CH719020B1 - Actuation mechanism for a flexible display needle driven by a clockwork movement. - Google Patents

Abstract

The present invention relates to an actuation mechanism (1) for a flexible display needle (20), this mechanism (1) being arranged to be moved by a clockwork movement, the flexible display needle (20) comprising a first drive barrel (16) connected to a first end of a first flexible arm (46), and a second drive barrel (18) connected to a first end of a second flexible arm (48), the first and second flexible arms (46, 48) being connected together at their second end by a tip (50), the first and second barrels (16, 18) being spaced apart from each other in a non-free state constrained position of the flexible display needle (20), an operating position in which the flexible display needle (20) has a defined shape and length being a constrained position in which the first barrel (16) and the second drive barrel (18) are arranged coaxially around an axis of rotation (D1), the first barrel (16) being mounted with a defined first preload angle, and the second barrel (18) being mounted with a second preload angle defined in a direction opposite to that of the first drive barrel (16), the mechanism (1) being arranged to drive the flexible display needle (20) in rotation and control its change in length, a first differential mechanism (2) of the actuation mechanism (1) comprising a first input to which the clockwork applies an angular rotation of angle θ1 which determines the rotation of the flexible display needle (20) thereon -same, this angular rotation θ1 being also applied with a gear ratio to a first input of a second differential mechanism (4) of the actuation mechanism (1), an angular rotation θ2 which determines a change in length of l the flexible display needle (20) being applied to a second input of the second differential mechanism (4), an output of the second differential mechanism (4) which controls the change in length of the flexible display needle (20) being applied to a second input of the first differential mechanism (2), an output of the first differential mechanism (2) driving the flexible display needle (20) to rotate and controlling its change in length.

Description

Technical field of the invention

[0001] The present invention relates to an actuation mechanism for a flexible display hand, this actuation mechanism being arranged to be moved by a clockwork movement of a watch.

Technology background

[0002] In the recent past, the Applicant has already disclosed a certain number of actuation mechanisms for flexible display hands. Such actuating mechanisms are arranged to rotate a flexible display needle on itself while controlling its change of shape and length in order to display time or other information in an original manner.

[0003] The development of such actuation mechanisms, however, requires fairly complex calculations in order to obtain the desired result in terms of speed of rotation and change of shape of the flexible display needle. On the other hand, these actuation mechanisms also have the disadvantage of freezing the trajectory of the flexible needle: in other words, the length of the needle is linked to its position.

Summary of the invention

[0004] The present invention aims to meet the need mentioned above as well as others by providing a mechanism for actuating a flexible display needle making it possible to define the movement of a needle of flexible display as well as its shape and length changes independently of each other.

[0005] To this end, the present invention relates to an actuation mechanism for a flexible display needle, this actuation mechanism being arranged to be moved by a clockwork movement, the flexible display needle comprising a first drive barrel connected to a first end of a first flexible arm, and a second drive barrel connected to a first end of a second flexible arm, the first and second flexible arms being connected together at their second end by a tip, the first and second drive barrels being spaced apart from each other in a free, unconstrained state of the flexible display needle, an operating position in which the flexible display needle has a defined shape and length being a constrained position in which the first drive barrel and the second drive barrel are arranged coaxially around an axis of rotation, the first drive barrel being mounted at a first angle defined preload, and the second drive barrel being mounted with a second defined preload angle in the opposite direction to that of the first drive barrel, the actuation mechanism being arranged to drive the flexible display needle in rotation and control its change in length, a first differential mechanism of the actuation mechanism comprising a first input to which the clockwork applies an angular rotation which determines the rotation of the flexible display needle on itself, this rotation angular also being applied with a gear ratio to a first input of a second differential mechanism of the actuation mechanism, a phase shift angular rotation which determines a change in length of the flexible display needle being applied to a second input of the second differential mechanism, an output of the second differential mechanism which controls the change in length of the flexible display needle being applied to a second input of the first differential mechanism, an output of the first differential mechanism driving the display needle flexible in rotation and controlling its change in length.

[0006] Thanks to these characteristics, the present invention provides an actuation mechanism for a flexible display needle whose mechanisms for driving this flexible display needle in rotation on the one hand, and for controlling the its change in length on the other hand, due to the fact that they are of the differential type, can be dissociated, which allows much greater freedom in the definition of the trajectory of the flexible display needle and in the choice of its shape and length. Thus, thanks to the dissociation of the functions of driving rotation and changing the shape and length of the flexible display needle, the actuation mechanism according to the invention makes it possible, in a remarkable manner, to display two distinct pieces of information using a single flexible display needle. Indeed, like any differential type mechanism, the first differential mechanism of the actuation mechanism according to the invention comprises two inputs and an output, a first input receiving an angular rotation applied by the clockwork movement which ensures the rotation of the flexible display needle on itself, the second input receiving the command to control the change in length of the flexible display needle, and the output ensuring the driving of the latter. As for the second differential mechanism of the actuation mechanism according to the invention, one of its inputs receives, through a gear ratio, the angular rotation applied to the first differential mechanism by the clockwork movement, its second input receives a phase shift angular rotation applied by the clockwork movement which determines the change in length of the flexible display needle, and its output applies the length change command to the needle and to the second input of the first differential mechanism of the flexible display needle. The actuation mechanism thus comprises two inputs independent of each other, one controlling the rotation of the flexible display needle, while the other controls the length of the latter. Thus, by way of non-limiting example only, the rotation of the flexible display hand can be used to display the current time, while the change in length can be programmed to occur at the time of triggering of 'an alarm bell. This result can be achieved by connecting the second input of the actuating mechanism which controls the length of the flexible display needle to an alarm mobile, for example the regulator.

[0007] Other particular embodiments of the invention are the subject of the dependent claims.

Brief description of the figures

[0008] Other characteristics and advantages of the present invention will emerge more clearly from the following detailed description of an embodiment of a mechanism for actuating a flexible display needle according to the invention, this example given for purely illustrative and non-limiting purposes only in connection with the appended drawing in which: - Figure 1 is an elevational view of an embodiment of a mechanism for actuating a display needle flexible according to the present invention; – Figure 2 is a perspective view and in the dissociated state of the actuation mechanism according to the invention illustrated in Figure 1; – Figure 3 is a top view in the unmounted state of a flexible display needle intended to be driven by the actuation mechanism according to the invention; – Figure 4 illustrates a particular embodiment of the invention in which the differential ring gear is provided with a cam follower finger by which it bears against the profile of the cam.

Detailed description of the invention

[0009] The present invention proceeds from the general inventive idea which consists of providing an actuation mechanism for a flexible display needle comprising a first and a second differential mechanism, the first differential mechanism, receiving an angular rotation applied by the clockwork movement, ensuring the rotation of the flexible display needle on itself, while the second differential mechanism, kinematically connected to the first differential mechanism with a gear ratio, receives an angular phase shift rotation applied by the clockwork movement or by the user, for example by actuation of a push button, which determines a change in length of the flexible display needle. Thus, the mechanism for actuating the flexible display needle according to the invention comprises two inputs independent of each other, one for the rotation of the flexible display needle and the other for the change in length of this flexible display needle, which makes it possible to dissociate the rotation function of the needle and the function of changing the shape and length of the latter and therefore to offer manufacturers great freedom in the determination of the trajectory of the needle.

[0010] An embodiment of the actuation mechanism according to the invention is illustrated in Figure 1. Designated as a whole by the general numerical reference 1, this actuation mechanism consists of a first and a second differential mechanism designated respectively by the numerical references 2 and 4.

The first differential mechanism 2, centered on a first axis of rotation D1, is carried by a first satellite carrier wheel 6 to which a clockwork movement applies an angular rotation of angle θ1. This first differential mechanism 2 comprises a first solar pinion 8 and a first solar mobile 10 mounted freely in rotation coaxially on the first solar pinion 8. This first solar mobile 10 comprises a second solar pinion 12 and a first sun wheel 14 fixedly mounted on the second sun gear 12. As will be seen in detail below, the first sun gear 8 plays the role of first roadway and the second sun gear 12 plays the role of second roadway for the first and second drive guns 16 and 18 a flexible display needle 20.

The second differential mechanism 4, centered on a second axis of rotation D2, is carried by a second planet carrier wheel 22 which is driven by the first planet carrier wheel 6. This second differential mechanism 4 comprises a second solar mobile 23 formed of a third sun gear 24 and a second sun wheel 25 which is engaged with the first sun wheel 14 of the first differential mechanism 2. This second differential mechanism 4 also comprises a differential ring gear 26 centered on the third pinion solar 24. This differential ring 26 is provided with internal teeth 28A and external teeth 28B. At least one satellite pinion 30 (three satellite pinions spaced 120° apart from each other in the example shown) rolls on the internal teeth 28A of the differential ring gear 26 and meshes with the third sun pinion 24. The second differential mechanism 4 further comprises a rake 32 provided with a toothed sector 34 by which it engages with the external teeth 28B of the differential crown 26. At its other end opposite the toothed sector 34, the rake 32 carries a cam follower finger 36 by which it follows a profile 38 of a rotating cam 40.

[0013] As already mentioned above, the energy necessary for the operation of the actuating mechanism 1 according to the invention is supplied to it by a clockwork movement which applies to the first planet carrier wheel 6 of the first differential mechanism 2 an angular rotation θ1. Thus driven by the clockwork movement, the first satellite wheel 6 in turn drives the first differential mechanism 2 in rotation on itself. More precisely, the first planet carrier wheel 6 rotates the first sun pinion 8 which, itself, rotates the second sun pinion 12 and therefore the first sun wheel 14 via first and second references 42 and 44. therefore understands that the rotation of the first satellite wheel 6 ensures the rotation and angular positioning of the flexible display needle 20.

[0014] Likewise, the first planet carrier wheel 6 rotates the second planet carrier wheel 22. By rotating, the second planet carrier wheel 22 rotates the planet gear(s) 30. These planet gears 30 roll on the internal teeth 28A of the differential ring gear 26 and in turn drive in rotation, via the third sun pinion 24, the second sun wheel 25 which is engaged with the first sun wheel 14 of the first differential mechanism 2.

[0015] Simultaneously, the clockwork applies to the rotating cam 40 an angular rotation of angle θ2 which will determine the length of the flexible display needle 20. In fact, by rotating, the rotating cam 40 causes the pivoting of the rake 32 which, by pivoting the differential crown 26, makes it possible to adjust the length of the flexible display needle 20 by adjusting the relative position of the drive barrels 16, 18 of the display needle flexible display 20 through the kinematic chain formed by the satellite gears 30, the third sun gear 24, the second sun wheel 25, the first solar mobile 10 and the first sun gear 8.

The first differential mechanism 2 ensures the rotation of the flexible display needle 20, without change in length. In the hypothesis where the rotating cam 40 would be stationary (in other words, θ2=0), the first sun pinion 8 and the first solar mobile 10 would rotate at the same speed because the gear ratio is calculated so that, in this case , the speed of the first planet carrier wheel 6 is equal to the speed of the first sun pinion 8 and the first solar mobile 10 which constitute the first and second roadways on which the first and second drive guns 16, 18 of the flexible display needle 20.

The second differential mechanism 4 ensures the change in length of the flexible display needle 20, without rotation of the latter. In the hypothesis where the first satellite wheel 6 would be stationary (in other words, θ1=0), the first solar pinion 8 and the first solar mobile 10 would rotate at the same speed but in opposite directions relative to each other. 'other, corresponding to the phase shift.

[0018] It will be noted that there cannot be a blocking situation between the first differential mechanism 2 and the second differential mechanism 4 because the actuation mechanism 1 as a whole is arranged so that the first sun wheel 14 and the second sun wheel 25 rotate at the same tooth frequency when the rotating cam 40 is stationary (in other words, θ2=0).

Designated as a whole by the general numerical reference 20, the flexible display needle capable of being driven by an actuation mechanism 1 according to the invention is illustrated in Figure 3. This flexible display needle 20 comprises a first drive barrel 16 connected to a first end of a first flexible arm 46, and a second drive barrel 18 connected to a first end of a second flexible arm 48. At their second end, the first and second flexible arms 46 and 48 are interconnected by a tip 50. In a free, unconstrained state of the flexible display needle 20 illustrated in Figure 3, the first and second drive barrels 16, 18 are spaced apart one of the other.

Conversely, a service position in which the flexible display needle 20 has a defined shape and length is a constrained position in which the first drive barrel 16 and the second drive barrel 18 are arranged in coaxially around the axis of rotation D1 (see figure 1). In this constrained position, the first drive barrel 16 is mounted with a first defined preload angle, and the second drive barrel 18 is mounted with a second defined preload angle in the opposite direction to that of the first drive gun. 16. The flexible display needle 20 is arranged to change shape and length in a desired manner when the angular position of the second drive barrel 18 varies relative to the angular position of the first drive barrel 16 by pivoting around the axis of rotation D1.

[0021] It goes without saying that the present invention is not limited to the embodiment which has just been described and that various simple modifications and variants can be envisaged by those skilled in the art without departing from the scope of the invention. as defined by the appended claims. In particular, it will be understood that by the length of the flexible display needle 20, we mean the radius R which passes between the two drive barrels 16, 18 and through the tip 50 of this flexible display needle 20. will also note that, in the case where the rotating cam 40 is not driven by the clockwork movement, a control member can be considered, for example a push button, operable by the user from outside the the watch case and controlling a change in position of the cam, which has the effect of changing the length of the flexible display needle 20. In effect, by moving the cam from a first to a second different position of the first, this has the effect of changing the phase shift ϕ between the flexible arms 46, 48 of the flexible display needle 20 and therefore the length of the latter. Then, as the position of the cam remains unchanged, the flexible display needle 20 will only rotate on itself, without changing length. By modifying the length of the flexible display needle 20, it is thus possible, for example, to bring the tip 50 of this flexible display needle 20 opposite one or the other of two distinct graduations, and therefore to display the values of two different parameters. Thus, for example, the angle formed by the flexible display needle 20 with its initial position can be used to provide the indication of the current time, while the length and/or shape of the needle d The flexible display 20 will provide the user with an indication relating to the power reserve of the watch. first and second references (42, 44). Figure 4 illustrates a particular embodiment of the invention in which the differential ring 26 is provided, on its outer perimeter which, in this case, is devoid of teeth, with a cam follower finger 52 by which it rests against profile 38 of cam 40.

Nomenclature

[0022] 1 Actuation mechanism 2 First differential mechanism 4 Second differential mechanism D1 First axis of rotation 6 First planet carrier wheel θ1 Angular rotation of the first planet carrier wheel 8 First sun pinion 10 First solar mobile 12 Second sun pinion 14 First sun wheel 16 First drive barrel 18 Second drive barrel 20 Flexible display needle D2 Second axis of rotation 22 Second planet carrier wheel 23 Second solar mobile 24 Third sun pinion 25 Second sun wheel 26 Differential ring gear 28A Toothing internal 28B External teeth 30 Planet gear 32 Rake 34 Toothed sector 36 Cam follower finger 38 Profile 40 Rotating cam 42 First gear 44 Second gear θ2 Angular rotation of the rotating cam ϕ Angular phase shift between the first sun gear and the second sun gear 46 First flexible arm 48 Second flexible arm 50 Tip 52 Cam follower finger

Claims (15)

1. Actuation mechanism (1) for a flexible display needle (20), this actuation mechanism (1) being arranged to be moved by a clockwork movement of a watch, the display needle flexible arm (20) comprising a first drive barrel (16) connected to a first end of a first flexible arm (46), and a second drive barrel (18) connected to a first end of a second flexible arm (48), the first and second flexible arms (46, 48) being connected together at their second end by a tip (50), the first and second drive barrels (16, 18) being spaced apart from one another other in a free, unconstrained state of the flexible display needle (20), an operating position in which the flexible display needle (20) has a defined shape and length being a constrained position in which the first drive barrel (16) and the second drive barrel (18) are arranged coaxially around an axis of rotation (D1), the first drive barrel (16) being mounted with a first angle of defined preload, and the second drive barrel (18) being mounted with a second defined preload angle in the opposite direction to that of the first drive barrel (16), the actuation mechanism (1) being arranged to drive the flexible display needle (20) in rotation and controlling its change in length, a first differential mechanism (2) of the actuation mechanism (1) comprising a first input to which the clockwork applies an angular rotation of angle θ1 which determines the rotation of the flexible display needle (20) on itself, this angular rotation θ1 also being applied with a gear ratio to a first input of a second differential mechanism (4) of the mechanism actuation (1), an angular rotation θ2 which determines a change in length of the flexible display needle (20) being applied to a second input of the second differential mechanism (4), an output of the second differential mechanism (4 ) which controls the change in length of the flexible display needle (20) being also applied to a second input of the first differential mechanism (2), an output of the first differential mechanism (2) driving the flexible display needle (20) rotating and controlling its change in length. 2. Actuation mechanism (1) for a flexible display needle (20) according to claim 1, characterized in that the first differential mechanism (2), centered on a first axis of rotation (D1), is carried by a first planet carrier wheel (6) to which the clockwork applies angular rotation of angle θ1. 3. Actuation mechanism (1) for a flexible display needle (20) according to claim 2, characterized in that the first differential mechanism (2) comprises a first solar pinion (8) and a first solar mobile (10 ) mounted free to rotate coaxially on the first solar pinion (8). 4. Actuation mechanism (1) for a flexible display needle (20) according to claim 3, characterized in that the first solar mobile (10) comprises a second sun pinion (12) and a first sun wheel (14). ) fixedly mounted on the second sun gear (12). 5. Actuating mechanism (1) for a flexible display needle (20) according to claim 4, characterized in that the first sun gear (8) is a first roadway and the second sun gear (12) is a second floor for the first and second drive guns (16, 18) of the flexible display needle (20). 6. Actuation mechanism (1) for a flexible display needle (20) according to one of claims 4 and 5, characterized in that the second differential mechanism (4), centered on a second axis of rotation (D2 ), is carried by a second planet carrier wheel (22) which is driven by the first planet carrier wheel (6) according to said gear ratio. 7. Actuating mechanism (1) for a flexible display needle (20) according to claim 6, characterized in that the second differential mechanism (4) comprises a second sun wheel (25) which is engaged with the first sun wheel (14) of the first differential mechanism (2). 8. Actuation mechanism (1) for a flexible display needle (20) according to claim 6, characterized in that the second differential mechanism (4) comprises a differential ring (26) centered on a third sun pinion ( 24), this differential ring gear (26) being provided with internal teeth (28A) and external teeth (28B), at least one satellite pinion (30) rolling on the internal teeth (28A) and meshing with the third sun pinion (24), this second differential mechanism (4) also comprising a rotating cam (40) provided with a profile (38) which, by rotating, will make it possible to determine the length of the flexible display needle ( 20). 9. Actuating mechanism (1) for a flexible display needle (20) according to claim 8, characterized in that the second differential mechanism (4) comprises a rake (32) provided with a toothed sector (34) by which it is engaged with the external teeth (28B) of the differential ring (26), at its other end opposite the toothed sector (34), the rake (32) carrying a cam follower finger (36) by which it rests against the profile (38) of the cam (40). 10. Actuation mechanism (1) for a flexible display needle (20) according to claim 9, characterized in that, when the clockwork applies to the rotating cam (40) an angular rotation of angle θ2 which determines the length of the flexible display needle (20), the rotating cam (40), by rotating, causing the pivoting of the rake (32) which, by rotating the differential ring (26), allows to adjusting the length of the flexible display needle (20) by adjusting the relative position of the drive barrels (16, 18) of the flexible display needle (20) through the kinematic chain formed by the at least one satellite pinion (30), the second solar mobile (23), the first solar mobile (10) and the first solar pinion (8). 11. Actuation mechanism (1) for a flexible display needle (20) according to claim 10, characterized in that, in the event that the rotating cam (40) is stationary, the first sun pinion (8) and the first solar mobile (10) rotate at the same speed because the gear ratio is calculated so that, in this case, the speed of the first planet carrier wheel (6) is equal to the speed of the first sun pinion ( 8) and the first solar mobile (10) which constitute the first and second roadways on which the first and second drive guns (16, 18) of the flexible display needle (20) are fixed. 12. Actuating mechanism (1) for a flexible display needle (20) according to claim 10, characterized in that, in the event that the first planet carrier wheel (6) is stationary, the first sun pinion (8) and the first solar mobile (10) rotate at the same speed but in opposite directions relative to each other, corresponding to the phase shift ϕ. 13. Actuation mechanism (1) for a flexible display needle (20) according to one of claims 9 to 12, characterized in that it comprises a control member operable by a user from outside the watch and which, in the case where the cam (40) is not driven by the watch movement, makes it possible to control a change in position of the cam (40), which has the effect of changing the length of the flexible display needle (20) by changing the phase shift ϕ between the flexible arms (46, 48) of the flexible display needle (20), the position of the cam (40) then remaining unchanged, the needle flexible display (20) rotating on itself, without changing length. 14. Actuating mechanism (1) for a flexible display needle (20) according to one of claims 3 to 13, characterized in that the first planet carrier wheel (6) rotates the first sun pinion ( 8) which rotates the second sun pinion (12) and the first sun wheel (14) via first and second references (42, 44). 15. Actuating mechanism (1) for a flexible display needle (20) according to claim 8, characterized in that the differential crown (26) is provided with a cam follower finger (52) by which it is supported against the profile (38) of the cam (40).