FR3008123A1 - LOCK CYLINDER, LOCK EQUIPPED WITH SUCH A CYLINDER - Google Patents

Abstract

The lock cylinder (2) comprises a toothed wheel (4) operable by at least one key cylinder (6) of said cylinder (2), said gear (4) being intended to drive at least one bolt (18, 10). a lock (1) receiving said cylinder (2). The toothed wheel (4) is rotatably mounted about an axis of rotation (R), the toothed road (4) having a plurality of teeth (52, 54) having vertices (72) having radial spacings which are different each other with respect to the axis of rotation (R).

Description

Lock cylinder, lock equipped with such a cylinder The invention relates generally cylinder locks. More precisely, according to a first aspect, the invention relates to a lock cylinder of the type comprising a toothed wheel operable by at least one key cylinder of said cylinder, said gear wheel being intended to drive at least one bolt of a lock receiving said cylinder. . The same lock cylinder can cause several bolts of the lock, for example a lock bolt and a latch bolt. In some locks, it is observed that the user must exert a significant force on the key to move the latch bolt.

In this context, the invention aims to provide a lock that is more user-friendly. To this end, the invention relates to a lock cylinder of the aforementioned type, characterized in that the toothed wheel is mounted rotatably about an axis of rotation, the toothed wheel having a plurality of teeth having vertices having radial spacings different from each other with respect to the axis of rotation. Teeth with vertices located at radial spacings, that is to say larger modules, allow to obtain a higher torque for driving the bolt, while teeth whose vertices are located at spacings lower radials provide a smoother and more precise wheel bearing.

This lock cylinder is particularly advantageous when it is used in a lock equipped with two bolts, or more than two bolts, comprising a lock bolt and a latch bolt. In this type of lock, the latch bolt is returned to its locking position of the leaf by a spring, so that it is necessary to overcome the return force of the spring to unlock the leaf. The lock bolt, on the contrary, is not biased towards one or the other of its positions by an elastic member. In case, it is particularly advantageous to use the teeth having vertices located at greater radial spacings to move the latch bolt, which gives a better momentum to the latch of the lock. The lock bolt is moved via the teeth having vertices located at lower radial spacings, which allows for a more flexible and more regular movement of the lock bolt. The quality perceived by the user is increased. Here, the term "teeth" having vertices located at different radial spacings from each other with respect to the axis of rotation, the fact that the tops of the teeth are situated radially at distances that are different from each other on the axis of rotation. rotation of the toothed wheel. The top of the tooth corresponds to the free end of the tooth.

The cylinder may also have one or more of the following characteristics, considered individually or in any technically possible combination: the gear comprises a plurality of first teeth having vertices having radial spacings with respect to the upper axis of rotation at a predetermined value, and a plurality of second teeth having vertices having radial spacings with respect to the axis of rotation less than the predetermined value, the first teeth being arranged side by side, preferably all arranged side-by-side, side by side, the second teeth being arranged side by side, preferably all being arranged side by side; the teeth are arranged on an oval line; - The oval line has a geometric center, the axis of rotation being offset along a major axis of the oval line with respect to the geometric center; - The axis of rotation is shifted to the second teeth; the teeth are arranged on a circle; the second teeth have second heights, the first teeth having first heights greater than the second heights; - the first teeth are truncated; and the first heights are different from each other.

According to a second aspect, the invention relates to a cylinder lock comprising: a cylinder having the above characteristics, the toothed wheel comprising a plurality of first teeth having vertices having radial spacings with respect to the axis of rotation; greater than a predetermined value, and a plurality of second teeth having vertices having radial spacings relative to the axis of rotation less than the predetermined value; - a lock bolt and a latch bolt; a driving wheel for driving the latch bolt and the latch bolt, the driven wheel co-operating with the second teeth of the toothed wheel for driving the latch bolt, and cooperating with the first teeth of the toothed wheel for the latch; latch bolt drive. Other features and advantages of the invention will become apparent from the detailed description given below, by way of indication and in no way limiting, with reference to the appended figures, among which: FIG. 1 is a view from above, partly , a lock according to the invention mounted on an opening; - Figure 2 is a view similar to that of Figure 1, only certain elements of the lock being shown; - Figure 3 is an enlarged view of the toothed wheel and the driven wheel of a lock according to a first embodiment of the invention; FIG. 4 is a perspective view of the toothed wheel of FIG. 3 and the first and second flanges; and - Figure 5 is a view similar to that of Figure 4, for a toothed wheel and a driven wheel according to the second embodiment of the invention. In Figure 1 is shown schematically a lock 1 provided with a cylinder 2 having a toothed wheel 4 and at least one key cylinder 6 provided for actuating the toothed wheel. The lock 1 is mounted on an opening O. The lock 1 further comprises a lock bolt 8, a latch bolt 10, and a driven wheel 12 for driving the lock bolt 8 and the latch bolt 10. The driven wheel 12 drives the lock bolt 8 between a locking position of the opening and a unlocking position of the opening, both stable, by means of a first drive mechanism 14. In the locking position of the bolt lock 8, it protrudes from the opening O and is engaged in a striker (not shown). In the unlocking position, the lock bolt 8 is extracted from the striker and retracted into the lock.

The driven wheel 12 moves the latch bolt 10 via a second drive mechanism 16, between a stable locking position of the opening, and a release position of the opening. The mechanism 16 comprises a return spring 18 of the latch bolt 10 in its stable locking position. In the locking position, the latch bolt 10 protrudes from the opening O and is engaged in another keeper (not shown). In the unblocking position, the latch bolt is retracted out of the latch into the lock. The toothed wheel 4 is rotated about its axis of rotation R by one of the keyed barrels 6, and itself drives the driven wheel 12 about a pinion axis 20 visible in FIG. rotation of the driven wheel 12 moves the lock bolt 8 and the latch bolt 10 through the mechanisms 14 and 16 respectively. The set of movable elements of the lock is mounted on a lock box 22, itself fixed on the opening O. The first drive mechanism 14 comprises a bolt plate 24 to which the lock bolt 8 is rigidly fixed. platen bolt 24 has a slot 26, in which are formed a plurality of notches 28 regularly spaced (Figure 1).

The driven wheel 12 is provided with pins 30 (FIG. 2) cooperating with the notches 28. Thus, the rotational displacement of the driven wheel 12 around the pinion pinion 20 causes the translational movement of the bolt plate 24 and the bolt lock 8 with respect to the lock box 22, by means of the pins 30 cooperating with the notches 28.

The second mechanism 16 comprises a turntable 32 on which is rigidly fixed the latch bolt 10, a half-turn rod 34 and a half-turn bracket 36 rigidly fixed to the driven wheel 12. The half-turn rod 34 is connected by a pivot connection 38 to the lock case 22. It has two arms 40 and 42 extending on either side of a central portion 44 connected to the lock box by the pivot connection 38. The arm 40 is provided with an oblong hole 46, in which is engaged a lug 48 carried by the half-turn plate 32. The half-turn bracket 36 comprises a cam 50, the arm 42 constituting a cam follower cooperating with the cam 50. More precisely when the driven wheel 12 is rotated with respect to the lock case 22 in the clockwise direction in the representation of FIG. 1, the cam 50 drives the arm 42, causing the half-turn link 34 to tilt around the link pivot 38 counterclockwise in the representation of Figure 1. The half-turn rod 34 in turn drives the turntable 32 in translation, through the oblong hole 46 cooperating with the lug 48, to its unlocking position. The spring 18 is interposed between the lock case 22 and the half-turn plate 32. This spring is a tension spring, which recalls the turntable and the latch latch to the locking position. Note that, as illustrated in Figure 2, the lock is a multipoint lock equipped with a linkage 51 for moving several other locking members (not shown) under the effect of the rotation of the driven wheel 12 relative to the lock case 22 around the pinion axis 20. According to a first aspect of the invention, seen more particularly in Figures 3, 4 and 5, the toothed wheel 4 comprises a plurality of teeth having vertices located at radial spacings, that is to say modules, different from each other with respect to the axis of rotation R of the toothed wheel 4. More specifically, the toothed wheel 4 comprises a plurality of first teeth 52 having respective radial spacings by relative to the axis of rotation R greater than a predetermined value, and a plurality of second teeth 54 having respective radial spacings with respect to the axis of rotation R less than the predetermined value undermined. Said predetermined value is a function of the size of the toothed wheel and other design parameters.

The first teeth 52 are placed next to each other. The second teeth 54 are also placed next to each other. Thus, a periphery of the toothed wheel 4 is located along a first sector where the first teeth 52 are disposed and then a second sector where the second teeth 54 are arranged. The first teeth 52 have first angular spacings between them. The second teeth 54 have between them second angular spacings, lower than the first angular spacings. In a first embodiment shown in FIG. 3, the teeth 52, 54 are arranged on a circle centered on the axis of rotation R. More specifically, the teeth 52, 54 are separated from each other by notches 56, 57, the notch bottoms being arranged in a circle centered on the axis of rotation R.

With respect to the bottom of the notches 56, 57, that is to say the circle, the first teeth 52 have first heights. The second teeth 54 have second heights lower than the first height. In order to avoid any fraudulent reproduction, the first teeth 52 are truncated, and more precisely are staggered at different heights from each other with respect to the bottoms of the notches 56, 57. The driven wheel 12 has shaped driven teeth to cooperate with the first and second teeth 52 and 54 of the toothed wheel 4. The angular spacing between the driven teeth, and the depth of the notches separating the driven teeth from each other, are chosen to allow the meshing of the teeth 52 and 54 of the toothed wheel 4 with the teeth of the driven wheel 12. More specifically, as shown in Figure 3, the driven wheel only has teeth on a portion of its circumference. It thus comprises a first angular sector 58 carrying first driven teeth 59, extended by a second sector 60 bearing second driven teeth 61 and a third sector 62 carrying first teeth 59. The sector 60 is therefore interposed between the sectors 58 and 62 along the circumference of the driven wheel. The first driven teeth 59 carried by the sectors 58 and 62 have between them an angular spacing greater than the angular spacing separating the second teeth 61 from each other.

Likewise, the first driven teeth 59 have, relative to the bottom of the notches 68, heights greater than those of the second driven teeth 61. As can be seen in FIG. 3, the depth of the notches 68 in the sectors 58 and 62 is variable, so that to adapt to the variable height of the first teeth 52. In the example shown, the toothed wheel 4 has five second teeth 54, and seven first teeth 52. For example, the first seven teeth 52 are at module 1.83 calculated on the base of eleven teeth. The five second teeth 54 are at module 1.25 calculated on the basis of fourteen teeth. Advantageously, the driven wheel 12 cooperates with the second teeth 54 of the toothed wheel 4 for driving the lock bolt 8 between its locking position and its unlocking position, and cooperates with the first teeth 52 of the toothed wheel 4 for driving the latch bolt 10 between its locking position and its unlocking position. Thus, the driving of the lock bolt 8 is made in a particularly flexible movement due to the configuration of the second teeth 54. The driving of the latch bolt is achieved with a better momentum, that is to say with a greater torque, because of the large size of the first teeth 52. According to a second aspect of the invention, independent of the first, the cylinder 2 comprises a first flange 70 attached to a first side face of the toothed wheel 4 and closing laterally at least some notches 56, 57 (Figure 3).

The first lateral face of the toothed wheel 4 corresponds to the face of the toothed wheel 4 which is perpendicular to the axis of rotation R and which is located on one side of the toothed wheel 4 intended to be turned outwards. the opening O. This side is towards the bottom of the sheet in the representation of Figure 1. This first flange 70 is rigidly attached to the toothed wheel 4. It completely closes certain notches 56. However, as shown in FIG. 3, a small number of notches 57 are not blocked by the first flange 70 and remain free, so as to mount the toothed wheel 4 inside the lock. More specifically, as shown in Figure 3, the flange extends from the bottom of the notches 56 at least to the top of the teeth 52 and 54 flanking the notches 56. The flange 70 extends radially beyond the vertices 72 of the greater part of the first and second teeth 52 and 54. In the example shown, two notches 57 are not closed by the first flange 70. All the other notches 56 are completely closed by the flange 70. The two notches 57 on the other hand are completely free. The two notched notches 57 are located between two second teeth 54. Furthermore, the cylinder also comprises a second flange 74, visible in FIG. 4. This second flange is placed against a second lateral face of the toothed wheel 4, opposite to the first side face. It is not rigidly attached to the toothed wheel. This second flange seals laterally at least some notches 56, 57, for example laterally closes all the notches 56, 57.

As can be seen in FIGS. 1 and 2, the first flange 70 is placed, according to the axis of rotation R of the toothed wheel, between the lock case 22 and the toothed wheel 4. In the locking position and in the unlocking position of the lock bolt 8, the driven wheel 12 cooperates with notches 56 of the toothed wheel 4 which are closed by the first flange. In other words, an edge zone of the first flange 70 is interposed, according to the axis of rotation R, between the lock box 22 and the driven wheel 12. Thus, if someone tries to axially push the cylinder 2 to from the outer side of the opening O on which the lock 1 is mounted, the first flange 70 bears against the driven wheel 12, which prevents the ejection of the cylinder 2.

This is valid in the locking position of the lock bolt 8 and in the unlocking position of the lock bolt 8. Moreover, the second flange 74 is interposed axially between the toothed wheel 4 and the half-turn bracket 36, at least in the locking position of the lock bolt 8. More specifically, an area of the outer edge of the second flange 74 is engaged between the driven wheel 12 and the turn-side bracket 36, in the locking position of the lock bolt 8. Thus, if someone exerts an axial thrust on the cylinder 2 from the outer side of the opening O on which the lock 1 is mounted, this axial thrust is transmitted by the toothed wheel 4 to the second flange 74, the peripheral edge of the second flange 74 abutting axially against the right-angle bracket 36. This further strengthens the resistance of the cylinder 2 ejection under the effect of an axial thrust. In a variant, a peripheral edge of the second flange 74 is engaged between the half-turn bracket 36 and the driven wheel 12 both in the locked position and in the unlocked position of the lock bolt. According to another variant embodiment, the second flange 74 is removably attached to the toothed wheel 4. In order to disassemble the cylinder 2, the second flange 74 is first extracted. Then, the toothed wheel 4 is turned into a position angular where the notches 57 not closed by the first flange 70 are engaged with the driven wheel 12. In this orientation, the first flange 70 does not prevent axially moving the toothed wheel 4, so as to extract it out of the lock . The assembly is carried out according to an inverse operating sequence. In order to prevent any interference of the first flange 70 with the driven wheel 12 during this disengagement movement, the flange 70 has a reduced diameter in the vicinity of the free slots 57.

As shown in Figure 3, the first flange 70 has along the first teeth 52 a first radius. In the portion of the flange 70 from the first teeth 52 to the free slots 57, the radius of the first flange 70 decreases. At the second teeth 54 located on either side of the free slots 57, the radius of the first flange 70 corresponds exactly to the height of the second teeth 54. A second embodiment of the invention will now be detailed, with reference in Figure 5. Only the points by which the second embodiment differs from the first will be detailed below. Identical elements or providing the same functions in the two embodiments will be designated by the same references. In the second embodiment, the teeth 52, 54 are arranged on an oval curve.

More precisely, the bottom of the notches 56 forms an oval line surrounding the axis of rotation R of the toothed wheel 4. The major axis X of the oval line is represented in FIG. 5 by a mixed line, and the geometric center of the oval line is materialized by the point C. It is thus seen in Figure 5 that the axis of rotation R is shifted along the major axis X, a first side of the geometric center C. The teeth located along the X axis the first side of the oval line are the second teeth 54. The teeth on a second side opposite to the first side are the first teeth 52. More precisely, if we consider the Y axis perpendicular to the X axis and passing by the axis of rotation R, as shown in Figure 5, the teeth on the Y axis or the second side of the Y axis are the first teeth 52, and the teeth on the first side of the Y axis are the second teeth 54. It is clear from Figure 5 that the vertices 72 of the second teeth 54 are, relative to the axis of rotation R, located at radial spacings smaller than those of the tops 72 of the first teeth 52. The angular spacing between the second teeth 54 is slightly larger than the angular spacing between the first teeth 54 teeth 52. In contrast, relative to the bottom of the notches 56, the first teeth and the second teeth 52 and 54 have the same height. The driven wheel 12 is designed to cooperate with the toothed wheel 4. It comprises a toothed angular sector 76, extending in an oval curve around the pinion axis 20 of the driven wheel 12. The portion 78 of this sector intended for cooperate with the second teeth 54 extends relatively further from the pinion axis 20. In contrast, the portions 80 and 82 of the sector 76 intended to cooperate with the first teeth 52 are relatively closer to the pinion axis 20.

In the example shown in FIG. 5, the first flange 70 is continuous, and closes all the notches 56 of the toothed wheel 4. In a variant, the first flange 70 does not close off certain notches, as illustrated in FIG.

Claims (10)

CLOSURE Cylinder (2) comprising a toothed wheel (4) operable by at least one key cylinder (6) of said cylinder (2), said toothed wheel (4) being intended to drive at least one bolt (18, 10) of a lock (1) receiving said cylinder (2), characterized in that the toothed wheel (4) is rotatably mounted about an axis of rotation (R), the toothed road (4) having a plurality of teeth (52,54) having vertices (72) having radial spacings different from each other with respect to the axis of rotation (R). 2. Cylinder according to claim 1, characterized in that the toothed wheel (4) comprises a plurality of first teeth (52) having vertices (72) having radial spacings relative to the axis of rotation (R) above at a predetermined value, and a plurality of second teeth (54) having vertices (72) having radial spacings relative to the axis of rotation (R) less than the predetermined value, the first teeth (52) being disposed rib side by side, preferably being all arranged side by side, the second teeth (54) being arranged side by side, preferably all being arranged side by side. 3. Cylinder according to claim 1 or 2, characterized in that the teeth (52, 54) are arranged on an oval line. 4. Cylinder according to claim 3, characterized in that the oval line has a geometric center (C), the axis of rotation (R) being offset along a major axis (X) of the oval line with respect to the geometric center (VS). 5. Cylinder according to claims 2 and 3, characterized in that the axis of rotation (R) is shifted to the second teeth (54). 6. Cylinder according to claim 1 or 2, characterized in that the teeth (52, 54) are arranged on a circle. 7. Cylinder according to claims 2 and 6, characterized in that the second teeth (54) have second heights, the first teeth (52) having first heights greater than the second height. 8. Cylinder according to claim 7, characterized in that the first teeth (52) are truncated. 9. Cylinder according to claim 7 or 8, characterized in that the first heights are different from each other. 10. Lock (1) cylinder comprising: - a cylinder (2) according to any one of the preceding claims, the toothed wheel (14) having a plurality of first teeth (52) having radial spacing relative to them an axis of rotation (R) greater than a predetermined value, and a plurality of second teeth (54) having radial spacings with respect to the axis of rotation (R) less than the predetermined value; - a lock bolt (8) and a latch bolt (10); - a driven wheel (12) for driving the lock bolt (18) and the latch bolt (10), the driven wheel (12) cooperating with the second teeth (54) of the toothed wheel (4) for the driving the lock bolt (8), and cooperating with the first teeth (52) of the toothed wheel (4) for driving the latch bolt (10) .10