CH715773B1 - Safe drive system, in particular for a watch calendar. - Google Patents

Abstract

The invention relates to a drive system comprising: a board (10) intended to receive a driving torque, a driving finger (12) intended to transmit the driving torque received by the board (10), said driving finger (12) being mounted free in rotation on the axis of the board (10), a drive pin (100) arranged on the board (10) so as to cooperate with the drive finger (12), characterized in that the pin (100 ) is elastically mounted and in that the pin (100) and the driving finger (12) are arranged so as to: connect the board (10) and the driving finger (12) in rotation when the board (10) is driven in a first direction of rotation by the driving torque, cause an elastic displacement of the pin (100) when the board (10) is driven in a second direction of rotation by the driving torque and is subjected to a resistant torque able to move the pin (100), the elastic displacement making it possible to position the pin (100) outside the stroke of the drive finger (12).

Description

Technical area

The present invention relates to the field of watchmaking. It relates, more particularly, to a safe drive system comprising a board intended to receive a motor torque, a drive finger intended to transmit the motor torque received by the board and a drive pin arranged on the board so as to cooperate with the trainer finger.

State of the art

[0002] Drive systems as mentioned above are commonly found in watch mechanisms. For example, in jumping type drive mechanisms, where a display is changed at a set time. For example, in date mechanisms, a 24-hour mobile is arranged to drive a display mobile one step per day, around midnight.

[0003] For the date correction, it is common that this can only be done in one direction, in this case forwards. According to the system used, the display mobile is driven by a rocker carried by a control mobile, which is itself driven by the drive finger. Such a rocker is capable of driving the mobile display only in one direction. Thus, during a backward correction, the rocker can cause blockage with the mobile display and the cogs of the kinematic correction or drive chain can be damaged.

[0004] Furthermore, safety devices can also be provided to avoid damage to the mechanism, if the time is set around midnight, when the drive finger is in engagement with a cog in the date display.

[0005] The drive finger can simply be elastically movable at the periphery of the 24h wheel, in order to be able to escape from the teeth with which it cooperates in the event of resistance. It is nevertheless necessary that the elastic displacement is absent or limited in the direction of the normal training, to have an effective training.

In the document CH8064959, there is a more complex system implementing a differential, comprising (the numbers in parentheses are the references used in this document) a sun wheel (24) with which meshes a radial finger (25) intended to drive a date crown (26). The wheel (24) is able to move angularly around its axis between a fixed stop and an elastic stop formed by a leaf spring (31). The member of the wheel (24) which cooperates with these stops consists of a pin (32) engaged in an opening (30). The mechanism is arranged in such a way that said finger, when the hour wheel is turned in the opposite direction to its normal direction, disappears in front of the next tooth of the crown.

The present invention aims to provide a safe drive system that is simple, efficient and reliable, by implementing a reduced number of components.

Disclosure of invention

More specifically, the invention relates to a drive system comprising: a board intended to receive an engine torque, a drive finger intended to transmit the driving torque received by the board, said drive finger being mounted free in rotation on the axis of the board, a drive pin arranged on the board so as to cooperate with the drive finger.

[0009] According to the invention, the pin is elastically movable and the pin and the drive finger are arranged so as to: connect the board and the drive finger in rotation when the board is driven in a first direction of rotation by the motor torque, cause an elastic displacement of the pin when the board is driven in a second direction of rotation by the motor torque and is subjected to a resistant torque able to move the pin, the elastic displacement allowing the pin to be positioned outside the travel of the finger coach.

Brief description of the drawings

Other details of the invention will appear more clearly on reading the description which follows, given with reference to the appended drawing in which FIGS. 1 to 5 relate to a first embodiment, with: FIG. 1 is an exploded view of the drive system according to this first embodiment, Figures 2, 3 and 4 are top views at three different times of the operating cycle, and Figure 5 is a perspective view of the drive system

Figures 6 to 10 relate to a second embodiment, with: FIG. 6 is an exploded view of the drive system according to this second embodiment, Figures 7 and 8 are top views at two different times of the operating cycle, and Figures 9 and 10 are respectively perspective and sectional views of the drive system.

Embodiment of the invention

In the present application, two main embodiments will be described, respectively with reference to Figures 1 to 5 and 6 to 10. The same references will be used for the elements in common between the two embodiments.

As can be seen in Figures 1 and 6, the drive system according to the invention comprises a plate 10 intended to receive a motor torque. This plate 10 is typically a toothed wheel, intended to be driven by a clockwork. If the drive system is intended to drive a date display, the plate 10 is typically driven at the rate of one revolution per 24 hours.

[0014] The drive system also comprises a drive finger 12 intended to transmit the motor torque received by the board 10 to a driven wheel 14. The drive finger 12 is rotatably mounted on the axis of the board 10. It comprises a tube 120, preferably screwed onto a barrel carrying the wheel, to be held in height, but those skilled in the art can adapt the assembly of the drive finger 12 on the board 10. The tube 120 is extended by a part in projection 122 extending radially and able to transmit a torque.

To connect the board 10 and the drive finger 12, the drive system further comprises a drive pin 100 arranged on the board 10 so as to cooperate with the drive finger 12.

According to the invention, the pin 100 is resiliently mounted.

[0017] More particularly, the pin 100 is mounted on an elastic arm 102 shaped in the thickness of the board 10. The board 10 can be cut to form the arm 102, at the end of which the pin 100 is fixed. edge of the board 10 formed by the cutout, defines a stop against which the arm 102 can rest, to limit its movements in the plane of the white. The gap between arm 102 and board 10 determines the maximum amplitude of movement of pin 100 in the plane of board 10, which is less than the maximum elastic deformation of arm 102.

The elastic arm 102 is preferably oriented substantially in the axis of the forces exerted by the pin 100 on the drive finger, so that the cooperation of the drive finger 12 and the pin 100, in the direction of training, essentially generates a tensile stress on the arm 102, in its longitudinal axis, and little or no elastic deformation.

More specifically, the projecting part 122 of the drive finger 12 has a drive flank 124, with which the pin 100 cooperates when the board 10 is driven in the first direction of rotation, represented by the arrow F. This first direction of rotation corresponds to normal drive through motion. The drive flank 124 has an edge arranged to provide tangential support to the pin 100.

More specifically to the examples illustrated, and in particular to Figures 2 and 7, the drive flank 124 has a concavity 126, or a rim defining a bearing zone oriented essentially radially. During the rotation of the board 10, the forces exerted by the pin 100 on the driving finger 12 are therefore essentially tangential, with respect to a circle centered on the center of rotation of the board 10 and of the driving finger 12, and passing through the point of contact between the pin 100 and the finger.

Opposed to the drive flank 124 with respect to the normal direction of rotation of the drive finger, the latter comprises a retraction flank 128 with which the pin 100 can cooperate when the board 10 is driven in the second direction of rotation. We will detail below the arrangement of the retraction side 128, which differs in the two illustrated embodiments.

However, in general, the pin 100 and the drive finger 12 are arranged so as to connect in rotation the board 10 and the drive finger 12 when the board 10 is driven in a first direction of rotation by the engine torque. This connection is made by the cooperation of the pin 100 and the drive side 124. The pin 100 and the drive finger 12 are also arranged so as to cause an elastic displacement of the pin 100 when the board 10 is driven in a second direction of rotation by the engine torque and is subjected to a resistive torque able to move the pin 100, the elastic movement making it possible to position the pin 100 outside the travel of the drive finger. The retraction is done by the cooperation of the pin 100 and the retraction flank 128. The resistant torque is typically transmitted by the driven wheel 14 which is locking the drive finger.

In the first embodiment illustrated in Figures 1 to 5, the drive system is characterized in that the pin 100 is elastically movable parallel to the plane of the board 10 and the possible amplitude of this movement allows the retraction of the pin 100. To do this, the retraction flank 128 comprises a milling 130 oriented to push the pin 100 and deform the elastic arm 102 in the plane of the board 10. The milling 130 amputates the drive finger 12 on a part of its height, greater than the pin 100. The milling 130 thus defines a guide wall and an opening in which the pin 100 can pass.

Thus, in normal operating mode, shown in Figure 2, the board 10 rotates counterclockwise. The pin 100 bears against the drive flank 124. The force induced by this bearing on the elastic arm 102 is essentially in traction in the axis of the arm 102 and almost without elastic deformation. If necessary, the periphery of the cutout of the board 10 provides a rigid support to limit the movements of the arm 102. The connection between the pin 100 and the drive finger 12 is almost rigid, in any case sufficient to allow the drive finger 12 to drive a driven mobile. If the driven mobile is positioned by a jumper, the stiffness of this jumper can also be taken into account to dimension the elastic arm 102 .

In case of correction carried out upside down, the board 10 rotates clockwise, as shown in Figure 3. The pin 100 bears against the retraction side 128. The finger driver 12 is blocked by driven wheel 14. More precisely, pin 100 passes under driver finger 12, being guided along the wall of milling 130, which moves it away from the axis of rotation of board 10 in constraining the elastic arm 102 which deforms (Fig. 4). After crossing the end of the milling 130, the pin 100 is brought back against the tube 120 of the drive finger 12 by the elastic return of the arm 102. It can then come back to rest against the drive flank 124 to drive the drive finger 12 .

In a second embodiment illustrated in Figures 6 to 10, the drive system is characterized in that the pin 100 is elastically movable transversely relative to the plane of the board 10. To do this, the side of retraction 128 comprises a bevel 140 oriented to push the pin 100 and deform the elastic arm 102 out of the plane of the board 10, in this case, on the side opposite the driving finger.

[0027] More particularly, the bevel 140 originates at the level of the retraction side 128, at a level higher than that of the pin 100, so that the latter comes into contact directly against the bevel 140, and not in the part right of the drive flank 124. The inclined plane of the bevel ends at the level of the underside of the drive finger, facing the board 10. The bevel 140 thus allows the retraction of the pin 100 below the drive finger 12 , without blocking. The inclination of the bevel can be adapted according to the elastic characteristics of the arm 102 and the resistance induced on the movement during retraction.

Thus, in normal operating mode, shown in Figure 7, the board 10 rotates counterclockwise. The pin 100 bears against the drive flank 124. The force induced by this bearing on the elastic arm 102 is essentially in traction in the axis of the arm 102 and almost without elastic deformation. If necessary, the periphery of the cutout of the board 10 provides a rigid support. The connection between the pin 100 and the drive finger 12 is almost rigid, in any case sufficient to allow the drive finger 12 to drive a driven mobile. If the driven mobile is positioned by a jumper, the stiffness of this jumper can also be taken into account to dimension the elastic arm 102 .

In case of correction carried out upside down, the board 10 rotates clockwise, as shown in Figure 8. The pin 100 comes to bear against the bevel of the retraction side 128, the drive finger being blocked against the driven wheel 14. The pin 100 then engages under the bevel 140. Consequently, this moves the end of the arm 102 away from the plane of the board 10 by elastically constraining it and deforming it outside of the plane of the board 10. After having reached the end of the bevel and crosses the edge of the projecting part 122 of the driving finger 12, the arm 102 returns elastically to the plane of the board 10. The pin 100 can then return to pressing against drive flank 124 to drive drive finger 12.

[0030] Thus, an advantageous solution is proposed for a unidirectional drive system, perfectly suited to a date drive. The solution according to the invention makes it possible, compared to the prior art, to reduce the number of components involved in the system and to simplify their assembly. In addition, the system is easier to dimension and there are fewer alterations to be made by the watchmaker.

Claims (8)

1. Drive system including: – a board (10) intended to receive a motor torque, – a drive finger (12) intended to transmit the motor torque received by the board (10), said drive finger (12) being mounted freely in rotation on the axis of the board (10), – a drive pin (100) arranged on the board (10) so as to cooperate with the drive finger (12), characterized in that the pin (100) is mounted elastically movable and in that the pin (100) and the drive finger (12) are arranged so as: – rotating the board (10) and the drive finger (12) when the board (10) is driven in a first direction of rotation by the motor torque, – cause an elastic displacement of the pin (100) when the board (10) is driven in a second direction of rotation by the motor torque and is subjected to a resistant torque able to move the pin (100), the elastic displacement making it possible to position the pin (100) outside the stroke of the drive finger (12). 2. Drive system according to claim 1, characterized in that the pin (100) is mounted on an elastic arm (102) shaped in the thickness of the board (10). 3. Drive system according to claim 2, characterized in that the pin (100) is resiliently movable parallel to the plane of the board (10). 4. Drive system according to claim 2, characterized in that the pin (100) is elastically movable transversely relative to the plane of the board (10). 5. Drive system according to one of the preceding claims, characterized in that the drive finger (12) has a drive flank (124), with which the pin (100) cooperates when the board (10) is driven. in the first direction of rotation, and a retraction flank (128) with which the pin (100) can cooperate when the board (10) is driven in the second direction of rotation. 6. Drive system according to the preceding claim, characterized in that the drive flank (124) has an edge arranged to provide tangential support, with respect to a circle centered on the axis of the board (10) and passing through the contact between the pin (100) and the drive flank (124). 7. Drive system according to claims 3 and 5, characterized in that the retraction flank (128) comprises a milling oriented to push the pin (100) and deform the elastic arm (102) in the plane of the board (10). 8. Drive system according to claims 4 and 5, characterized in that the retraction flank (128) comprises a bevel oriented to push the pin (100) and deform the elastic arm (102) out of the plane of the board (10).