DE2158728C - Device for switching calendar information in clocks step by step - Google Patents

Description

(14) can be adjusted.

15. Device according to one of claims 1 to 14, characterized in that the pinion

(15) is constantly pressed by spring elements (10) into the toothing (13) which interacts with it, so that no backlash occurs between the pinion (15) and the toothing (13).

16. Device according to one of the claims! to 15, characterized in that the toothing (13) of the part (14) is an internal toothing .

17. Device according to one of claims 12 to 16, characterized in that the toothing of the component (19) is an internal toothing.

18. Device according to one of claims 12 to 17, characterized in that the setting of the component (19) only against the pressure of a Spring element (22) can be done.

19. Device according to claim 18, characterized in that the spring element (22) the The gear wheel (18) presses into the toothing of the component (19).

20. Device according to claim 19, characterized in that the spring element (22) so is designed that it positions the gear wheel (18) within the backlash.

21. Device according to claim 19 or 20, characterized in that the spring element (22) is positioned by a projection together with a cutout (22) .

22. Device according to one of claims 19 to 21, characterized in that when adjusting the component (19) the effective length of the Spring element (22) is greatly shortened by a stop (28), whereby the resistance, which is required to overcome the spring element (22) increases sharply.

23. Device according to one of claims 19 to 22, characterized in that a spring element (24) presses the component (19) against the toothing of the gear wheel (18).

24. Device according to one of claims 2 to 23, characterized in that the spring element (10) consists of a coiled spring connected to the rocker (9).

25. Device according to one of claims 12 to 24, characterized in that the gear wheel (18) in a limited area around the The pivot point of the pinion (16) is pivotable.

26. Device according to one of claims 1 to 25, characterized in that the drive of the date ring (19) takes place through a gear chain, in which u. the interlocking of the Tagesriiiijes (14) is located.

The invention relates to a device for step-by-step switching of calendar information

[Ion-bearing components in clocks, the indexing of the part carrying the calendar information takes place through a pinion which is constantly in engagement with the toothing of the part.

Hs facilities are known which enable iLis clocks to switch calendar information abruptly, z. B. in dor German Auslegeschriit 1523 770. In this Auslegesehrifi a device is shown in which the date ring is provided with a toothing. which constantly meshes with a pinion of the pointer mechanism. In order to enable the calendar increments to be switched abruptly, a screen is provided, which is attached between the observer and the country information and which is provided with a cutout through which only a number of those printed on the date ring Calendar information can be observed. The abrupt switching of the calendar information is achieved by jerky shifting of this cover. The date ring itself, like the rest of the gear train, moves continuously. This device has the disadvantage that a movable component, namely this cover, must be attached between the dial and the date ring, which can be easily blocked by unevenness in the dial and which also leads to the overall height of the entire clock being increased. In addition, parts of the bezel are visible from the dial side. The cover must therefore be printed or otherwise surface-treated in accordance with the dial. In addition, the continuous running of the date ring has the consequence that the date information is not positioned in constant positional relationship to the other display means on the dial. It is also a relatively broad and elongated one. Cutout in the dial required. Most of the above disadvantages affect the aesthetic design of the watch and are therefore a significant disadvantage.

There are also devices for indexing calendar information are known in which the date ring by leaps and bounds Pawls are shifted. These facilities have the disadvantage that the date ring by a Frictional connection must be positioned with pawls. However, this frictional connection must be overcome when switching. Since only relatively small forces are available to switch the clockwork stand, either the date ring is not held in place sufficiently, which means that rotational accelerations result in incorrect advancement of the Date ring have the consequence, or that the frictional connection is carried out vigorously, which leads to an excessive load on the gear train and in a significant amplitude change or frequency change of the time standard results.

The object of the invention is to create a device for the step-by-step switching of components in clocks that carry calendar information that has only a small and, in particular, no Require sudden force to advance.

This object is achieved according to the invention in that the pinion can be moved by a cam disk during part of a revolution of the pinion relative to the part carrying the calcining information and is stationary against a restoring force and that the indexing of the part is controlled by the cam disk by the Restoring force takes place. The pinion is thus .stets in engagement with the part, but is guided along with the speed of its rolling of the cam disc along this, so that the part stops. However, this movement takes place against the restoring force, which is preferably provided by a spring element

ίο is formed so that the saved by this Force discharged at the moment when the top dead center of the cam has been overcome. Nevertheless there is always a positive engagement between the pinion and the part. the one and unintended Adjustment prevented.

The present invention thus provides an execution which overcomes the disadvantages of the aforementioned execution. In addition, the facility requires only a few components, which leads to a reduction in

tion of the manufacturing costs -.ihn. The few components required make it possible; n also one Reduction of the calendar device to the size of a ladies' watch with simple means.

The F i g. 1 to 4 show exemplary embodiments of

present invention.

F i g. 1 shows a calendar circuit from the dial side in the normal position immediately after Advance the calendar information;

F i g. 2 shows this calendar circuit from the digit

ferblattseite, in which it is shown how the component carrying the date information can be advanced relative to the component carrying the day information;

F ~ i g. 3 shows the calendar circuit for manual

len backward rotation of the hand mechanism;

4 shows the calendar device in section from the wheel 18 to the pinion 16, to the pinion 2, to the center of the work, to the pinion 15.

As shown in Fig. 1, a ritual

• i »zel 2 driven hour wheel, which normally carries the hour hand, not shown, rotated by the clockwork in the direction of the arrow. With the hour wheel 1, the pinion 3 rotates, which with a day bike 4 combs. Day bike 4 is on a pivotable rocker 9 mounted. the Rocker 9 has a spring arm which is attached to position 11 and is pretensioned so that the rocker is exposed to a torque whose direction is counterclockwise. The Day wheel 4 is provided with a nose6 angled towards the work side, which into a recess? the Cam 5 engages. With the cam 5, that's a crack! 15 positively connected, which is shown in the toothing 13 of the day ring 14 engages. In the The toothing of the day ring 14 also engages the pinion 16, which meshes with the wheel 17. The wheel 17 is positively connected to the wheel 18 which meshes with the date ring 19. The wheels Λ7 and 18 are connected to the pin 20, which is positioned in the recess 21. The wheel 18 is positioned by the spring 22 within the range of motion resulting from the tooth play. The spring 22 is provided with the dashed projection, which is in a recess 28 of the board engages. A spring 24 presses on the side of the date ring approximately opposite the wheel 18 on the date ring teeth and thus holds the date ring without play in the toothing of the

of the 18th mil of the revolution of the hour wheel 1 turns is also the wheel 4, with the nose 9 to the opposite end of the recess? is moved. As soon as the end of the recess is reached, the cam 5 is rotated, which also causes the Pinion 15 is rotated. In order to prevent the day ring 14 from twisting, the circumference 27 slides the cam 5 along the pin 8 fixed to the housing. The pinion 15 is just as fast as a result moves counterclockwise like its teeth in engagement with the Tagcsringverzahn 13. Through this movement of the pinion 15 is also achieved that the day ring is securely positioned in a form-fitting manner is. The mounting of the rocker 9 is radially displaceable on the surface 12. Through the Fcdcrmoment at position 11, the pinion 15 is pressed into the toothing 13 of the day ring 14 without play. The toothing of the day ring 14 is now also positioned over the pinion 16 and the wheels

17 and 18 form-fit the date ring 19. the Recess 21 for the pivoting movement of the wheel

18 to the pinion 16 is provided to rotate the date ring relative to the day ring for to enable manual adjustment of the Dalumber device. The spring fulfills two functions:

1. it eliminates the disturbing influence of the tooth picl, whereby an unsafe positioning of the calcining information 26 would be caused.

2. In addition, the spring represents a resistance which prevents unintentional further turning the date ring prevented.

F i g. 2 shows the form in which the spring fulfills this task. The forces required to eliminate the tooth spicl should be very small because they have to be overcome by the clock's gear train. However, the resistance that the gear train opposes to the manual adjustment of the date ring should be great in order to avoid unintentional adjustment, and because very large forces are available here in relation to the movement. In order to achieve such different moments of force, the spring 22 is provided with a projection which engages in the recess 23. With a slight deflection of the spring, which occurs when the wheel 18 is rotated by the clockwork, this projection does not come to the edge 28 of the projection 23. The spring is thus relatively long and its force is therefore low. However, as soon as the wheel 18 is moved by the date ring around the pinion 16 in the recess 21, the projection of the spring 22 comes to the stop 28 of the recess 23, whereby the effective length of the spring 22 is greatly shortened, which is due to a strong increase in the Spring force leads This function has the consequence that the resistance which the date ring opposes to the arbitrary turning is very different from the resistance which the clockwork has to overcome. The clockwork only has to overcome those small forces which are necessary to keep the calendar rings 14 and 19 free of play. If external accelerations occur, the calendar rings can move in a limited range until they are positively blocked by the teeth. At the end of the acceleration, both lime rings are then returned to their original position by the spring elements.

F i g. 2 also shows how the pinion 15, rotated by the wheel 14, runs along the toothing 13 of the day ring 14. This wciterbcwcgting takes place until the top dead center of the cam disk 5

S passes pin 8. At this moment the rocker 9 is moved 1 · counterclockwise by the spring. The cam 5 and the pinion 15 are thus moved by the rocker 9 . The pinion 15 and the rocker 9 are also

ίο rotated about its pivot point by sliding the pin 8 along the steep side of the cam. The rigid connection of pinion 15 and cam 5 ensures that pinion 15 and cam 5 are always in a certain position

The relationship to one another remains independent of the angular rotation of the wheel4. The wheel 4 must be rotatable with respect to the cam disk 5 if, despite the sudden switching of the calendar information, a manual backward rotation of the pointer

ao wcrks should be possible . Since in this case, _t represents darg as in Fig. 3, scroll the Wippe9 and the pinion 15 and the ring 14 days in a clockwise direction, the sliding angle from bottom dead center of the cam plate 5 must verlau- flat to the top dead center

»5 fen to prevent jamming. The flat course of this sliding angle leads, as already described above, to a rotation of the cam disk 5, Mjbald the pins the top dead center he has reached when changing the Kalcndcrinformation.

To enable this rotation independently of the gear train, is the recess? and thus the relative rotatability of the cam ? and bike 4 required.

The establishment of this calculator brings ο

with it, the day ring and the date ring during reverse rotation of the dial train Dall can be rotated backwards. This makes it easier to set the day rate. The date ring 19 can then be adjusted relative to the tag ring by means of a quick correction (not shown).

The illustration according to FIG. 4 shows the simple structure of the switching device. The difference between the outer diameter of the hour wheel is 1 µm ! the inner diameter of the day ring 14 possible

It is necessary to: position the support point for the dial in the scm area, which simplifies the production of the dial and increases its reliability. The continuous drive of the day ring and the resulting drive of the date ring are advantageous in this respect. because the day ring normally never has to be adjusted when the clock is used continuously, because the number of days per week is constant.

length must be adjusted regularly, this wildly appropriately positioned at the end of the gear chain. In order not to require too long a path to turn the day ring 14 at an angle, the day ring is expediently in each case at Vm

Twisted circumference. It is therefore equipped with the calendar information for two days of the week. The interlocking of the calendar parts results as follows: That Pinion 15, which performs one revolution per day, has 6 teeth, which results in a number of teeth

$ 6 of 84 for the daily rmg. The toothing of the wheel 17 must then be 6 times larger than the toothing of the wheel 18.

For this ? Sheet drawings

Claims (14)

Patent claims: 1. Device for the step-by-step resounding of components carrying calendar information in clocks, the forwarding of the part carrying the calendar information through a pinion takes place, which is constantly in mesh with the toothing of the part, d a d u r c Ii marked that the Riizel (15) of a cam (5) during part of a revolution of the pinion (15) relative to the person carrying the customer information while stationary part (14) is movable against a restoring force (10) and that the Switching of the part (14) under control by the cam disc (5) by the restoring force (10) takes place. 2. Device according to claim 1, characterized in that the pinion (15) and the corner of the curve (S) and approximately the pinion driving wheel (4) are mounted coaxially on a rocker (9). 3. Einrichiung according to claim 2, characterized in that the pivot point of the rocker is coaxial with the pivot point of the calendar information mation bearing part (14) is stored. 4. Device according to one of claims 1 to 3, characterized in that the pinion (15) and the cam disc (5) are positively connected to one another. 5. Device according to one of claims 1 to 4, characterized in that the wheel (4), the amreibt the .Ritzel (15), _e is rotatable through a limited angular range egenüber the pinion (15). 6. Device according to one of claims 2 to 5, characterized in that the rocker (9) the cam (5) by means of spring elements (10) presses against a stop (8). 7. Device according to claim 6, characterized in that the stop (8) is designed as a pin fixed to the housing. 8. Device according to one of claims 5 to 7, characterized in that the relative rotatability between the pinion (15) and the Wheel (4) through a projection (6 ^ of the wheel (4) is limited, which engages in a cutout (7) of the cam (5). 9. Device according to one of claims 2 to 8, characterized in that the rocker is rotated suddenly after reaching the top dead center of the cam (5), wherein the Stop (8) comes to the bottom dead center of the cam. 10. Device according to one of claims 1 to 9, characterized in that the through the Pinion (15) driven part (14) carries the day calendar information. 11. Device according to one of claims 1 to 10, characterized in that the part (14) is moved by 1/14 of a turn. 12. Device according to one of claims 1 to 11, characterized in that the directly driven part (14) which carries the day-Ka calendar information, via a transmission drives the component (19) which carries the date-calendar information. 13. Device according to claim 12, characterized in that the transmission which lies between the part (14) and the component (19) . is so designed. that the component (19) can be adjusted independently of the rotational movement of the part (14). 14. Device according to claim 13, characterized in that the component (19) only in its normal direction of rotation independent of the part