FR3031761A1 - ADAPTATION MECHANISM FOR A PANNETON CYLINDER - Google Patents

Abstract

Adaptation mechanism for adapting a lock using a bit cylinder, of European type in particular, to a locking mechanism with continuous movement. According to the invention, this mechanism comprises an inlet pinion (40), annular, split radially according to a slot (42) extending at least over a certain angular quarter, intended to be arranged around the cylinder (10) in such a way that the bit (14) occupies the slot (42) of said input gear (40), an output gear (70), and two intermediate gears (50a, 50b), each having a toothing (51) and having a tooth-free exhaust recess (53), each configured to engage the input gear (40) when said toothing (51) meets the input gear (40), and with the output gear ( 70) when said toothing (51) meets the output gear (70); the intermediate gears (50a, 50b) are configured so that at any point in the path of the input gear (40) at least one of the two intermediate gears (50a, 50b) is engaged simultaneously with the pinion of input (40) and the output gear (70), and the exhaust recesses (53) of the intermediate gears (50a, 50b) are configured to allow the passage of the bit (14) of the cylinder (10).

Description

FIELD OF THE INVENTION The invention relates to an adaptation mechanism for adapting a lock using a bit cylinder to a locking mechanism with continuous movement; it also relates to a continuous motion lock incorporating such a cylinder with bit and this adaptation mechanism. Such a mechanism can be used to adapt a large number of locks using a bit cylinder, typically a European type cylinder, to locking mechanisms requiring continuous drive. STATE OF THE PRIOR ART Certain locking mechanisms are designed independently of the lock and are driven by simple rotation of an input shaft, thus offering the user the possibility of easily adapting the lock of his choice from a wide range. range of locks provided with a continuous rotary axial output. An example of a highly integrated lock requiring such a continuous drive is described in patent FR 2 930 582. Such mechanisms therefore require the use of cylinders with continuous rotary axial output. However, some markets require the use of specific cylinders to adapt to an existing key flow chart or a standard profile, these cylinders are not necessarily continuous axial output rotary. In particular, the European market favors the so-called "European" cylinder which operates by causing the rotation of a bit around the axis of the cylinder and therefore does not have a continuous rotary axial output adapted to such locking mechanisms. Some European profile cylinders equipped with a continuous rotary axial output have been developed but their use is limited: only a few manufacturers offer them and only in certain ranges. It is therefore not possible to impose such models on users. There are also mechanisms transforming the passage of the bit in a rotation of a complete turn of an output shaft, but these mechanisms are bulky, complex, and cause an unpleasant jerk at each turn since the effort of Lock training is focused on a small fraction of the stroke of the bit, typically of the order of a quarter turn. Other mechanisms have been proposed in which a split gear provided with a plurality of teeth is arranged around the axis of the blade and driven by the latter. However, in these mechanisms, since the input pinion is slotted, it is necessary to find a way to drive the locking mechanism on a complete key turn despite the interruption of the gear teeth and the obstacle represented by the bit. Some mechanisms then propose to use teeth of different sizes or shapes to mesh directly on the bit at the passage thereof: however, such solutions are coarse and detract from the fluidity and comfort of locking, especially at the time of passage of the bit. Other mechanisms provide gears provided in different planes, some provided with an exhaust to let the bit pass: however, these staged mechanisms are bulky, especially in the axial direction, so that they can not be used. used for certain particularly thin openings, such as glass doors 20. This is particularly the case for doors equipped with a standardized notch, called "64A", limited volume in which must hold the lock. There is therefore a real need for an adaptation mechanism capable of adapting a wide range of locks utilizing a bit cylinder to continuously moving locking mechanisms and which lacks the inherent drawbacks of the aforementioned known systems. PRESENTATION OF THE INVENTION The invention relates to an adaptation mechanism for adapting a lock using a bit cylinder to a continuously movable locking mechanism, comprising an annular, radially split inlet gear in a slot extending at least over a certain angular quarter, intended to be arranged around the cylinder so that the bit occupies the slot of said input gear, an output pinion, and two intermediate gears, each having a toothing and having a recess a tooth-free exhaust, each configured to be engaged with the input gear when said toothing encounters the input gear, and with the output gear when said toothing encounters the output gear, wherein the intermediate gears are configured so that at any point in the travel of the input gear at least one of the two intermediate gears is simultaneously engaged with the input gear and the output gear, and wherein the exhaust recesses of the intermediate gears are confljured to allow the passage of the bit of the cylinder. Upon insertion of the lock, the bit cylinder is inserted into the adapter mechanism such that the cylinder takes place within the space defined by the input gear, the latter then surrounding the cylinder body. In this position, the bit takes place in the slot of the input gear. Therefore, the rotation of the bit causes rotation of the input gear in one direction as in the other. Since at any time at least one intermediate gear is engaged simultaneously with the input gear and the output gear, the rotation of the bit always causes the rotation of at least one intermediate gear and the output gear. The rotation of the bit being driven continuously by the key, it is understood that the rotation of the key then continuously drives the rotation of the output gear. Since the input gear is necessarily split to accommodate the bit, there is an angular area in which the input gear has no teeth. When this angular portion occupied by the bit passes in front of the toothing of the first intermediate gear, it is no longer in engagement but continues to rotate because its toothing remains in engagement with the output gear driven in rotation by the second pinion. intermediate, which remains in engagement with the pinion input. In addition, in the case where the bit is longer than the root diameter of the input gear, that is to say the diameter of the circle passing through the base of its toothing, this first intermediate gear is configured to present its escape recess when the bit arrives, allowing the passage of the bit. Since this first gear continues to rotate during the passage of the bit, its exhaust recess will again place the teeth to resume engagement with the input pinion when the bit is completely past. Once the first intermediate gear is engaged again, the second intermediate gear can escape in turn. The two intermediate gears remain synchronized since they are in continuous engagement with either the input gear or the output gear. Such configurations in which at any time at least one pinion, provided with a single toothing, is simultaneously engaged with the input pinion and the output pinion are few and difficult to identify. In particular, the number of existing geometric solutions further decreases when certain design constraints are superimposed in order to adapt this mechanism to certain openings or certain particular locking mechanisms. Thus, given the many parameters defining such a mechanism, including the positions, pitch diameters and number of teeth of each of the pinions, the inventors have found that a trial and error approach was futile to identify a satisfactory configuration. In particular, the smaller the intermediate gears, the more the exhaust recesses occupy a large angular range, which compromises the possibility of always having at least one of the two intermediate gears which is engaged simultaneously with the pinion. entrance and the output gear. Therefore, the inventors have studied precisely the problem to identify the mathematical rules governing the operation of such a mechanism. This allowed them to greatly reduce the scope of potential solutions and thus highlight sets of functional parameters given the constraints imposed by a given application. Thus, in this way is achieved the adaptation of a lock using a bit cylinder in continuous motion lock in which the key continuously drives an output pinion. It is then possible to drive a locking mechanism with continuous rotation by connecting this locking mechanism to the output gear with a shaft for example. This adaptation mechanism thus makes it possible to reconcile the technical requirements of the locking mechanism with the requirements of the market. This adaptation mechanism is more particularly adapted for openings requiring a lock of reduced thickness.

In addition, it offers an impression of greater fluidity during locking / unlocking since the drive force of the locking mechanism is distributed over the full stroke of the blade thus eliminating the traditional shock of the bit cylinders felt at the moment effective work of the bit. The impression of quality is thus increased. In addition, this mechanism allows a great modularity since different types of bit cylinders can be used without changing the adaptation mechanism: each user can choose the cylinder he wants from a wide range of models. In addition, it makes it possible to change the cylinder without dismantling the adaptation mechanism, which greatly facilitates the management of key organization charts in a company for example. In some embodiments, it is not a key that drives the bit but a button. In some embodiments, each intermediate gear has a single toothing. In particular, the intermediate gears are not shaded. The latter do not cause a shift in depth of some parts of the mechanism, which ensures its axial compactness. In some embodiments, the toothing of each intermediate gear has a plurality of identical teeth regularly spaced apart from the area of the exhaust recess. In addition to the presence of the exhaust recess, these gears therefore respect a conventional geometry, possibly standardized. In particular, the intermediate gears do not have teeth having a different shape in order to cooperate with the bit or with a special tooth of another pinion for example. The stroke of the mechanism remains fluid and regular, smoothly or altering the kinetics of movement, which is more pleasant and comfortable for the user. Such a regular toothing is also stronger and more robust against the risk of jamming. In some embodiments, the toothing of each intermediate gear comprises at least fifteen teeth. In some embodiments, the intermediate gears are identical. They can however be out of phase, that is to say have different angles of rotation relative to the input gear. The manufacture of parts is thus facilitated. In some embodiments, the axes of rotation of the input gear, the intermediate gears, and the output gear are parallel. This arrangement simplifies the arrangement of the gears and keeps a direction unchanged between the drive shaft of the locking mechanism and the axis of the key. In some embodiments, the input gear, the intermediate gears and the output gear are arranged in the same plane. In this way, the mechanism has a reduced thickness and can be implemented in a thin opening, including a glass door, type "CLARIT" for example. The thickness of the device can thus be less than 10 mm, preferably 8 mm. In some embodiments, the transmission ratios between the input gear and each of the two intermediate gears are equal, and the transmission ratios between the output gear and each of the two intermediate gears are also equal, so that both intermediate gears are synchronized. This makes it possible to keep a constant phase shift between the two intermediate gears.

In some embodiments, the transmission ratios between the input gear and the intermediate gears on the one hand, and between the output gear and the intermediate gears on the other hand are equal, so that the input gears and output are homokinetic. In this way, a turn of the key will cause a turn of the output gear and thus a latch of the locking mechanism. In other embodiments, these transmission ratios are chosen so that the locking mechanism performs more than one turn during a key turn, for example two full turns. In some embodiments, the input and output gears have the same pitch diameter. This ensures easy equality of transmission ratios and thus the homokinetics of the input and output gears. In some embodiments, the axes of rotation of the input and output gears are not located in the same half-space defined by the axes of rotation of the intermediate gears. In particular, the output gear can be arranged next to the cylinder.

In some embodiments, the assembly formed by the input gear and the intermediate gears fit into a circle of diameter less than 63mm. This makes it possible to integrate the mechanism into a standardized notch of the "64A" type frequently used for glass doors, such as CLAM '. In some embodiments, the intermediate gears have a pitch diameter strictly less than the pitch diameters of the input gear and / or the output gear. This improves the compactness of the mechanism.

In some embodiments, the mechanism further comprises an adjustment member intended to be arranged and placed in compression between the bit and the input pinion, so that the rotation of the bit is transmitted to the input gear by via said adjustment member. This organ makes it possible to adapt the mechanism to different geometries of pannetons. In particular, it ensures the centering of the bit in the slot of the input pinion and reduces the game related to the movement of the bit in the slot. In some embodiments, this adjustment member is composed of two elastic bars, said bars being placed in compression between the bit and the input gear. Grooves may be provided in the flanks of the slot of the input gear to wedge said elastic bars. In other embodiments, this adjustment member is an elastic adjustment ring of diameter substantially equal to the inside diameter of the input gear, interrupted on an angular sector substantially equal to said angular region of the slot of the pinion. input, and having in this sector two convergent tabs, said ring being placed in compression against the input pinion during the introduction of the bit between said two tabs.

In some embodiments, the mechanism further includes a lock pinion and a lock member having a bolt and a cam surface; the locking gear is provided with a finger configured to cooperate with the cam surface of the locking member so as to control the position of the bolt. The mechanism thus makes it possible to cause the exit of the bolt when it is driven to its locked state in order to lock an opening.

In some embodiments, when the mechanism is in its locked state, the lock pinion finger is disposed on the normal line to the cam surface of the lock member and passing through the axis of rotation of the lock pinion or overtook such a straight line during the course of the locked state. This ensures the irreversibility of the locking mechanism in case of fraudulent attempt to manually retract the bolt. The invention also relates to a continuous motion lock incorporating a bit cylinder and an adaptation mechanism according to any one of the preceding embodiments. In some embodiments, the cylinder is a European cylinder comprising an oblong projection radial to the axis of rotation of the key and provided with a transverse window allowing the passage of the bit. This type of cylinder is very common and frequently imposed on the European market. In such a case, the slot of the input gear is sufficiently wide to allow the passage of the oblong protrusion of the cylinder. In some embodiments, the input gear is configured to pass into the cylinder window. This allows rotation of the input gear 20 despite the presence of the oblong protuberance. In some embodiments, the axial width of the input gear is substantially equal to the axial width of the cylinder window. This makes it possible to increase the tooth width and the strength of the input gear. In some embodiments, the diameter of the input pinion head circle, i.e. the diameter of the circle passing through the tops of its toothing, is substantially equal to the depth of the cylinder window since the axis of rotation of key. This makes it possible to reduce the size of the exhaust recesses of the intermediate gears, thus increasing the strength of the intermediate gears. In some embodiments, the rotational axes of the intermediate gears are arranged in a plane parallel to the plane of symmetry of said oblong outgrowth. In other words, the straight line connecting the centers of the two intermediate gears is parallel to the axis of the oblong protrusion of the cylinder.

In some embodiments, the exhaust recesses of the intermediate gears are contiguous so as to flush the bit during its passage. This makes it possible to remove less material from the intermediate gears and thus to increase their solidity.

The above-mentioned characteristics and advantages, as well as others, will appear on reading the following detailed description of embodiments of the mechanism and the lock proposed. This detailed description refers to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings are schematic and are intended primarily to illustrate the principles of the invention. In these drawings, from one figure to the other, identical elements (or element parts) are identified by the same reference signs.

Figure 1 is a perspective view of an example of a European half-cylinder. Figure 2 is a perspective view of an adaptation mechanism according to the invention. Figure 3 is a partial plan view of the mechanism of Figure 2. Figures 4A to 4D are plan views of a lock according to the invention at different times of the stroke of the bit. Figure 5 is a plan view of a standardized 64A type notch.

Figure 6 is a plan view of standardized 6300 EX ports. DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS In order to make the invention more concrete, an exemplary lock is described in detail below with reference to the accompanying drawings. It is recalled that the invention is not limited to this example. This lock 1 consists of a bit cylinder 10 and the adaptation mechanism itself 20. The bit cylinder 10, shown in Figure 1 and Figures 4A to 4D, here is a half-cylinder European type. It consists of a cylindrical body 11, axis A, radially extended over its entire length by an oblong protuberance 12. It has at one end a flat face in which is formed a slot 13 for receiving a key. The cylinder is internally provided with several moving elements, typically pistons, balls or blades, allowing the locking of the cylinder. When a key having the appropriate geometry is inserted in the slot 13, it cooperates with these moving elements to release the rotation of a bit 14. In this case, the bit cylinder 10 presented here is a European half-cylinder because it has only one key entry; however, it goes without saying that an entire cylinder provided with a key or button input at each of these ends would also be possible and even preferable in many applications. Thus, once a suitable key inserted in the slot 13, the rotation of this key around the axis A drives continuously, at the same speed, the rotation of the bit 14 around the cylindrical body 11 of the cylinder. It is noted that a window 15 is made in the oblong protrusion 12 of the cylinder 10 to allow the passage of the bit 14. The adaptation mechanism 20, shown in Figure 2 and Figures 3 and 4A-4D, comprises meanwhile a support 30, an input gear 40, two intermediate gears 50a and 50b, an output gear 70 and a locking device 80. The output gear 70 comprises an output shaft 73, fluted, allowing the driving on a complete turn of a not shown locking mechanism such as for example a cremone mechanism such as that presented in application FR 2 930 582. The input gear 40 is substantially annular of inner diameter Di substantially equal, although strictly greater than the diameter of the cylindrical body 11 of the cylinder 10. The input gear 40 has a toothing 41 on its outer radial surface. This toothing 41 has a pitch diameter Dp and a head diameter D.sub.t This head circle diameter D.sub.t is smaller than the depth of the window 15 of the bit 14 taken from the axis A of the cylinder 10. The input gear 40 is split radially along a slot 42 of width L1 substantially equal to, although strictly greater than, the width of the oblong protrusion 12 of the cylinder 10.

This inner diameter Di and this slot 42 define a passage space 43 within the input gear 40. The input gear 40 also has two wedging rings 44 flanking the toothing 41 and cooperating with a wedging surface 31 of the 5 support 30 ensuring its good arrangement within the mechanism 20. When mounting the lock, the cylinder 10 is inserted into the passage space 43 of the input gear 40. The bit 14 is then found within the slot 42 of the input pinion 40. Locking members are provided for retaining the cylinder 10 in the adaptation mechanism 20. An adjustment member is provided between the bit 14 and the input pinion 40. In this case, FIG. embodiment, it consists of two elastic bars 90a and 90b placed on either side of the bit 14, at its proximal end. They can each be retained in a groove formed in each side of the slot 42 of the input gear 40. These bars are made in the form of hollow cylinder split longitudinally along their entire length. Thus, the rotation of the key about the axis A continuously drives the rotation of the input gear 40. Each intermediate gear 50a and 50b is a pinion provided with a single toothing 51. The intermediate gears 50a, 50b are arranged so that their teeth 51 can meet the toothing 41 of the input gear 40. In addition, each intermediate gear 50a, 50b has an exhaust recess 53 at which no tooth 25 is present and where the pinion intermediate 50a, 50b could be dug beyond the foot ring of the toothing 51. Each intermediate gear 50a, 50b further has a central bore 54 each cooperating with a pivot 33 of the support 30. The output gear 70 has a It is arranged in such a way that its toothing 71 can meet the teeth 51 of each of the intermediate gears 50a and 50b. It is provided with an output shaft 73 projecting out of the adaptation mechanism. This output shaft 73 is splined so as to allow its connection to the locking mechanism, not shown, following the lock 1. This shaft 73 also acts as a pivot for the output gear 70 vis-à-vis the support 30.

In addition to this locking mechanism, controlled by the shaft 73, which can extend vertically within the sash or stick handles added along the sash, the adaptation mechanism also comprises a locking device 80 of medium opening member 5 comprising a locking gear 81 and a locking member 85. The locking pinion 81 is provided with a toothing 82 engaged with the toothing 71 of the output pinion 70 and a locking pin 83 protruding perpendicular to the front surface of the locking gear 81. The locking member 85 takes the form of a plate guided in translation at its upper and lower ends between two guides 35 of the support 30. A light 86 is formed in the locking member 85: the walls of this slot 86 form a cam surface 87 adapted to cooperate with the locking pin 83 of the locking pinion 80, the latter being engaged in the light 86. The distal end of the locking member 85 forms a portion of bolt 88, thicker, capable of protruding out of the lock 1 to cooperate with a keeper provided on the amount of the opening. This locking device 80 integrated in the adaptation mechanism 20 is optional and can be provided in addition to or in replacement of the door locking mechanism. Figures 4A to 4D show in plan, at four different times of the stroke of the bit 14, a lock 1 incorporating the adaptation mechanism 20 previous. It can be seen from these figures that, despite the exhaust recesses 53 of the intermediate gears 50a and 50b, at any time at least one intermediate gear 50a or 50b is engaged simultaneously with the input pinion 40 and the output pinion 70. FIG. 4A illustrates the unlocked state of the lock 1. The adapted key 30 is then inserted into the slot 13 of the cylinder 10 and begins to drive the bit 14 in the clockwise direction, that is to say the direction locking. FIG. 4B illustrates the passage of the bit 14 at the level of the first intermediate gear 50a: it can be seen that the latter has been configured to present the escape recess 53 of its toothing 51 during the passage of the bit 14 in order not to block it.

At this time, since the second intermediate gear 50b is engaged simultaneously with the input gear 40 and the output gear 70, the output gear 70 continues to be driven regularly without any interruption or shifting. . Therefore, since the first intermediate gear 50a remains engaged with the output gear, the first intermediate gear 50a continues to rotate during the passage of the key bit 14 synchronously with the second intermediate gear 50b. It can then resume naturally and smoothly with the input pinion 40 as soon as its escape recess 53 leaves the cooperation zone with the input pinion 40 as shown in FIG. 4C. The first intermediate gear 50a is now engaged again, the second intermediate gear 50b can in turn escape when its exhaust recess 53. Finally, FIG. 4D illustrates the locked state of the lock 1 reached 15 after a complete turn. bit 14; the cylinder 10 having returned to its initial state, the key is released and can be removed from the slot 13. Due to the transmission ratios chosen, it can be seen in FIG. 4D that the intermediate gears 50a and 50b have made a total of a little more than one lap while the output pinion 70 did exactly one lap. During this locking stroke of the lock, the locking pin 83 rotates about the axis of rotation 84 of the locking pinion 81 integrally with the latter, which is in engagement with the output gear 70. The locking pin 83 then circulates in a first time within a circumferential portion 86a of the light 86 25 and therefore does not lead to the bolt portion 88. Then, as shown in FIG. 4B, it penetrates and passes through a rectangular portion 86b of the light 86 without touching the walls of the light 86 and thus without driving the bolt portion 88. About two-thirds of the stroke of the bit 14, at the moment shown in FIG. 4C, the locking finger 83 reaches the distal wall 87 of the rectangular portion 86b of the light 86: from this moment, the locking pin 83 pushes on this wall 87 forming a cam surface and therefore causes the exit of the bolt portion 88. In the locked state , 4D, the locking pin 83 is located in the distal and upper angle of the rectangular portion 86b of the lumen 86 and on the straight line extending perpendicular to the cam surface 87 and passing through the axis. turn of 84 locking pinion 81. Thus, if an ill-intentioned person seeks to press the bolt tab 88 to try to unlock the lock, no torque is exerted on the lock pinion 81 so that the lock 1 is not driven to its unlocked state. The unlocking of the lock 1 is carried out in the opposite direction in a similar way. During this movement, the locking pin 83 first passes through the rectangular portion 86b of the light 86 without driving the bolt 88. Then, it reaches the proximal wall of the rectangular portion 86b of the light 86: from this point moment, the locking finger 83 pushes on this proximal wall and therefore causes the return of the bolt portion 88 within the lock. The locking pin 83 ends up running along the circumferential portion 86a of the lumen 86, thus without driving the bolt portion 88. One way of determining a functional configuration of such a mating mechanism will now be described. In this example, the inventors have sought to integrate the lock previously described in the notch 64A of a CLARIT glass door 8 mm thick. The dimensions of such a notch 64A, standardized, are shown in Figure 5. Such a notch, symmetrical along a horizontal axis, extends 119 mm from the side edge of the door thus equipped. It comprises a circular portion, 63 mm in diameter, whose center is disposed at 87.5 mm from the edge of the door, and a trapezoidal portion whose long side measures 64 mm at the edge of the door and the short side measures 54 mm at the intersection with the circular portion. In addition to this congestion constraint, it was also desired that the output gear 70 be homokinetic with the input gear 40 30 so that a turn of the key exactly drives one turn of the output shaft 73. The inventors then determined that in order to perform the calculations, it was necessary to take advantage of the symmetries offered by the system. Thus, to carry out the calculations, the slot 42 of the input pinion 40 allowing the bit 14 to pass is positioned horizontally, in a central position between the two intermediate gears 50a, 50b, in accordance with the situation shown in FIG. position, the system necessarily has two axes of symmetry: a vertical axis V centered on the two intermediate gears 50a, 50b; and a horizontal axis 1-1 centered on the input 40 and output 70 gears.

From each point of tangency of the pitch circles of the input pinion 40 and the intermediate gears 50a, 50b, we will search for the nearest point corresponding to a vertex (or a bottom) of tooth. Between these two points P1, P2 on the input gear 40, there is necessarily an integer Ni of teeth. The only possible positions of such gear train, forming gear, are those corresponding at the same time to an integer number of teeth N2 on the corresponding sector of the intermediate gear 50a to the output gear 70. The positions allowing the constitution of Such a gear is discrete, few in number, and can therefore be tested one by one. A priori defines a number of teeth N of the input pinion 40 (without taking into account the slot 42 and therefore the absence of certain teeth in reality) which will also be that of the output pinion 70. The module M of In this case, the input pinion 40 defines the pitch diameter Dp of the input pinion 40 as well as its head diameter, that is to say its overall diameter. The module M is then defined a priori so that the head diameter Dt of the input gear is slightly smaller than that of the circle described by the end of the bit 14 of a European cylinder 10. This module M is naturally taken over for the other pinions 50a, 50b and 70 of the mechanism 20. The number of teeth N 'of the intermediate gears 50a, 50b may then vary around N. In order to respect the compactness constraint, a lower number of teeth N' will be chosen. to N. N being given, for each N ', the remaining degree of freedom is the angular position To intermediate gears 50a, 50b with respect to the input pinion 40, the horizontal axis of symmetry H defining the axis of reference for the calculation of this angle. However, there are only a few angular positions to intermediate gears 50a, 50b which satisfy the rules set out above and which do not overlap the intermediate gears 50a, 50b with respect to each other on the one hand ( To too low), and input gears 40 and output 70 on the other hand (too high). For each of these angular positions to be admissible, the positions of the slot 42 of the input gear 40 and the exhaust recesses 53 of the intermediate gears 50a, 50b are calculated. It can then be verified whether, on a complete rotation of the input gear 40, there is at any time at least one of the two intermediate gears 50a, 50b which is engaged with both the input pinion 40 and the output gear 70.

It appears that if N 'becomes too small with respect to N, there is no longer any construction ensuring this permanent gear. It also appears that for an N 'less than but close to N, there exists at most a very limited number of positions satisfying all these conditions. Under these conditions, at most three distinct positions are generally functional. The choice of the optimal solution is then made between a very limited number of theoretically admissible solutions by minimizing the overall dimension of the system, in this case by ensuring its integration within a notch 64A, and ensuring the greatest overlap angular possible between the continuous gear positions of each of the intermediate gears 50a, 50b. In addition, to simultaneously satisfy a second standard sizing door locks, including CLARIT doors, called 6300EX, competing with the notch 64A but majority out of France, it should be checked that the distance between L2 separating the pinion input 40 and output pinion 70 is included in a range compatible with the two circular holes made in the door according to this standard 6300EX. Indeed, in the context of this standard 6300EX, the lock is reported in front of the door but the cylinder 10 on the one hand and the output shaft 73 on the other hand must be able to pass through the door at the two circular orifices provided by this standard. The dimensions of these 6300EX orifices are shown in FIG. 6: the two orifices are aligned on the same horizontal line and measure 45 mm in diameter; their centers are respectively 121 mm and 60 mm from the edge of the door. Therefore, to be compatible with this 64Astandard 6300 EX, the lock 1 must have a center distance L2 strictly between 16 and 106 mm, and preferably even between 30 and 90 mm to take account of the bulk of the European cylinder 10 and of the output shaft 73. All these constraints having been taken into account, the inventors 5 determined that a functional configuration could be defined as follows: input gear 40: number of teeth N = 33 (of which 4 removed to practice cleft 42); pitch diameter Dp = 27 mm; intermediate gears 50a, 50b: number of teeth N '= 31 10 (of which 3 removed to practice the recesses 53); pitch diameter Dp '= 25.36 mm; output gear 70: number of teeth N = 33; pitch diameter Dp = 27 mm; angular difference of the intermediate gears λ = 35.16 °; The distance between the input 40 and output 70 gears L2 = 42.81 mm; - exhaust recesses 53: angular sector of 3 whole teeth removed; the residual radius in the middle of the recess is 10 mm, ie a cut-out of 2.68 mm with respect to the pitch phase-shift pitch of the intermediate gears: 145.17 °. The embodiments or examples of embodiment described in the present description are given as illustrative and not limiting, a person skilled in the art can easily, in view of this presentation, modify these modes or embodiments, or consider others, while remaining within the scope of the invention. In addition, the various features of these modes or embodiments can be used alone or be combined with each other. When combined, these features may be as described above or differently, the invention not being limited to the specific combinations described herein. In particular, unless otherwise specified, a characteristic described in connection with a mode or example of embodiment may be applied in a similar manner to another embodiment or embodiment.

Claims (11)

REVENDICATIONS1. An adaptation mechanism for adapting a lock using a bit cylinder to a continuously moving locking mechanism, comprising an annular, radially split, input gear (40) which is split radially into a slot (42) extending over at least some angular region, intended to be arranged around the cylinder (10) so that the bit (14) occupies the slot (42) of said input gear (40), an output gear (70), and two pinions intermediate members (50a, 50b), each having a toothing (51) and having a tooth-free exhaust recess (53), each configured to engage the input gear (40) when said toothing (51) encountering the input gear (40), and with the output gear (70) when said toothing (51) meets the output gear (70), wherein the intermediate gears (50a, 50b) are configured so that at any point in the travel of the input gear (40) at least one of the two gears intermediate (50a, 50b) is engaged simultaneously with the input gear (40) and the output gear (70), and wherein the exhaust recesses (53) of the intermediate gears (50a, 50b) are configured to allow the passage of the bit (14) of the cylinder (10). 2. Mechanism according to claim 1, wherein each intermediate gear (50a, 50b) comprises a single toothing (51), and in which the toothing (51) of each intermediate gear (50a, 50b) comprises a plurality of identical teeth. regularly spaced apart from the area of the exhaust recess (53). 3. Mechanism according to claim 1 or 2, wherein the input gear (40), the intermediate gears (50a, 50b) and the output gear 35 (70) are arranged in the same plane. 4. Mechanism according to any one of claims 1 to 3, wherein the transmission ratios between the input gear (40) and the intermediate gears (50a, 50b) on the one hand, and between the output gear ( 70) and the intermediate gears (50a, 50b) on the other hand are equal, so that the input (40) and output (70) gears are homokinetic. 5. Mechanism according to any one of claims 1 to 4, wherein the assembly formed by the input gear (40) and the intermediate gears (50a, 50b) are in a circle with a diameter less than 63mm. 6. Mechanism according to any one of claims 1 to 5, wherein the intermediate gears (50a, 50b) have a pitch diameter strictly less than the pitch diameters of the input gear (40) and / or the output gear (70). ). The mechanism of any one of claims 1 to 6, further comprising a lock gear (81) and a lock member (85) having a bolt (88) and a cam surface (87), wherein the locking pinion (81) is provided with a finger (83) configured to cooperate with the cam surface (87) of the locking member (85) to control the position of the bolt (88). 25 8. Mechanism according to claim 7, wherein, when the mechanism (20) is in its locked state, the finger (83) of the locking gear (80) is disposed on the line normal to the cam surface (87) of the locking member (85) and passing through the axis of rotation of the locking pinion (81) or has exceeded such a right during the course of the locked state. 9. Continuous motion lock incorporating a bit cylinder (10) and a matching mechanism (20) according to any one of the preceding claims. 35 10. A lock according to claim 9, wherein the cylinder (10) is a European cylinder comprising an oblong outgrowth (12) radial to the axis of rotation of a key (A) and provided with a transverse window (15) allowing the passage of the bit (14). 11. Lock according to claim 9 or 10, wherein the rotational axes 5 of the intermediate gears (50a, 50b) are arranged in a plane parallel to the plane of symmetry of said oblong projection (12).