DE1178793B - Automatic reset device - Google Patents

Description

Applicant: Kienzle Uhrenfabriken Aktiengesellschaft, Schwenningen / Neckar The invention relates to an automatic reset device for balance watches.

Balance clocks all show after a more or less long period of time Rate deviations, even if the watch is accurate in the manufacturer's factory or at the repair shop was adjusted. These rate deviations have several causes, e.g. B. Running in the bearings and gears, aging of the oil, etc. Gear deviations are mostly caused by Tried to eliminate manual adjustment of the regulator, but the technical one In the rarest of cases, the layman manages to set the watch to zero to regulate. There is therefore an effort to avoid these inevitable rate deviations to compensate as automatically as possible.

Some devices are already known in which the regulator is semi-automatic is adjusted. In one of these devices, the rate deviation of the watch is during a number of hours and if there is a rate deviation by pressing of a pusher, the position of the regulator changed according to the rate deviation. A disadvantage of this device is the relatively large amount of parts and the Need to precisely check the rate deviation after a certain number of hours ascertain. According to another known solution that is used on pocket and wrist watches applies, the winding shaft has three positions, one for each winding, for pointer setting and for simultaneous pointer and reset creation. Next to the large expenditure on individual parts and the condition that a special winding or Pointer adjusting shaft must be present, is a disadvantage that the speed of the clock regularly must be monitored in order to correct the index according to the position of the pointer to be able to provide.

It is also known an automatic reset device at which the minute shaft inevitably turns off a reset part when it is being adjusted its normal position rotates, whereas the return of the restoring part in its Normal position is done automatically by part of the movement. It is here too however, it is necessary that a special pointer adjusting shaft is axially adjusted brings the reset part in operative connection with the minute shaft.

Car clocks also show several solutions. Here is the Rücker inevitably when the pointer moves. Disadvantageous in this embodiment it is that a special pointer adjusting shaft must also be present here, which is before the setting of the pointer must be brought into engagement with the movement, so that So the type of pointer setting that is generally used today for this type of watch a setting button on the minute shaft (or with living room clocks by means of Turning the minute hand) is not possible here.

The present invention is based on these common types today of the hand setting by the minute shaft. When adjusting the hands or the minute shaft inevitably becomes a reset part from the minute shaft up to a certain one Maximum angle qg. ", Rotated from its normal position. The reset part is then at a certain time again automatically from a part of the work to its normal position returned: The regulator is moved either when it is unscrewed of the restoring part from its normal position, i.e. when setting the pointer, or Return the part to its normal position.

Accordingly, with a pointer adjustment over a certain amount of time the Rücker shifted each time by a certain amount, the .a gear change of a few seconds per day. When commissioning one on a rate deviation When the clock is adjusted to zero, a very specific one is inevitably created when the hands are set Change of gear; by the time deviation of the clock caused by this and the necessary new positions of the hands, however, this rate deviation is reversed again, because the regulator is automatically shifted back by the same amount, that is resumes its original position. If a gear change occurs over time one, this is almost entirely when the pointer is set or by the inevitable Adjustment of the regulator balanced. For this it is necessary to set the maximum back adjustment to determine which occur when setting the pointer over a certain amount of time allowed. For this purpose, a larger series is preferred from Clocks. which were adjusted to zero rate deviation after a few months the current gear is determined and then the maximum back adjustment is determined.

The object on which the present invention is based is to the adjustment of the regulator by simply turning the minute shaft - without prior axial shifting - to enable so that when adjusting the pointer (through Turning the minute hand or the minute shaft) the reset part automatically is adjusted.

According to the invention, this object is achieved in that the simultaneously Minute shaft serving as hand setting shaft with the reset part via a twisting coupling is constantly in operative connection.

The technical progress that can be achieved by the invention is available all in the fact that now the restoring device in the simplest way without axial Shifting can be actuated, the back adjustment being completely automatic takes place with the pointer adjustment; In addition, there is no need for a special hand shaft, whereby the entire structure of the restoring device is considerably simplified.

In a particularly advantageous embodiment of the subject matter of the invention is the friction clutch between the minute wheel and the minute shaft at the same time designed as a torsion coupling between the latter and the reset part.

In the drawings, exemplary embodiments of the reset device according to the invention are shown, namely FIG. 1 shows a section, FIG. 2 shows a plan view of a device, FIG. 3 and 4 details of the friction clutch between minute shaft and reset part, F i g. Fig. 5 shows a detail of the reset part; F i g. 6 and 7 show a second type of device, FIG. 8 an operative connection between the regulator and the reset part, FIG. 9 and 10 a third type of device. Part 3 is a part that is firmly connected to the minute wheel and has planar knurling on the face 3 '. A part 5 and an expanding spring 4 are firmly connected to the minute shaft 2. The expanding spring 4 has two angled lugs 4 'and 4 "which sit on the knurling of part 3. In normal operation, part 3 and minute shaft 2, so that part 5 and expanding spring 4, have the same angular speed 2 due to the sum or difference of the angular velocities faster than part 3 of the minute wheel, whereby the two claws 4 'are supported on the knurling of part 3 when the pointer is turned clockwise and the two claws 4 "are supported when the pointer is counterclockwise. Characterized two spring arms 4 "respectively stand out and compress itself against the regulator setting member 1, which, supported on the roller 6, which is firmly connected to the minute shaft 2. The regulator setting member 1 is thus taken in accordance with the pointer adjusting movement. The claws 4 ' or 4 " slide over the knurling of part 3. The pin 7, which is fixed to the board, limits the rotary movement of the reset part 1 by means of the opening 8 in the reset part 1. After this maximum rotary movement, the spring arms 4"' slide over the reset part 1 as the pointer moves further. The spring 19, which is attached to the pin 7 fixed to the circuit board and the pin 9 fixed to the reset part, holds the toothed segment 10 of the reset part 1 and the toothed segment 11 of the reset out of engagement during the forced adjustment of the reset part. At the maximum rotational movement of the reset part 1, both arms snap the leaf spring 12 attached to the pin 7 is created in the recesses 13 'or 13 "of the back eiles 1. The reverse movement is now triggered by means of a part of the clockwork. When the reset part 1 was deflected from its rest position, a sheet metal strip 15 was pushed out of its normal position by the cam 18 'or 18 ". As shown in FIGS The stable sheet metal strip 15 rotatably mounted in point 14 clocks pressed into its rest position by means of a pin 17. The sheet metal strip 15 can also represent the hinged armature of an electromagnetic elevator device mounted in point 14. By the movement of the metal strip 15, which is placed on the cam 18 ' or 18 " pushes, the reset part 1 is forced by the leaf spring 12 locked in the grooves 13 'or 13" to first make a pushing movement, whereby the two toothed segments 10 and 11 come into engagement, and then a rotary movement around the minute shaft 2 at the end of this movement, the spring 19 pulls the reset part into the position shown in FIG F i g. 2 position shown.

F i g. Figures 6 and 7 show a second type of reset device. The restoring part 1 is taken along as described above by means of frictional engagement by the expansion spring 4. When the spring arms 4 '''are axially deflected, the restoring part is raised at an angle, as shown by the contour 1'. The spring 20 causes the inclination through which the toothed segments 10 and 11 are disengaged from the normal position during the subsequent rotary movement of the reset part 1. The rotary movement is limited by the pin 7 and the recess 21 of the reset part. After the pointer position has ended, the reset part 1 is again placed on the plate by the spring 20 The two extreme positions of the restoring part, which are identical to those of the device shown in FIGS. 1 and 2, are represented by the contours 1 " and 1"' 1 and 2 in that the pin 17, which is shown here on the swing disk of an electromagnetic elevator device sits, on the deflected sheet metal strip 15 around its pivot point 14, which was also deflected during the inevitable adjustment of the reset part, presses, whereby a sliding of the cam 18 ' or 18 " and thus a rotary movement of the reset part 1 takes place. Since the toothed segments 10 and 11 are in engagement with one another, the indexer is adjusted. A pushing movement, as in the case of the in FIG. 1 and 2 is necessary, does not take place here. Instead of the tooth segments 10 and 11 , as in FIG. 8, the operative connection between the regulator and the reset part can also be established by means of the friction surfaces 10 ' and 11' . Here, too, the reset part and the reset part are brought into operative connection by the leaf spring 20, which presses on the reset part.

A third device is shown in FIGS. 9 and 10. The toothed segment 10 of the reset part and the toothed segment 11 of the reset are in engagement with each other during the adjustment of the minute shaft 2 and the inevitable adjustment of the reset part. The reset part is taken along again, as described above, by frictional engagement by means of the expansion spring 4. The spring 23 holds the toothed segments 10 and 11 in engagement with each other by pressing on the reset part, so that when the minute shaft 2 is adjusted, the regulator is also adjusted. The restoring part is returned to its normal position by a pin 17 on the minute wheel. This pin 17 presses the spring 23 outwards, the reset part being taken along and the operative connection to the regulator being interrupted. When the spring 23 is moved out and the reset part 1 is deflected, the spring 22 brings the reset part back into its normal position. If the pin 17 leaves the spring 23, the toothed segments 10 and 11 snap into operative connection again.

Claims (12)

Claims: 1. Automatic reset device in which at Adjustment of the pointer over a certain amount of time the back adjustment constant is, whereby when advancing the pointer the indexer to process, when resetting the Pointer, however, is set to follow-up and with the return of the reset part in its normal position takes place automatically by part of the clockwork, thereby gekennzeichn e t that when setting the pointer, the shaft that also serves as the pointer setting shaft Minute shaft in operative connection with the reset part via a torsion coupling occurs. 2. Automatic reset device according to claim 1, characterized in that that when adjusting the minute shaft and the inevitable adjustment of the reset part the restoring part and the regulator are out of force and during the return of the reset part into its rest position, the reset part and the regulator non-positively are connected, the work necessary for the reset of the reset part part of the movement that returns to its normal position. 3. Automatic Reset device according to claim 1, characterized in that when adjusting the minute shaft and the inevitable adjustment of the reset part the reset part and the Rücker are non-positively connected, the necessary for the Rücker adjustment Work is derived from the minute shaft and when returning the reset part in its rest position the restoring part and the regulator are out of force. 4th Automatic reset device according to claim 1 to 3, characterized in that that the inevitable adjustment of the restoring part by means of a fixed with the Minute shaft connected expansion spring 4 happens, with the twisting of the Minute shaft opposite the minute wheel the claws 4 'or 4 "on the knurled one Support face 3 'of part 3 of the minute wheel, whereby the spring arms 4 '' 'expand axially and the restoring part from its normal position by means of friction take along. 5. Automatic Rückerstellvorrichung according to claim 1 to 4, characterized in that a preferably on the flywheel or the change wheel or the hour wheel or the minute wheel or the intermediate wheel seated pin 17 at point 14 rotatably mounted sheet metal strip 15 against the cam 18 'or 18 "of the reset part presses, whereby the cam 18 'or 18" slides on the sheet metal strip and thus brings about a return movement of the reset part into its normal position. 6. Automatic reset device according to claim 1 to 4, characterized in that the hinged armature of an electromagnetic elevator device during its tightening movement presses against the cam 18 'or 18 "of the reset part and so by sliding the cam on the hinged armature, a reverse rotation movement of the reset part brings about its normal position. 7. Automatic reset device according to claim 1, 2 and 4 to 6, characterized in that the spring 19 keeps the toothed segments 10 and 11 out of engagement during the adjustment of the minute shaft or the inevitable adjustment of the reset part and the arms of the leaf spring 12 in the extreme position of the reset part snap into the grooves 13 ' or 13 " . B. Automatic reset device according to claim 7, characterized in that characterized in that the grooves 13 'and 13 "are shaped so that during the return movement of the restoring part is initially forced into its normal position a pushing movement, whereby the toothed segments 10 and 11 come into engagement with one another, then to perform a rotary movement, whereby the regulator changes its position. 9. Automatic reset device according to claim 1, 2 and 4 to 6, characterized in that the expansion spring 4 when adjusting the minute shaft or the inevitable adjustment of the reset part raises the reset part by means of its spring arms 4 "'at an angle, so that the toothed segment 10 of the reset part and the toothed segment 11 of the regulator disengage. 10. Automatic restoring device according to claim 1, 2 and 4 to 6, characterized in that the expanding spring 4 when adjusting the minute shaft or the inevitable adjustment of the restoring part raises the restoring part by means of its spring arms 4 "'at an angle, so that the friction surface 10' des Reset part and the friction surface 11 'of the regulator come out of engagement. 11. Automatic Reset device according to claim 1, 2, 4 to 6, 9 and 10, characterized in that that the leaf spring 10 by pressure on the restoring part the toothed segment 10 or the friction surface 10 'of the restoring part and the toothed segment 11 or the friction surface 11 'of the regulator brings into operative connection with one another. 12. Automatic reset device according to claim 1, 3 and 4, characterized in that the pin 17, which preferably sits on the minute wheel or the change wheel or the hour wheel or the intermediate wheel or the flywheel in electromagnetically wound clocks, deflects the leaf spring 23 23 ', wherein the restoring part is carried along and the toothed segments 10 and 11 disengage so that the spring 22 returns the adjusted restoring part to its normal position. References considered: U.S. Patent Nos. 2,948,109, 2,955,411; British Patent No. 787 002.