axially forwards when the rotor 12 pivots, which tends to compress the spring 62 axially.

 Also, when the rotor 12 has pivoted about 90, the strand 84 of the spring 62 is found facing the recess 80 and is capable of falling behind, pressing against the second part 81B of the rear transverse edge 81.

 However, the recess 80 forming an intermediate edge and the first end edge 70 of the window 68 being spaced substantially at the same angle as the two edges 76, 78 of the window 74 of the stator 10, the two strands 82, 84 of the spring 62 are then substantially supported both against the edges of the stator window and against two edges of the rotor window.

 Thus, when the rotor 12 is pivoted relative to the stator 12, the windows 68, 74 are moved relative to each other and they cause the angular bringing together of the two strands 82, 84 of the spring 62. However, the displacement relative is thus limited to 40 angle in each direction of the fact that the fenêt the case where an intermediate socket is interposed between the two to form a disengageable lock.

Claims (12)

 1. Rotary barrel lock, of the type comprising a rotor (12) capable of being immobilized in rotation about its longitudinal axis (Al) in a socket (10) by at least one flake (14) mounted to slide in a transverse direction in the rotor (12), of the type in which the straw (14) comprises a locking member (28), intended to be received at least partially in a recess (18) of the sleeve (10), and a coding member (30) which cooperates with a key rod (26), of the type in which the coding (28) and locking (30) members are put in place in the lock before the glitter (14) is assembled and are blocked one with respect to the other, in the sliding direction of the straw (14), in a particular coding position during the assembly of the straw (14),  characterized in that a first of the two members (28, 30) carries a claw (40) which is integral with this member (30) in the transverse direction of sliding of the straw (14), in that, when the members (28, 30) are arranged in the rotor (12) without the straw (14) being assembled, the claw (40) is movable in translation relative to the second member (28) in the transverse direction perpendicular to the sliding direction , and in that for the final assembly of the straw (14), the claw (40) is moved to an assembly position in which it cooperates with the second member (28) to link the two members in translation according to the sliding direction of the straw (14).  2. Lock according to claim 1, characterized in that the claw (40) is moved towards its position for assembling the straw (14) by cooperation with a cam path (20) relative to which it is moved for the final assembly of the straw (14).  3. Lock according to claim 2, characterized in that the locking members (28) and coding (30) consist of two plate elements which are slidably mounted in a transverse plane in a housing (16) of the rotor ( 12) and which are joined in the axial direction, in that the members (28, 30) each include a lumen (32, 34) through which extends the key rod (36) when it is inserted into the rotor (12), in that the lumen (34) of the coding member (30) cooperates by at least one of its edges (38) with the key rod (26), and in that the rod key (26) is not capable of cooperating with the light (32) of the locking member (28).  4. Lock according to claim 3, characterized in that the claw (40) is carried by the coding member (30), in that it extends over an edge of the member (42) which is parallel in the sliding direction, in a plane offset axially with respect to the plane of the coding member (30), and in that it is intended to cooperate with a corresponding edge (44) of the locking member (28 ) to assemble the straw (14).  5. Lock according to claim 4, characterized in that, in the direction of movement of the claw (40) towards its position for assembling the straw (14), the lumen (34) of the coding member (30 ) is wider than the width of the key rod (26).  6. Lock according to any one of claims 2 to 5, characterized in that the rotor (12) is capable of being pivoted about its axis (Al) relative to the sleeve (10) between two angular coding positions and of service, and in that the cam path which urges the claw (40) towards its assembly position is formed on an internal surface (20) of the sleeve (10).  7. Lock according to claim 6 taken in combination with one of claims 4 or 5, characterized in that, before the assembly of the straw (14), when the coding (30) and locking (28) members are arranged in their housing (16) in the rotor (12), the claw (40) has a control surface (54) which protrudes radially outside the rotor (12), in that when the rotor (12) is in its coding position in the lock, the control surface (54) of the claw (40) extends inside the recess (18) of the socket (10) intended to receive the straw (14 ), and in that when the rotor (12) is brought to its operating position, the control surface (54) of the claw (40) cooperates with the cam track (20) to move the claw to its position d 'assembly of the straw (14).  8. Lock according to claim 7, characterized in that means are provided to prevent the return of the rotor (12) from its operating position to its coding position.  9. Lock according to claim 8, characterized in that the rotor (12) is capable of pivoting an angular service stroke around its service position towards which it is returned by an angular action spring (62), and in that the spring (62) prevents the rotor (12) from returning to its operating position.  10 Lock according to claim 9, characterized in that the angular action spring (62) is a cylindrical spring received axially inside a cylindrical wall (65) of the rotor (12) and comprising two end strands ( 82, 84) which extend radially outward through a window (68) of the rotor (12) and through a window (74) of the sleeve (10), in that the two strands (82, 84) of the spring (62) are angularly supported each against a longitudinal edge (76, 78) of the window (74) of the sleeve (10), in that the window (68) of the rotor (12) has two extreme longitudinal edges (70, 72) and an intermediate longitudinal edge (80), in that, in the operating position of the rotor (12), the two strands (82, 84) of the spring (62) cooperate respectively, a first (82) with a first extreme longitudinal edge (70) and the second (84) with the intermediate longitudinal edge (80) of the rotor (12), in that the second extreme longitudinal edge ( 72) is spaced from the intermediate edge (80) by an angle at least substantially equal to the angular difference between the mounting and service positions of the rotor (12).  11. Lock according to claim 10, characterized in that the second strand (84) of the spring (62) is pressed axially against a substantially transverse edge (81A, 81B) of the window (68) of the rotor (12) which comprises, between the two extreme longitudinal edges (70, 72) a longitudinal recess forming the intermediate longitudinal edge (80) of the window (68) of the rotor (12), in that the substantially transverse edge comprises a ramp (81A) against which s '' axially supports the second strand (84) when the rotor (12) is brought from its coding position to its operating position, and in that when the rotor (12) reaches its operating position, the second strand comes into contact angularly against the intermediate edge (80).  12. Lock according to claim 1, characterized in that it is possible to release the second strand (84) of the angular spring (62) out of the recess forming the intermediate edge (80) to force the rotor (12) back towards its coding position.