CH715246B1 - A display device comprising a movable indicator moving along a predefined path. - Google Patents

Abstract

The display device according to the invention comprises a rotary drive member (125) and a movable indicator (103) comprising a pivot (105) perpendicular to a main display plane of the device and arranged to be driven by the rotatable drive member so as to move along a predefined path. The mobile indicator also comprises at least two eccentric columns (107a, 107b, 107c, 107d) which are oriented parallel to the pivot, and the display device comprises a slider which extends parallel to the main display plane, the slider being provided to guide the eccentric column so as to determine the orientation of the mobile indicator when its pivot moves along the predefined path. The mobile indicator (103) is arranged to adopt different orientations, depending on whether one or the other of the eccentric columns (107a, 107b, 107c, 107d) is guided by the slide. In addition, the slide has at least one intersection (116a) comprising a baffle (117) associated with an opening in the slide, the baffle being arranged to deflect the trajectory of one of the eccentric columns during the movement of the mobile indicator , so as to rotate the mobile indicator on itself sufficiently so that, after passing the intersection, the eccentric column which is guided by the slide is no longer the same eccentric column.

Description

The present invention relates to a display device, in particular for a timepiece, comprising a rotary drive member arranged to rotate around an axis perpendicular to a main display plane of the display device, and a mobile indicator comprising a pivot perpendicular to the main display plane and arranged to be driven by the rotary drive member so as to move along a predefined path while rotating around the axis integrally with the rotary drive member.

PRIOR ART

[0002] Patent document CH 709 035 B1 describes a timepiece equipped with an unconventional time display. In fact, according to this document, the timepiece indicates the hours by means of a rotating disc which includes an off-center window. This window is arranged to rotate above an hour circle comprising twelve mobile indicators numbered from 1 to 12 and which are regularly distributed around a circle concentric with the rotating disc.

[0003] In accordance with this known document, the time setting of the hour indication is not done by adjusting the angular position of the rotary disk, but is done on the contrary by pivoting a disk-shaped support on which are fitted with the twelve mobile indicators forming the hour circle. Each of the twelve mobile indicators is mounted on a pivot integral with a pinion rotatably mounted on the disc-shaped support. The mobile indicators are kinematically connected to each other by belts, and are further connected to a fixed central wheel via at least one intermediate mobile so that the mobile indicators always keep the same orientation when, to set the time, the disc-shaped support on which they are mounted is rotated. It will be understood that thanks to the characteristics which have just been described, it is possible to ensure that the numbers from 1 to 12 carried by the twelve mobile indicators always remain oriented in the direction of reading, even after being switched on. hour.

[0004] In accordance with this prior solution, the 12 mobile indicators are not independent, but are interconnected through gears. A disadvantage of this type of construction is that it is difficult to adapt to ways of indicating the time which are even slightly different. For example, we do not see how it could be used to indicate the hours by means of a single mobile indicator rotating around the dial.

BRIEF DESCRIPTION OF THE INVENTION

An object of the present invention is to remedy the drawbacks of the prior art which have just been explained. The present invention achieves this and other objects by providing a display device according to appended claim 1.

[0006] According to appended claim 1, the display device has a “main display plane”. Conventionally, such a main display plane can be materially produced in the form of a dial. It will however be understood that alternatively, the existence of the main display plane could only be geometric, and designate a spatial orientation according to which the indications provided by the display device are organized.

According to the invention, the mobile indicator comprises at least two eccentric columns which are angularly spaced around the pivot. It will be understood that, thanks to this characteristic, the mobile indicator can have at least two distinct orientations relative to the direction of the slide, depending on whether it is one or another of the at least two eccentric columns which is engaged in the slide.

Still according to the invention, the slide has at least one intersection comprising a baffle and at least one opening associated with the baffle. The baffle is arranged to deflect the trajectory of one of the eccentric columns during the movement of the mobile indicator along the predefined path. It will be understood that thanks to this characteristic, when the direction of movement of the mobile indicator is substantially parallel to the slide and that the baffle forces one of the eccentric columns of the mobile indicator to deviate from its trajectory, the entire mobile indicator changes orientation by rotating.

[0009] When the mobile indicator pivots, it causes in particular all of the at least two eccentric columns to be shifted together, each following a path in an arc of a circle around the pivot. In addition, still in accordance with the invention, the slide is arranged so that, when an eccentric column meets a baffle, the value of the pivot angle of the mobile indicator relative to the direction of the slide corresponds the angular offset required for a second of the at least two eccentric columns to take the place in the slide of a first of the at least two eccentric columns, to be guided by the slide.

BRIEF DESCRIPTION OF FIGURES

Other characteristics and advantages of the present invention will appear on reading the following description, given solely by way of non-limiting example, and made with reference to the accompanying drawings in which: FIGS. 1A and 1B are perspective views respectively showing the top and bottom of the mobile indicator of a display device according to a first particular embodiment of the invention; FIG. 2 is a partial schematic top plan view showing the cooperation between the mobile indicator and the slide of the particular display device, to which the mobile indicator illustrated in FIGS. 1A and 1B belongs. Figure 3 is a schematic plan view similar to that of Figure 2, but still showing the rotary drive member. FIGS. 4A and 4B are perspective views respectively showing the top and bottom of the mobile indicator of a display device according to a second particular embodiment of the invention; FIG. 5 is a partial schematic top plan view showing the cooperation between the mobile indicator illustrated in FIGS. 4A and 4B and the slide of the display device of which it forms part; FIG. 6 is a general plan view from above showing schematically the mobile indicators, the slideway and the rotary drive member of the display device which is partially illustrated in FIG. 5; FIG. 7 is an enlarged partial view taken from FIG. 6 and showing the same portion of the display device as FIG. 5, FIG. 7 differing from FIG. further represented; FIG. 8 is a general plan view from above of the display device of FIGS. 4A, 4B, 5, 6 and 7, the mobile indicators being illustrated each capped with a patch bearing a number; Figure 9 is a partial schematic view similar to Figure 7, but showing the mobile indicators capped with their pad. FIGS. 10A to 10F illustrate a sequence of six successive instants in the cooperation between the lug carried by a baffle and one of the notches present in the circumference of the disc of one of the mobile indicators.

DETAILED DESCRIPTION OF EMBODIMENTS

Figures 1A, 1B, 2 and 3 are partial views which show different parts of a display device according to a first particular embodiment of the invention. The perspective views of Figures 1A and 1B respectively show the top and bottom of the mobile indicator of the display device. As shown in the figures, the mobile indicator 3 is essentially formed of a pivot 5 and of a disc 6 carried by the pivot in a concentric position. It can also be seen that two eccentric columns (referenced 7a and 7b) protrude from the lower surface of disc 6 (FIG. 1B). These columns are angularly spaced along the same circle concentric with the pivot 5 and they extend parallel to the latter. Referring more particularly to FIG. 1B, it can also be noted that, on the one hand, the length of the part of the pivot 5 which protrudes under the disc 6 substantially exceeds that of the two eccentric columns 7a and 7b, and that d On the other hand, the central angle which is subtended by the columns 7a and 7b is 90°. It is worth specifying however that according to other variants or embodiments, the angle subtended by the columns could be different from 90°. FIGS. 1A and 1B still show two symmetrical notches (referenced 9a and 9b) which are arranged on the edge of disc 6 in diametrically opposite positions. It can be seen that the two eccentric columns 7a and 7b and the two notches 9a and 9b are arranged symmetrically with respect to the same axis of symmetry which coincides with a diameter of the disc 6. It will further be specified that the mobile indicator 3 is topped with a 15 index arranged above the dial. Index 15 is not shown in Figures 1A and 1B.

The partial view of Figure 2 schematically illustrates the cooperation between the movable indicator 3 of Figures 1A and 1B and a section of the slide (generally referenced 11) of the display device. In the example illustrated, the slide 11 takes the form of a groove formed by the space between two parallel rails 13a and 13b. The two rails 13a and 13b are constituent parts of a guide bridge (not referenced) which is arranged under a perforated dial (not shown). The guide bridge and the slide 11 extend in a plane which is parallel to the dial. As we will see in more detail, the indicator 3 can have two distinct orientations, depending on whether it is one or the other of the eccentric columns 7a and 7b which is guided in the slide 11. Thus, in order to facilitate understanding, the mobile indicator is shown twice in Figure 2. A first image of the mobile indicator (referenced 3) shows it turned so that the index 15 points towards the top of the sheet, whereas a second image of the same indicator (referenced 3') shows it oriented so that the index 15' points to the right in the drawing.

In accordance with the embodiment which is the subject of this example, the eccentric columns 7a and 7b have the same diameter as the pivot 5. This configuration allows the pivot 5 and one or other of the eccentric columns 7a and 7b to be inserted and to be guided simultaneously in the slide 11. It will therefore be understood that, in the present embodiment, the pivot 5 and one of the two columns 7a or 7b slide one behind the another along the slide, and therefore follow the same path. According to the invention, the mobile indicator can have at least two distinct orientations relative to the direction of the slide, depending on whether it is one or another of the at least two eccentric columns which is engaged in the slide. With regard to the present embodiment, it can be understood from FIG. 2 that, when the index 15 of the mobile indicator 3 points towards the top of the drawing, the pivot 5 and the eccentric column 7b are guided in the slide, the eccentric column 7a then being outside the slide, next to it. Conversely, when the index 15' points to the right of the drawing, it is the eccentric column 7a' which is guided in the slide along with the pivot 5, and the eccentric column 7b' is then outside the slide.

Still referring to Figure 2, we can see that the slide has two intersections 16a and 16b each comprising a baffle (respectively referenced 17 and 19) and two openings (respectively referenced 21a and 21b and 23a and 23b). Openings 21a and 23a are provided in rail 13a, and openings 21b and 23b are provided in rail 13b. As will now be seen, when the mobile indicator 3, 3' moves along the slide 11 from the left towards the right of the drawing, the configuration of the slide leads it first to pivot in the direction counterclockwise at the level of the first intersection 16a, and leads it to then return to its starting orientation by pivoting in the other direction at the level of the second intersection 16b. Although the mobile indicator 3, 3' is not represented when it is on the left in the drawing, it will be understood that in this position, before the mobile indicator has approached the first baffle 17, its orientation is the same as when it is to the right of the drawing. It is therefore the eccentric column 7a which is guided in the slideway when the mobile indicator 3 is on the left of the drawing. Column 7b is therefore not in the slideway when the mobile indicator is to the left of the baffle 17, but it moves along a path parallel to it.

The process leading the mobile indicator 3 of the display device shown to change orientation when passing an intersection (16a or 16b) will now be described. As already mentioned, when the mobile indicator 3 is to the left of the first baffle 17 and moves in the direction of the right in the drawing, the column 7b follows a trajectory parallel to the slide which leads it in the direction of the first baffle . When the column 7b actually reaches the baffle 17, its rectilinear translation movement is stopped, while the pivot 5, which is driven by the rotary drive member (not shown in Figure 2), is forced to continue to advance. along the slide 11. The combination of the force exerted by the drive member on the pivot 5, and that exerted in reaction by the baffle 17 on the eccentric column 7b, produces a torque that tends to rotate the counterclockwise moving indicator.

As already mentioned, the baffle 17 is associated with an opening 21a arranged in the rail 13a and an opening 21b arranged in the rail 13b. These two openings are arranged so as to respectively constitute passages through the two rails for the eccentric columns 7b and 7a. Thus, when the presence of the baffle 17 forces the movable indicator 3 to pivot counterclockwise, the eccentric column 7a crosses the rail 13b through the opening 21b, and thus disengages from the slide 11. Simultaneously, the opening 21a allows the eccentric column 7b to cross the rail 13a, so that the column 7b takes the place which was previously occupied by the column 7a in the slide, the mobile indicator having thus pivoted by 90°.

When after crossing the first intersection 16a, the mobile indicator 3 continues its movement in the direction of the right of the drawing, the eccentric column 7b and the pivot 5 are guided one behind the other in the slide 11 , so that the orientation of the movable indicator 3 with respect to the slide 11 is again determined. Column 7a, for its part, now follows a trajectory parallel to the slide which leads it in the direction of the second baffle 19. The second baffle 19 is associated with an opening 23a arranged in the rail 13a and with an opening 23b arranged in the track 13b. Thus, when the presence of the baffle 19 forces the mobile indicator 3 to pivot clockwise, the eccentric column 7b crosses the rail 13a through the opening 23a, and thus disengages from the slide 11. Simultaneously, the opening 23b allows the eccentric column 7a to cross the rail 13b, so that the column 7a then takes the place of the column 7b in the slide, the mobile indicator having thus pivoted 90° clockwise.

Figure 3 is a schematic plan view similar to that of Figure 2, but still showing a rotary drive member 25 arranged under the dial and the guide bridge to rotate relative to the latter about an axis 27 which is perpendicular to them. In the example illustrated, the drive member 25 can itself be actuated, for example, by the power reserve indication mechanism of a timepiece fitted with the device for displaying the invention. The illustrated drive element has the shape of a three-pointed star. It will however be understood that it could just as well be constituted for example by a disk or by a rotary arm. Referring to Figure 3, it can be seen that the rotary drive member 25 has a radial slot (referenced 29) which extends under the slide 11. The pivot 5 of the mobile indicator 3 is longer than the eccentric columns 7a and 7b. The pivot 5 is arranged to slide by its end in the radial slot 29, while being held axially between the two rails 13a and 13b of the slide 11. It will therefore be understood that the mobile indicator 3 is held above the intersection between the radial slot 29 and the slide 11. The eccentric columns 7a and 7b, for their part, are shorter than the pivot 5 and do not extend as far as the rotary drive member 25.

[0019] When the power reserve indication mechanism actuates the drive member 25 in rotation, the radial slot 29 pivots around the axis 27, so that the place of its intersection with the slide 11 moves. The pivot 5 of the mobile indicator 3 is thus forced to slide along the slide 11, so as to always remain vertical to the crossing. As shown in Figure 3, an advantage of this embodiment is to allow the mobile indicator 3 to travel a non-circular path with respect to the dial.

Figures 4A to 10 illustrate a display device according to a second particular embodiment of the invention. According to this embodiment, the mechanical display device is intended to be driven by the hour wheel of the movement of a timepiece in which it is integrated. FIG. 8 is a dial side plan view of this display device. As can be seen, it comprises twelve pads 115 which are arranged on the same concentric circle on the dial of the timepiece. The twelve pellets 115 are regularly distributed around the dial, and they carry twelve numerical indications which form the sequence of numbers from 1 to 12. The sequence of numerical indications is ordered so that the numbers increase as one goes around the counterclockwise. It will also be understood that the patches 115 of the display device are arranged to be driven by the hour wheel so as to rotate around the dial in the clockwise direction at the rate of one revolution in twelve hours.

[0021] Still referring to Figure 8, it can be seen that at the instant represented the three pellets 115 bearing the numbers 9, 10 and 11 are in the upper quarter of the hour circumference, in other words in the in the interval between 10:30 a.m. and 1:30 a.m., the three pellets bearing the numbers 6, 7 and 8 are in the right side quarter, in other words in the interval between 1:30 and 4:30 a.m., the three pellets bearing the numbers 3, 4 and 5 are in the lower frame, in other words in the interval between 4:30 and 7:30, and finally the three pellets bearing the numbers 12, 1 and 2 are in the left side quarter, in other words in the interval between 7:30 and 10:30 a.m. We can also see, on the one hand, that in the upper and lower quarters, the pads are oriented so that the direction of reading is tangent to the hour circle, and on the other hand, that in the quarters right and left sides, the pads are oriented so that the reading direction is radial. Indeed, in accordance with what will be explained in more detail later, the pads 115 are arranged to pivot on themselves by a quarter turn in the counterclockwise direction each time, while traversing the hour circle, they pass by 1:30 a.m., 4:30 a.m., 7:30 a.m. and 10:30 a.m.

The perspective views of Figures 4A and 4B respectively show the top and bottom of one of the twelve mobile indicators of the display device. As can be seen, the mobile indicator 103 is essentially formed of a pivot 105 and of a disc 106 carried by the pivot in a concentric position. Four eccentric columns (referenced 107a, 107b, 107c and 107d) also project from the lower surface of the disc 106 (FIG. 4B). These four columns are regularly spaced along a circle concentric with the pivot 105, and they extend parallel to the latter. It will therefore be understood that the four eccentric columns are spaced angularly by a quarter turn, the columns 107a and 107c thus being arranged symmetrically on the same diameter of the disc 106, and the columns 107b and 107d being arranged in a similar manner on another diameter which is perpendicular to the first diameter. FIGS. 4A and 4B still show four symmetrical notches (referenced 109a, 109b, 109c and 109d) which are regularly spaced along the circumference of the disc 106 and whose function will be explained later. It can also be seen that the part of the pivot 105 which extends from the upper surface of the disc 106 is formed of two sections (referenced 108a and 108b) having different diameters, and which are separated from one of the another by a shoulder (FIG. 4A). It can be seen in the figure that the diameter of the proximal section 108b is significantly larger than that of the distal section 108a. Finally, the distal section 108a is designed to carry one of the pads 115 illustrated in Figure 8.

The partial view of Figure 5 schematically illustrates the cooperation between a movable indicator 103 and a section of the slide (generally referenced 111) of the display device. In the example illustrated, the slide 111 takes the form of a groove formed by the space between two parallel rails 113a and 113b. The two rails are part of a guide bridge (not referenced) which is arranged under the perforated dial (not shown) of the display device. It will be understood that the latter is also the dial of the timepiece. Slide 111 extends in a plane which is parallel to the dial. As will be seen in more detail, the eccentric columns 107a, 107b, 107c and 107d are arranged to be able to cooperate with the slideway so as to determine four distinct possible orientations of the movable indicator 103. As shown in FIG. 4B, in the this example, the eccentric columns 107a, 107b, 107c and 107d and the pivot 105 have the same diameter and extend over the same length below the disc 106. This configuration allows the pivot 105 and two eccentric columns arranged on either side and on the other side of the pivot 105, on the same diameter, to be inserted simultaneously into the slide 111 in order to be guided by the latter. It will therefore be understood in particular that, according to this embodiment, it is the layout of the slide 111 which determines the predefined path along which the pivot 105 moves.

The slide 111 has four intersections 116a, 116b, 116c and 116d which are respectively arranged at 1:30 a.m., 4:30 a.m., 7:30 a.m. and 10:30 a.m. Only one of these intersections is visible in Figure 5 where it is referenced 116. It can be seen that the intersection comprises, on the one hand, a baffle 117, and on the other hand, two openings 121a and 123a arranged in the rail 113a and two openings 121b and 123b arranged in the rail 113b. As will now be seen, when the movable indicator 103 moves along the slider 111 from the left towards the right of the drawing, the configuration of the slider causes it to pivot counterclockwise at the level of the intersection 116. Figure 5 shows a first time the mobile indicator 103 on the left in the drawing. It can be seen that it is then oriented so that the eccentric columns 107a and 107c are both inserted into the slide 111, and the columns 107b and 107d are outside the slide on either side of it. FIG. 5 also shows a lug (referenced 119) which projects vertically from the baffle 117 at the level of the axis of symmetry of the latter. The function of the pin 119 will be explained later.

The process leading the movable indicator 103 of the display device shown to change orientation on passing the intersection 116 will now be described. As already mentioned, when the mobile indicator 103 moves in the left part of the drawing, the eccentric columns 107a and 107c and the pivot 105 are all inserted in the slide 111, so that the orientation of the mobile indicator 103 relative to the slide 111 is fixed. The column 107b, for its part, follows a trajectory parallel to the slide which leads it in the direction of the baffle 117. When the column 107b abuts against the baffle 117, its rectilinear translation movement is stopped, while the pivot 105, driven by the rotary drive member (not shown in Figure 5) is forced to continue advancing along the slideway 111. The combination of the force exerted by the drive member on the pivot 105, and of that exerted in reaction by the baffle 117 on the eccentric column 107b, produces a torque which tends to cause the movable indicator to rotate counterclockwise.

As already mentioned, the intersection 116 which includes the baffle 117 also includes two openings 121a and 123a arranged in the rail 113a, and two openings 121b and 123b arranged in the rail 113b. These four openings are arranged so as to respectively constitute passages through the two rails for the eccentric columns 107b, 107c, 107a and 107d. Thus, when the presence of the baffle 117 forces the mobile indicator 103 to pivot counterclockwise, the two eccentric columns 107a and 107c emerge from the slide 111 by respectively crossing the rail 113b and the rail 113a through the openings 121b and 123a. Simultaneously, the eccentric columns 107b and 107d enter the slide 111 through the openings 121a and 123b while crossing the rail 113a and the rail 113b respectively, so that the columns 107b and 107d take the places which were previously occupied by the columns 107a and 107c in the slide 111, the mobile indicator having thus pivoted by 90°. When, after crossing the intersection 116, the mobile indicator 103 continues its movement in the direction of the right of the drawing, the eccentric columns 107d and 107b and the pivot 105 are guided one behind the other in the slide 111, so that the orientation of the mobile indicator 103 relative to the slide 111 is again determined.

A feature of the second embodiment shown in Figures 4A to 10 is that it allows a mobile indicator 103 to cross the intersection 116a by moving, either in one direction or in the other. Referring more particularly to FIG. 5, it can indeed be seen that the left half and the right half of the intersection 116 are symmetrical. In particular, the openings 121a and 123a in the rail 113a are symmetrical with respect to each other, as are also the openings 121b and 123b in the rail 113b. It can further be seen that the shape of the baffle 117 is also symmetrical. The mobile indicator is shown a second time on the right in the drawing (where it is referenced 103'). It can be understood that, when the mobile indicator moves backwards from the right of the drawing, the column 107c' follows a trajectory parallel to the slide which leads it in the direction of the baffle 117. When the column 107c' abuts against the baffle 117, the torque produced tends to rotate the movable indicator clockwise, so that the two off-center columns 107b' and 107d' emerge from the slide 111 by respectively crossing the rail 113a and the rail 113b through the openings 121a and 123b. Simultaneously, the eccentric columns 107a' and 107c' enter the slide 111 through the openings 121b and 123a while crossing the rail 113b and the rail 113a respectively, so that the columns 107a' and 107c' take the places which were occupied until there by the columns 107b' and 107d' in the slide, the movable indicator having thus pivoted 90° clockwise.

According to an advantageous variant of the second exemplary embodiment of the invention, on the one hand, the twelve mobile indicators 103 each comprise four symmetrical notches (referenced 109a, 109b, 109c and 109d) which are regularly spaced along of the circumference of the disc 106, and on the other hand, the baffle 117 of each of the intersections 116a, 116b, 116c and 116d carries a lug (referenced 119) which is arranged so as to project vertically from a point located on the axis of symmetry of the baffle. Figures 10A to 10F illustrate a sequence of six successive instants in the cooperation of the lug 119 with the notch 109a. As the movable indicator 103 engages the intersection (Figure 10A), the notch 109a is rotated 45° counterclockwise relative to the direction of the slider 111. Then, the inside edge of the notch 109a meets lug 119 (FIG. 10B) at about the same time as eccentric column 107a meets baffle 117. the lug 119 to fit into the notch 109a (Figures 10C, 10D and 10E). When the mobile indicator has finally turned 90° counterclockwise, the eccentric column 107c abuts against the rail 113a. The notch 109a then forms an angle of 135° with respect to the direction of the slide 111 and the lug 119 is now free to come out of the notch (FIG. 10F). The advantageous variant which has just been described makes it possible to improve the stability and the safety of operation during the pivoting of the mobile indicators. In particular, it can be understood that the motor torque necessary to move the mobile indicators 103 of the display device forward suddenly increases in a transient manner each time a mobile indicator is caused to pivot by a quarter turn while crossing an intersection. . Under these conditions, the cooperation of the lug 119 with one of the notches 109a, 109b, 109c or 109d has the effect of spreading out the peak corresponding to the transient increase in the necessary engine torque.

Figure 6 is a general schematic top plan view showing the twelve movable indicators 103, the slide 111 and the rotary drive member 125 of the display device of this example. Figure 7 is an enlarged partial view taken from Figure 6 and which shows the same portion of the display device as Figure 5. As shown in Figures 6 and 7, the rotary drive member 125 is arranged to rotate between the dial (not shown) and the slide 111 formed in the guide bridge. In the example illustrated, the drive member 125 is itself actuated by the hour wheel of the movement of the timepiece via a gear train, not shown. The drive element shown in Figure 6 has the shape of an internally toothed ring gear. It will be understood, however, that it could just as well be constituted, for example, by a wheel set comprising a disk and a concentric pinion.

Referring more particularly to Figure 6, it can be seen that the periphery of the ring gear forming the rotary drive member 125 is provided with twelve forks 129 which are regularly distributed along the circumference of the crown . Each fork 129 is oriented radially with its opening facing the outside of the crown 125. It can also be seen that the twelve mobile indicators 103 are each sandwiched between one of the forks 129 and the slide 111. The proximal section 108b of the pivot 105 of each mobile indicator 103 is guided between the two branches of one of the forks 129, while the lower part of the pivot 105 is guided in the slide 111. As already indicated, according to this second exemplary embodiment, it is the path of the slider 111 which determines the predefined path along which the pivot 105 moves. extending to the periphery of the dial, concentrically to the latter.

Still referring to Figure 6, we can see that the slide 111 has four intersections (referenced 116a, 116b, 116c and 116d) which are respectively placed at 10:30 a.m., 1:30 a.m., 4:30 a.m. and 7:30 a.m. around the dial. The intersections thus divide the slide 111 into four parts of the same length which correspond respectively to the upper quarter, to the right lateral quarter, to the lower quarter and to the left lateral quarter of the slide 111. It will be understood that the rotary drive member 125 is arranged to drive the twelve mobile indicators 103 so that they travel around the hour circle clockwise at the rate of one revolution in twelve hours.

The layout of each of the four quarters of the slide 111 is curved, so that when a mobile indicator 103 is driven from one end to the other of one of the quarters, it rotates 90° in the direction clockwise without having changed its orientation with respect to the slide. On the other hand, in accordance with the present embodiment, a mobile indicator 103 is led to successively cross the four intersections 116a, 116b, 116c and 116d by traversing the slide 111. As explained above, each time a mobile indicator 103 crosses one of the intersections, it pivots on passing 90° counterclockwise with respect to the slide. It will therefore be understood that, in the present example, the presence of the intersections 116a, 116b, 116c and 116d makes it possible to compensate for the pivoting of the mobile indicators which is due to the curvature of the slide 111.

As already mentioned, a feature of the second embodiment of the display device of the invention is that it can also operate when the mobile indicators 103 move in the opposite direction. Thus, if the mobile indicators 103 are driven backwards by the hour wheel when setting the time, for example, and at least one of the mobile indicators 103 crosses an intersection backwards, this indicator pivots when passing d a quarter turn clockwise.

Figure 9 is an enlarged partial view similar to that of Figure 7, but in which the two mobile indicators shown are capped with their pad. At the moment represented, the intersection 116a is between the two mobile indicators bearing the numbers 11 and 12, and it can be noted that the digital indication 11 is oriented so that the direction of reading is tangent to the turn d 'hours, while the digital indication 12 is oriented so that the reading direction is radial. It will be understood that, when turning around the dial, the mobile indicator capped with the pellet bearing the number 12 will cross the intersection 116a, it will pivot by a quarter turn counterclockwise, so that the direction reading will then be tangent to the hour revolution, as is the case for the mobile indicator bearing the number 11.

[0035] It will also be understood that various modifications and/or improvements obvious to a person skilled in the art can be made to the embodiment which is the subject of the present description without departing from the scope of the present invention defined by the appended claims. In particular, according to other embodiments, the pivot could not be guided in the slideway, but could be guided for example by a slot in the dial, or simply be pivoted on the rotary drive member.

Claims (5)

1. Display device, in particular for a timepiece, comprising a rotary drive member (25; 125) arranged to rotate around an axis (27; 127) perpendicular to a main display plane of the device. display, and a mobile indicator (3; 103) comprising a pivot (5; 105) perpendicular to the main display plane and arranged to be driven by the rotary drive member so as to move along a predefined path while rotating around the axis (27, 127) integrally with the rotary drive member (25; 125), the mobile indicator further comprising at least one eccentric column (7a, 7b; 107a, 107b, 107c, 107d) and oriented parallel to the pivot, and the display device comprising a slide (11; 111) extending parallel to the main display plane, the slide being provided to guide the at least one eccentric column so as to determine the orientation of the moving indicator as its pivot moves along the predefined path; characterized in that the mobile indicator (3; 103) comprises at least two eccentric columns (7a, 7b; 107a, 107b, 107c, 107d) which are angularly spaced around the pivot (5; 105), the mobile indicator being arranged to adopt different orientations, depending on whether one or the other of the at least two eccentric columns is guided by the slide (111), and in that the slide has at least one intersection (16a, 16b; 116a, 116b, 116c, 116d) comprising a baffle (17, 19; 117) associated with an opening (21a, 21b, 23a, 23b; 121a, 121b, 123a, 123b) in the slide, the baffle being arranged to deflect the trajectory of a at least two eccentric columns when the mobile indicator passes through the intersection comprising the baffle, so as to cause the mobile indicator to pivot on itself sufficiently so that, after passing the intersection, the eccentric column which is guided by the slide is no longer the same eccentric column. 2. Display device according to claim 1, characterized in that the path of the slide (11; 111) corresponds to the predefined path, and in that the pivot (5; 105) is arranged to cooperate with the slide in such a way to be guided by the latter, the pivot and the eccentric column (7a, 7b; 107a, 107b, 107c, 107d) which is guided by the slide following the same path outside the intersection(s) (16a, 16b; 116a, 116b, 116c, 116d). 3. Display device according to claim 1 or 2, characterized in that the pivot (5) of the movable indicator (3) passes through a radial slot (29) of the rotary drive member (25). 4. Display device according to claim 1 or 2, characterized in that the movable indicator (103) is pivotally mounted on the rotary drive member (125) in an eccentric position, the predefined path along which the pivot of the movable indicator (103) is arranged to move in the shape of a circle or an arc of a circle. 5. Display device according to one of the preceding claims, characterized in that the slide (11; 111) in the form of a groove, in that the intersection (16a, 16b; 116a, 116b, 116c, 116d) comprises a symmetrical baffle (117) arranged on the side of the groove so as to be on the trajectory of one of the at least two eccentric columns (107a, 107b, 107c, 107d), but outside the predefined path followed by the pivot (105), the two walls (113a, 113b) of the groove further each having two openings (121a, 123a, 121b, 123b) arranged symmetrically on either side of the baffle to let the at least two eccentric columns when the mobile indicator (103) pivots on passing the intersection.