DE2349759A1 - DRIVE MECHANISM FOR TWO COAXIAL CALENDAR DISPLAY ORGANS OF A MOVEMENT - Google Patents

Description

29,981

A. Schild S.A. , 2540 Grenchen (Canton Solothurn, Switzerland), Mühlestrasse 14

"Drive mechanism for two coaxial calendar display elements of a clockwork "

There are already drive mechanisms known that the sudden switching ensure a display organ for the day and a display organ for the day of the week in calendar clocks. However, they are outdated Constructions. On the other hand, most calendar mechanisms are changing of wristwatches with date and weekday display, at least one of the displays is progressive.

The object of the invention is to provide a drive mechanism for wristwatches with day of day and day of the week, these organs being coaxial. The mechanism must switch the two organs in at lightning speed the way to ensure that each organ advances one step, so it must avoid accidentally jumping two steps will. Another task of the invention is the creation of a mechanism which ensures these functions through a simple and space-consuming construction. Finally, the invention also aims to in addition to the above-mentioned services, to have the option of correcting the day as soon as the change has taken place, without the risk of blocking the work.

Accordingly, the invention is directed to a drive mechanism for two coaxial calendar organs that are intended to step

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to rotate around their common axis in a clockwork and one step at a time Drive organ with two fingers, which are intended to each one of the said To drive calendar parts, a calendar wheel which is connected to the gear train and is coaxial with the drive organ, a clutch with angular play between the calendar wheel and the drive organ, a cam firmly connected to the drive organ, a cooperating with the cam Lever and a spring that acts on the lever in such a way that the two calendar organs suddenly jump over due to the rotation of the drive element is then effected when the latter has been brought into a certain position by the calendar wheel, characterized in that the profile the cam has a retaining groove which cooperates with the lever and limits the rotation of the drive organ under said spring action.

Further features and advantages essential to the invention can be found in the following Description in which exemplary embodiments are explained with reference to the drawings.

In the drawings show:

Fig. 1 is a plan view with some organs torn off,

Fig. 2 is a plan view of the mounting plate with the cam and the switching lever, and

FIG. 3 shows a section along the line III-III in FIG. 1.

The mechanism to be described lies in a circular clockwork, whose board 1 carries a day ring 2 and whose hourly mandrel 3 ensures the turning of a weekday star 4 with a display 5 that is on the extends the same level as the crown 2. As with certain mechanisms known per se, the weekday star 4 has fourteen teeth and the The drive mechanism is arranged in such a way that this star moves gradually

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rotates, with each step forwards two teeth when switching mean. Normally the two organs 2 (and 4, 5) are attached with two grids 6 and 7 which rotate about a common axis 8 and are stressed by superposed spring blades 9 and 9 '. Since the two grids 6 and 7 extend on both sides of the axis 8 and since one of them has a centripetal effect in such a way that it is in the toothing of the star 4 engages, while the other has a centrifugal effect in such a way that it fits into the toothing of the crown 2, it can be seen that the two springs 9 and 9 'are subjected to bending stress, when one or the other of the grid moves away from the toothing with which it interacts.

The drive device of the organs 2 and 4 is guided on a mounting plate 10 which is fastened to the plate 1 with two screws 11. The exact positioning of this plate is ensured by the head 12 in the plate 10, this head engaging in a corresponding groove in the board and by the tenon head 26, as will be shown later. The plate 10 is cut out with a lateral arm 13 which is bent at right angles and which forms a switching spring. Said plate 10 carries a first portion 14 consisting of a pinion and a wheel. A pin 15 about which the wheel 14 rotates _a of the board is in an opening wedged or fitted 10 as shown in Fig. 3 to be seen. The flat head ensures the positioning of the movable part 14 in the axial direction. The wheel of part 14 is in communication with the hour wheel 3, while the pinion drives a calendar wheel 16 which rotates once every twenty-four hours. This calendar wheel 16 rotates around a cylindrical receptacle which has a hub 17 which is inserted rotatably in an opening 18 of the plate 10. As can be seen in FIG. 3, this hub has several receptacles of different diameters. At the upper end, a finger 19 is guided, which is fitted around an annular groove, under which a second lateral finger 20 extends, which is cut out with the hub 17 and deep-drawn

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and which has a pin 21 on its lower surface. Below the Finger 20 extends the circular receptacle 22, which allows the rotation of the Rades 16 ensures and extends even below see a recording that in the opening 18 is inserted. At the lower end, the hub 17 has a last recording on which a cam 23 is wedged, the top view of which is visible in dashed lines in FIG. The entirety of the elements 17, 19 and 23 forms a kind of ratchet with two fingers 20 and 19 which are approximately diametrically opposed, although they extend at different levels. The length of these fingers is also different, as can be seen in FIG.

The functions are explained later, but it is already indicated now, that the pin 21 is inserted into an arcuate gap 24 which is provided in the wheel 16 on an arc of a circle which almost reaches 180 °. As in To see Fig. 3, the wedging of the cam 23 on the hub 17 connects the drive organ to the mounting plate 10. Finally, this plate still carries (Fig. 2) a lever 25 which rotates around the pin 26. The latter is similar to the pin 15. Its foot is therefore inserted into an opening in the plate 10 and its head holds the lever 25 in the axial direction. The head of the pin 26, which is thicker than that of the pin 15, is used as a positioning element of the Plate 10 used. During assembly, it is inserted into a cylindrical opening inserted into the circuit board. The drive organ is also used during assembly 17, 19, 23 precisely positioned and the rotatability ensured. In fact, a central hole in the hub 17 then comes to rest on the pin 27, that protrudes from the board. The axis of rotation of the hub 1 ″ and of the wheel 16 is thus determined by the pin 27 and not by the opening 18, which is only used during assembly.

The cam 23 has a spiral rising ramp 28 and a descending one Ramp 29, the course of which is carefully developed, as will be explained later. An intermediate ramp 33 extends between these two ramps and a groove 30. These elements of the cam 23 are intended to either

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the one with the extreme nose 31 of the lever 25 or with the bulge 32 act together behind the nose at a distance equal to that which separates the bottom of the descending ramp 29 from the groove 30.

The mechanism described works as follows: due to the Presence of the part 14 between the calendar wheel 16 and the hour wheel 3, and after the latter two wheels move in the same direction rotate and are constantly driven by the clockwork, it follows that, starting from the position of FIG. 1, the rear end of the column 15 to the Pin 21 strikes after the wheel 16 has rotated a few hours. The drive ratchet 17, 19, 23 is then connected to the calendar wheel 16 and from that moment on it rotates with this wheel. The spiral one Part 28 of the cam 23 then comes under the bulge 32 of the lever 25 which rotates to the left in FIG. 1 and progressively reinforces the spring 13. Then the nose 31 is supported on the spiral-shaped part 28. This Reinforcement takes about fourteen hours until the nose 31 is at the highest point of the cam, directly behind the steeply inclined part that forms the beginning of the descending ramp 29. The ratchet (17, 19, 23) is then pushed by the spring 15 and rotates suddenly. The finger 19 gets into the path of one of the toothed parts of the star 4. Under the action of the spring 13, which acts on the lever 25, this star is rotated until the grid 7 has passed two teeth of the teeth 4. The finger 20 also actuates the organ 2 and drives one of the teeth in such a way that the grid 6 engages the next toothing. At this point the rotation of the cam is so that the nose 31 is located in the part of the cam which is closest to the axis at the end of the ramp 29. Under the effect of the received However, energy continues to rotate the cam and the bulge 32 of the lever 26 comes to rest in the groove 30, which forms an arc between the lever and Cam causes. The drive member remains in the one shown in the drawing

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Blocked location. The mechanism described therefore has an instantaneous effect Skipping both display organs, using a single spring and a single drive, the latter with two almost diametrically opposed fingers is provided. Since the drive member is mounted at the end of its movement, each of the fingers holds the one it controls Calendar part, which avoids the danger of a double jump of this organ. It can indeed be seen in Figure 1 that fingers 19 and 20 Remain on the way of the teeth of the daily crown or the weekday star when the rubbing organ is blocked in the described position. If, on the other hand, the nose part 31 (Fig. 2) rests on the cam at a point which is beyond the center and therefore tends to To let them rotate in the counterclockwise direction, the bulge 32 is supported at the bottom of the groove 30 at a point which is this side of the center of the cam and accordingly tends to rotate clockwise. The risk of a double jump is thus avoided with certainty. On the other hand, it is noted that the column 24 extends in a clockwise direction (FIG. 1) over the Finger 20 continues out. This arrangement makes it possible to set the day at any time and in particular immediately after the change has taken place. Indeed, this setting of the day is done by means of a separate adjustment mechanism with respect to the drive mechanism, which acts directly on the day ring. Moving the latter in the clockwise direction causes the drive member to rotate about the finger 20, but this rotation has only a small amplitude: that which is necessary for the tooth that is behind the Finger 20 is located, can get beyond this finger. Thanks to the fact that the column 24 extends over the finger 20 in the position according to Fig. extends, this displacement of the drive finger is possible without influencing the calendar wheel and accordingly without the gear train the setting option is blocked. If there is a possibility of adjustment at this point in time, the displacement of the finger 20 causes a rotation of the

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Nooke in such a way that the bulge 32 rises along the flank of the groove 30. Under the action of the spring 13, the cam then resumes its rest position. The support conditions of the bulge 32 in the groove 30 and the nose 31 between the ramps 29 and 33 are such that a lock against any unintentional rotation occurs between these workpieces.

The mechanism described has the advantage that it is simplified Construction is. The assembly of all workpieces takes place on the plate 10 independently of the rest of the clockwork and it is then sufficient to to attach the drive block to the circuit board so that the drive is established. The regulations and the necessary adjustments are practically nonexistent. Although the two grids 6 and 7 are mounted on the board and are tightened by two springs 9 and 9 ', which are supported on a curved tongue 33 which is part of the plate 1, a larger plate could also be used in another embodiment which would also carry the grids 6 and 7. It is further noted that the profile of the cam 23 is developed so that the Speed of rotation of the drive member as a function of the execution of the operations to be performed is set. Developing a reasonable one Depending on these criteria, it is possible to ensure an almost simultaneous switching of the two coaxial organs, although they are as different as a day star with fourteen teeth that has to advance a seventh of a turn and a day crown, theirs Feed is only 1/31 of a turn. It follows from the above description, that the problem has reasonably been completely solved by the invention.

Claims;

409816 / 085B

Claims (10)

29,981 claims: 1.) Drive mechanism for two coaxial calendar organs, the are intended, step by step, around their common axis in one To rotate clockwork, and which has a drive organ with two fingers, which are intended to drive one of the said calendar organs, a calendar wheel that is connected to the gear train and for Drive organ is coaxial, a coupling with angular play between the calendar wheel and the drive organ, one with the drive organ firmly connected Cam., A lever cooperating with the cam and a Spring that acts on the lever in such a way that the calendar elements are instantly skipped by rotation of the drive element is ensured when the latter has been brought into a certain position by the calendar wheel, characterized in that the Profile of the cam has a retaining groove which cooperates with the lever and the rotation of the drive organ under the action of said spring limited. 2. Mechanism according to claim 1, characterized in that the retaining groove cooperates with a bulge of the lever, the latter also has a nose that follows the rest of the profile of the cam. 3. Mechanism according to claim 2, characterized in that the cam has a spiral ramp which moves away from its axis from said retaining groove, furthermore a descending ramp which extends approaches the said axis from the outer end of the spiral lamp and a third ramp that connects the inner end of the descending Έί-mpe with the Holding groove connects. 409816 / 085b 4. Mechanism according to claim 3, characterized in that the distances between the axis of rotation of the lever and its nose on the one hand and the said bulge on the other hand are larger or smaller than the distance between the axes of rotation of the lever and the cam. 5. Mechanism according to claim 4, characterized in that the profiles of the cam and the lever are such that the nose of the lever is supported against the inner end of the descending ramp when the bulge occurs is held in the retaining groove. 6. Mechanism according to claim 1, characterized in that the connection between the drive member and the calendar wheel is established is by a connecting finger, which is firmly connected to the drive element and is pushed into a circular arc-shaped column, which the Has calendar wheel. 7. Mechanism according to claim 1, 2 and 6, characterized in that the length of said circular arc-shaped column of the calendar wheel so is that at least one of said calendar parts can then move by one step around its axis when the drive member is blocked by sensing the bulge of the lever in the retaining groove of the cam. 8. 'Mechanism according to claim 1, characterized in that the drive organ is guided by a mounting plate, which also carries the lever and with which said spring is firmly connected. 9. Mechanism according to claim 8, characterized in that said spring is formed by an arm which is in the mounting plate is cut out and bent at right angles with respect to the plane of the latter 409816/0856 10. Mechanism according to claim 8, characterized in that the drive member is pushed into an opening in the mounting plate with play is and has a cylindrical receptacle on its hub, which on a Pivot is pushed on, which protrudes from the plate when the mounting plate is attached to the plate of the clockwork. 409816 / 08SÖ Blank page