阅读说明：本技术 具有弹性指针的钟表显示机构 (Timepiece display mechanism with elastic hands ) 是由 M·斯特兰兹 于 2021-05-27 设计创作，主要内容包括：具有弹性指针(1)的钟表显示机构(10),包括用于驱动在柔性叶片(3)的端部处同轴的条盒轮(2；4)的装置,包括具有包括输入齿(182)的输入框架(180)的差动机构,该输入框架自由旋转并且承载彼此啮合的中间轮(103)和行星轮(101),该行星轮(101)包括在固定凸轮(104)的轨道(105)上行进且通过弹性指针(1)的弹性而返回抵靠该轨道的偏心指状物(1010),输入框架(180)包括轴(185),该轴同轴地承载包括第一条盒轮(2)的第一分轮(1020)和包括第二条盒轮(4)的第二分轮(1040),第一分轮和第二分轮中的一个的齿(1049)与中间轮(103)的齿(1039)啮合,且第一分轮和第二分轮中的另一个的齿(1029)与行星轮机(101)的齿(1019)啮合。(Timepiece display mechanism (10) with elastic hands (1), comprising means for driving a barrel wheel (2; 4) coaxial at the end of a flexible blade (3), comprising a differential mechanism with an input frame (180) comprising input teeth (182), which rotates freely and carries an intermediate wheel (103) and a planet wheel (101) in mesh with each other, the planet wheel (101) comprising an eccentric finger (1010) which travels on a track (105) of a fixed cam (104) and is returned against the track by the elasticity of the elastic hands (1), the input frame (180) comprising a shaft (185) which coaxially carries a first minute wheel (1020) comprising a first barrel wheel (2) and a second minute wheel (1040) comprising a second barrel wheel (4), the teeth (1049) of one of the first and second minute wheels being in mesh with the teeth (1039) of the intermediate wheel (103), and the teeth (1029) of the other of the first and second partial wheels are meshed with the teeth (1019) of the planetary turbine (101).)

1. A variable geometry timepiece display mechanism (10) comprising at least one elastic hand (1) comprising a first driving barrel wheel (2) fixed to a first end of a flexible blade (3) and a second driving barrel wheel (4) fixed to the other end of the flexible blade (3), and comprising a display hand which, in an unconstrained free state of the elastic hand (1), is distanced from the first driving barrel wheel (2) and from the second driving barrel wheel (4), in which unconstrained free state neither the first barrel wheel (2) nor the second barrel wheel (4) are subjected to any stress and distanced from each other, the operating position of the display hand (1) being a constrained position in which the first driving barrel wheel (2) and the second driving barrel wheel (4) are coaxial to each other about an output axis (D), said display mechanism (10) comprising first driving means for driving said first reel (2) about said output axis (D) and second driving means for driving said second reel (4) about said output axis (D), said first and second driving means being arranged to deform said flexible blade (3), to vary the angular position of said second drive reel (4) with respect to the angular position of said first drive reel (2) about said output axis (D), and to vary the radial position of said display hand with respect to said output axis (D), characterized in that it comprises a differential-type mechanism comprising an input frame (180) mounted so as to rotate freely about said output axis (D), said input frame (180) comprising a first pivot (183) and a second pivot (181), the first and second pivots respectively carrying an intermediate wheel (103) and a planet wheel (101) meshing with each other by means of their teeth (1039; 1019), the planet wheel (101) comprising an eccentric finger (1010) arranged to travel on a track (105) of a fixed cam (104) and to return against the track (105) by the elasticity of the elastic fingers (1), the input frame (180) comprising an input tooth (182) and a shaft (185), the shaft (185) carrying coaxially along the output axis (D) a first partial wheel (1020) comprising the first partial wheel (2) and a second partial wheel (1040) comprising the second partial wheel (4), wherein the teeth (1049) of one of the first and second partial wheels mesh with the teeth (1039) of the intermediate wheel (103), and wherein the teeth (1029) of the other of the first and second partial wheels mesh with the teeth (1019) of the planet wheel (101).

2. The display mechanism (10) of claim 1 wherein the track (105) is an internal track.

3. The display mechanism (10) of claim 1 or 2 wherein the cam (104) is the only cam.

4. The display mechanism (10) according to any one of claims 1 to 3, characterized in that the cam (104) is arranged to sense information of the angle Δ θ to be applied, which is transmitted directly to the first minute wheel (1020) and indirectly to the second minute wheel (1040) via the intermediate wheel (103) to reverse the direction of the angle Δ θ to be applied to the first and second magazine wheels (2, 4) of the elastic pointer (1).

5. A display mechanism (10) according to claim 4, characterised in that the input frame (180) forming the planet wheel holder plate comprises a shaft (185) for guiding the first and second partial wheels (1020, 1040), an external toothing (182) or pinion for driving the first and second partial wheels through a timepiece movement, and a pivot (181; 183) for guiding the planet wheel (101) and the intermediate wheel (103), the planet wheel (101) comprising planet wheel teeth (1019) which mesh firstly with a first toothing (1029) of the first partial wheel (1020) and secondly with an intermediate toothing (1039) of the intermediate wheel (103), the intermediate toothing (1039) of the intermediate wheel (103) meshing with a second toothing (1049) of the second partial wheel (1040).

6. The display mechanism (10) according to any one of claims 1 to 5, characterised in that the planet (101) is the only planet carried by the input frame (180) forming a planet carrier plate and is arranged to sense a single said angle Δ θ on a single said cam track (105).

7. A timepiece movement (900) comprising at least one display mechanism (10) according to any one of claims 1 to 6, and arranged to drive the input frame (180).

8. Watch (1000) comprising at least one movement (900) according to claim 7 and/or at least one display mechanism (10) according to any one of claims 1 to 6.

Technical Field

The invention concerns a variable-geometry timepiece display mechanism comprising at least one elastic hand comprising a first driving barrel wheel fixed to a first end of a flexible blade and a second driving barrel wheel fixed to the other end of said flexible blade, and comprising a display hand which, in the unconstrained free state of said elastic hand, is remote from said first barrel wheel and from said second barrel wheel, wherein neither said first barrel wheel nor said second barrel wheel is subjected to any stress and is remote from each other, the operating position of said elastic hand being a stressed position in which said first barrel wheel and said second barrel wheel are coaxial to each other about an output axis, said display mechanism comprising means for driving said first barrel wheel about said output axis and second means for driving said second barrel wheel about said output axis, the first and second drive means are arranged to deform the flexible blade by changing the angular position of the second drum relative to the angular position of the first drum about the output axis and to change the radial position of the display pointer relative to the output axis.

The invention concerns a timepiece movement including at least one such display mechanism.

The invention relates to a watch comprising at least one such movement and/or at least one such display mechanism.

The present invention relates to the field of timepiece display mechanisms, and more particularly to a timepiece with a complex structure, which, due to the small dimensions of the mechanism according to the invention, can be used both for static timepieces (such as swinging watches and other watches) and for watches.

Background

For the user, good viewing of the display part on the timepiece is important.

The dial of many timepieces is not circular and it is advantageous to have available solutions so that the entire available surface can be occupied for better display.

The design of the variable geometry display mechanism makes it possible to break some monotony of the display and make the display more vivid, having a different appearance according to the time of day or according to a specific time period. For example, in a number of possible other applications, the AM/PM display may simply be provided in the form of a pointer having a first appearance during twelve hours of the morning and a second appearance during the rest of the day; it is also possible to distinguish between day/night displays, a spherical crescent display or others.

Disclosure of Invention

Resilient pointers and display mechanisms comprising such resilient pointers have been described in documents EP2863274, EP3159751 and EP3605244, which disclose many variants.

The present invention proposes to further simplify such a mechanism and to make it more compact and economical to produce.

The invention also proposes a wheel which prevents any abutment in the elastic pointer display mechanism, avoids pushing the wheel and is beneficial to traction and installation.

To this end, the invention relates to a variable-geometry timepiece display mechanism according to claim 1.

The invention concerns a timepiece movement including at least one such display mechanism.

The invention relates to a watch comprising such a movement and/or at least one such display mechanism.

Drawings

Other features and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which:

fig. 1 shows, schematically, partially and in exploded perspective view, a display mechanism according to the invention, limited to a not shown barrel wheel of an elastic hand; this mechanism comprises a differential-type mechanism carried by the planet-holder frame, and the assembly thus shown constitutes an additional unit that can be adapted to existing movements; the two barrel wheels of the elastic hands are here coaxial around a minute wheel arranged to constitute the output of such a movement;

fig. 2 shows the mechanism of fig. 1 schematically, partly and in assembled perspective, without the planet carrier plate;

figure 3 shows the mechanism of figure 2 schematically, partially and in side view;

fig. 4 shows schematically and in plan view an elliptical dial comprising such a display mechanism, in front of which a resilient pointer is moved, said pointer being shown in two different positions: in solid lines at twelve o 'clock, and in dashed lines at two o' clock;

figure 5 shows schematically, partially and in perspective view a display mechanism according to the invention, with an elastic cursor on its barrel wheel;

figure 6 shows, in a similar way to figure 4, an elliptical path associated with the tip of the elastic pointer;

figure 7 shows, in a similar way to figure 4, the path associated with the tip of the elastic cursor, which successively adopts the shape of an almond and a heart;

figures 8 and 9 show, in a similar way to figure 4, the position of the differential plate and the position of the arm of the elastic cursor, respectively at the noon of figure 8 and at the four o' clock of figure 9;

fig. 10 is a block diagram of a timepiece including a movement and such a display mechanism.

Detailed Description

Application EP3605244, which is incorporated herein by reference, relating to a variable geometry timepiece display mechanism with elastic hands, discloses a first mechanism actuated by a wheel with shaped teeth. Such an embodiment allows to realize a very innovative display in a timepiece, which is however expensive and reserved for luxury goods.

This same application describes yet another case of an actuating mechanism realized by a first differential on the train of first reel wheels and a second differential on the train of second reel wheels and at least one cam constituting the input of such a differential. Therefore, it is necessary to find and size a suitable (differential) planetary gear. Planetary gears have the advantage of achieving high gear ratios in a compact manner. The input and output axes are in line with each other. The possibilities of combining gears are very numerous. They make it possible in particular to produce gearboxes of interest. In this case, it is the case that one of the inputs to the differential is controlled to produce an equivalent lead and corresponding lag of a particular value at each end of the hands. And when this value is zero, a transmission ratio of 1 needs to be obtained (a positive value means that the direction must also be the same).

The invention proposes to further simplify the mechanism, making it more compact and more economical to produce. Particularly when the elastic hands are mounted on a small caliber, such as a lady watch, and additionally on the minute hand. The main difficulty is related to the small torque available. Thus, it is desirable to create a mechanism with the least possible energy consumption.

In order to redirect the normal operation of the differential, the invention proposes to control the planets. By mounting the feeler spindle in the planet wheel and controlling it by means of a circular cam, we obtain a gear ratio between the sun wheel and the frame carrying the planet wheel equal to one: the whole behaves as a wheel.

The circular cam of the present example is replaced by a cam of suitable shape so that the advance or retard we wish to obtain on the drum can be controlled thereafter. It should also be noted that this mechanism does not have a return spring to maintain the feeler spindle in contact on the cam, since it is the elastic pointer that performs this function.

The invention proposes to avoid any abutment phenomena, to avoid the use of wheels to be pushed, in particular planet wheels, and to facilitate the use of traction sheaves.

The particular actuation of the hands involves referencing the planetary gripper plate of the differential in order to operate each hand drum symmetrically. Fig. 8 and 9 show the rotation angle to be applied to the barrel wheels 2 and 4 of the hand 1. In fig. 8, pointer 1 represents noon: line a shows the position of the differential plate, which in this non-limiting example rotates at a rate of 1 revolution per hour, and lines B and C represent the position of the arm of the pointer 1. In fig. 9, hand 1 represents four o 'clock, hand a of the differential plate points to the mark at four o' clock on the dial, and each arm B, C has the same angular theta of advance and symmetrical retraction relative to the planet carrier.

To this end, the invention concerns more particularly a variable-geometry timepiece display mechanism 10, comprising at least one elastic hand 1.

Such resilient fingers and display mechanisms comprising such resilient fingers are described in documents EP2863274, EP3159751, EP3605244 and EP3605243, which are incorporated herein by reference, and which disclose many variations.

The elastic hand comprises a first driving barrel wheel 2 fixed at a first end of the elastic blade 3 and a second driving barrel wheel 4 fixed at the other end of the elastic blade 3.

The flexible blade 3 may be a continuous blade or a blade comprising a series of segments 5 connected two by two at the tip 6, as shown in figures 5 and 6.

The elastic blade 3 comprises a display hand which, in the unconstrained free state of the elastic hand 1, is distanced from the first and second cartwheel 2, 4, wherein neither the first cartwheel 2 nor the second cartwheel 4 is subjected to any stress and distanced from each other, the operating position of the elastic hand 1 being the constrained position, wherein the first cartwheel 2 and the second cartwheel 4 are coaxial with each other about the output axis D. In particular, in the variant comprising connected segments 5, the display pointer is advantageously, but not necessarily, formed by a tip 6.

The display mechanism 10 comprises first means for driving the first reel 2 about the output axis D and second means for driving the second reel 4 about the output axis D.

Variants in which the first cartwheel 2 and the second cartwheel 4 are not described here, which are still realizable for certain special displays, in particular displays of the non-swivel type (for example, rebound or similar displays).

The first and second drive means are arranged to: by varying the angular position of the second drum 4 about the output axis D with respect to the angular position of the first drum 2, the flexible blade 3 is deformed and the radial position of the display hand with respect to the output axis D is varied.

In accordance with the present invention, display mechanism 10 comprises a differential-type mechanism including an input frame 180 mounted for free rotation about an output axis D. The input frame 180 comprises a first pivot 183 and a second pivot 181 carrying respectively an intermediate wheel 103 and a single planet wheel 101, which mesh with each other via their teeth 1039, 1019. The planet 101 comprises an eccentric finger 1010 which is arranged to travel on the track 105 of the fixed cam 104 and which is returned against this track 105 by the elasticity of the elastic hands 1 themselves. The input frame 180 comprises input teeth 182 and/or a drive pinion, and a shaft 185 which coaxially carries, on the output axis D, a first cannon pinion 1020 comprising a first barrel 2 and a second cannon pinion 1040 comprising a second barrel 4, wherein the teeth 1049 of one of the first and second cannon pinions mesh with the teeth 1039 of the intermediate wheel 103, and wherein the teeth 1029 of the other of the first and second cannon pinions mesh with the teeth 1019 of the planet wheels 101.

More particularly, and as can be seen in the specific and non-limiting variant shown, the track 105 is an internal track.

Therefore, the present invention simplifies the structure by using a single cam that senses the information of the angle Δ θ to be applied. This information is transmitted directly to the first minute wheel 1020. The second minute wheel 1040 receives this information via the intermediate wheel 103, which reverses the direction of the angle Δ θ to be applied, as shown in fig. 2 and 3: the single planet 101 carried by the planet-holder plate 180 senses, on the single cam track 105 presented by the flange 104 constituting the cam, the single angle Δ θ to be applied to the two barrel wheels 2 and 4 of the hand 1.

The planet 101 applies rotation directly to the first partial wheel 1020 carrying the first magazine wheel 2. For the second minute wheel, the planet 101 transmits the rotation through the intermediate wheel 103 to the second minute wheel 1040 carrying the second barrel wheel 4, so as to reverse the direction of rotation.

The planet 101 carries a finger 1010 that senses the cam track 105.

The planet-holder plate 180 here comprises a shaft 185 for guiding a minute wheel 1040 and indirectly the minute wheel 1020, external teeth 182 driven by the timepiece movement, and pivots 181 and 183 which guide the planet 101 and the intermediate wheel 103. The teeth 1019 of the planet wheels 101 mesh firstly with the teeth 1029 of the first partial wheel 1020 and secondly with the teeth 1039 of the intermediate wheel 103, which teeth 1039 mesh with the teeth 1049 of the second partial wheel 1040.

Figure 3 shows that the mechanism is very compact, with a slight thickness enabling it to be housed in a small watch case. The number of components is reduced and none have any particular design complexity, so the overall cost is moderate.

The invention also concerns a timepiece movement 900 including at least one such display mechanism 10.

The invention also relates to a watch 1000 comprising at least one such movement 900 and/or at least one such display mechanism 10.

In short, the invention makes it possible to produce an advance and/or a delay on the two drums of the elastic hands, making it possible to produce complex paths, which are as a whole implemented in a very simple and compact manner, are economical in terms of torque and therefore have a high reliability.

This arrangement with a single planet wheel and a single cam does have advantages. The additional dial is very simple. And a single planet wheel is dragged and installed and cannot be abutted clockwise. The energy consumption is low due to the reduced friction. The amplitude loss at the resonator is very small. The mechanism includes fewer parts, is compact and is easy to assemble.