EP0211285A2 - Wrist watch - Google Patents

Abstract

On the one hand, the display elements of a wristwatch rotate continuously, such as the second, minute and hour hands, but on the other hand they only change their position at certain times, such as the signal ring for calendar display. The energy store of the watch, ie the battery in an electric wristwatch, must, however, be designed for the highest torque requirement that arises with these display elements, which are only actuated from time to time.

In order to keep the torque as low as possible at these display elements which only change their position at certain times, it is proposed according to the invention that a non-uniformly driving gear is inserted between the adjustment mechanism of these display elements and the gear train, which gear is designed so that the largest (smallest) Torque occurs at the time of changing the position of these indicators.

Description

The invention relates to a wristwatch, preferably an electrically (electronically) operated wristwatch, the display elements of which are driven by a clockwise rotating drive (balance wheel, stepper motor) via a gear train, the display elements on the one hand continuously rotating hands (second, minute, hour hands) ) and on the other hand serve signal rings (signal disks, special pointers) that only change their position at certain times.

A typical display element of the second type, which only changes its position at certain times, is the indication of the calendar day. The calendar days from 1 to 31 are shown on a signal ring, which is rotated one step further to the next display by the clockwork of the clock every day, at around midnight. Around To carry out rotation only for a limited period of time at 0.00 am, the signal ring carrying the calendar data is generally provided with an additional jump adjustment mechanism or with a mechanism such as that shown in DE-GM 19 07 388, for example, which operates within a relatively short time the adjustment causes. Both for the uniform twisting movement of the signal ring within a certain relatively short period of time, and to an increasing extent for the sudden twisting movement of this signal ring ^q, it is necessary, over a short period of time, to produce a relatively large amount of power from the energy accumulator of the watch, i.e. a spring accumulator or one Battery, must be applied. This force must therefore be available over the entire operating time of the watch, although it is only required for a short period of time within a day. This deficiency is particularly noticeable in modern electric wristwatches, which have to be as small and light as possible and which should also ensure a very long service life for the battery used. However, the service life of the battery depends not only on the internal battery structure, but also on the power consumption or the power requirement by the clockwork. It is not only the amount of the withdrawal that is decisive, but also the fluctuations in the size of this withdrawal. Such batteries used in modern wristwatches are designed, in particular, to deliver a relatively low current over a very long time. Current peaks, such as those required for calendar adjustment, have an extremely reducing effect on the overall service life of such batteries.

In particular for this reason caused by the type of energy store, elegant and dainty, light and small wristwatches that can only hold a small battery are not equipped with a calendar display.

The object of the invention is to provide a possibility for a rotary movement of the signal rings, which change their position only at certain times, which only requires a slight increase in the power consumption from the energy store when this rotary movement is carried out, so that a total power draw is required results, whose minima and maxima are as close together as possible.

This is achieved according to the invention in that rings are inserted between the adjusting mechanism of this signal and the gear train, a non-uniform abortive gear.

Non-uniformly abortive gears are, for example, elliptical gears or also gears in which an eccentrically mounted circular gear works together with a non-circular counter gear. In all cases, the driving wheel is rotated uniformly by the clockwork or by the clockwise rotating drive of the clockwork, while the driving wheel performs a non-uniform rotary movement or has uneven angles of rotation per unit of time. Corresponding to the non-uniform rotary movement, the gear ratio changes constantly, which changes between two extremes, the gear ratio extremely slow and that extremely fast. However, not only the rotational movement is non-uniform, but also the torque of the driven wheel, which reciprocally follows the change in the rotational speed. Thus, due to the non-uniform abortion Gear the highest torque then to be adjusted to the organ to be adjusted, that is to the adjusting mechanism, if this organ is to be actuated. However, this also ensures that the high peak power or high power consumption is not required at this time, but that a high torque at the output is available due to this extreme translation into slow speed at this time, although the drive torque hardly increases.

It should be borne in mind that practically no force is required to turn the gear train over the entire remaining time up to ₇ u the time the position ring of the signal ring etc. changes, so within this period the reduction in torque at increased rotational speed does not result in increased power consumption from the energy accumulator .

Instead of applying the highest torque at the changeover time, the other extreme than the high rotational speed can of course also be used for an operation at this time. This is the case, for example, when a contact ring is to be rotated, which is only intended to give a contact pulse, the torque only playing a very minor role, but it is important that only one wiping contact occurs. Under certain circumstances, this can save additional snap elements that are otherwise necessary.

The speed ratio between the cooperating wheels of the non-uniformly driven gear will generally be 1, but can also be a multiple thereof. Especially when changing the calendar, you will usually choose a speed ratio of 1 and provide a cycle time of one day for the driven wheel. However, this speed ratio, like this orbital period, is not mandatory; Larger ones are quite conceivable Speed ratios, as well as the rotation of the driven wheel within a period corresponding to the usual time units, i.e. within a minute, an hour, a half day, a day, a week, a month or a year.

Since, as a rule, the non-uniformly abortive gear must be arranged outside the actual gear train, i.e. above or below the work plate of the clockwork, the wheels of this gear train must therefore be removed before maintenance of the gear train, it is recommended according to the invention that one of the Wheels of the cooperating pair of wheels of the non-uniformly abortive gear have a tooth with a larger tooth height relative to the other teeth and the other gear at the correct mutual position of the two wheels of this pair of wheels each has a correspondingly larger gap or several such gaps. This ensures that the two wheels of this pair of wheels are always used in the correct mutual position.

• Fig. 1 zwei miteinander in Eingriff stehende Ellipsenräder,
• Fig. 2 die Drehgeschwindigkeits-Kurven des antreibenden und des abtreibenden Rades,
• Fig. 3 die entsprechenden Drehmoment-Kurven,
• Fig. 4 ein Getriebe mit außermittigem Kreisrad und unrundem Gegenrad,
• Fig. 5 die Drehgeschwindigkeitskurve und
• Fig. 6 die Dremomentenkurve zu diesem Getriebe nach Fig. 4,
• Fig. 7 ein Getriebe mit dem Drehzahlverhältnis 2,
• Fig. 8 ein Getriebe mit dem Drehzahlverhältnis 3 und
• Fig. 9 die Ansicht bei einem vergrößerten Zahn eines Radpaares.

Exemplary embodiments of such a non-uniformly abortive gear are shown in the drawing, namely:

• 1 two interlocking elliptical wheels,
• 2 shows the rotational speed curves of the driving and the driven wheel,
• 3 shows the corresponding torque curves,
• 4 a gear with an eccentric circular wheel and a non-circular counter wheel,
• Fig. 5 shows the speed curve and
• 6 shows the torque curve for this transmission according to FIG. 4,
• 7 is a gear with the speed ratio 2,
• Fig. 8 shows a transmission with the speed ratio 3 and
• Fig. 9 is a view of an enlarged tooth of a pair of wheels.

The driven wheel 1 of a non-uniformly driving gear formed with two congruent elliptical wheels meshes with the driving wheel 2. If the driven wheel 1 is driven uniformly by the clockwork of the clock or its drive, the driving wheel 2 has a rotational speed as it results from Fig. 2 can be seen. 2, the time axis of which is subdivided into equal time periods, shows how the non-uniformly driving gear is converted into the uniform speed ω 1 of the driven wheel 1 into an extremely non-uniform rotational speed ω 2 of the driving wheel 2. Correspondingly, it is formed also the torque curve, as can be seen from FIG. 3, wherein the uniform torque M1 is converted into the non-uniform torque M2. This course of rotational speed or torque is repeated periodically, it being possible, for example to drive a signal ring for a calendar display, to set the repeating times t1 to the 0.00 o'clock changeover time. At this point in time tl, the greatest torque is present on the driven wheel 2, or the lowest power is required by the drive from the clockwork side to rotate the signal ring.

Both wheels of the pair of wheels of this non-uniformly driven gear have shafts 11, 12, on which further circular wheels, or in the case of the driven wheel, drivers are arranged. The driven wheel is connected to the clockwork and the driven wheel to the display element via these elements.

The same applies to the non-uniformly abortive gear according to FIGS. 4 to 6, which has an eccentrically mounted circular wheel 3, which cooperates with a non-circular counter wheel 4. Again, there are both non-uniform rotary movements ω 4 of the driven wheel 4 compared to the uniform rotary movement ω 3 of the driven wheel 3. Of course, the same reciprocal torque curve as shown in FIG. 6 also results.

The previously described, non-uniformly abortive gears have a speed ratio of 1, with one revolution of the driven wheel 1, 3 corresponding to one revolution of the abortive wheel 2, 4. FIG. 7, on the other hand, shows a non-uniformly driven gear with a speed ratio of 2, so that the driven eccentrically mounted circular wheel 5 has to make two rotations in order to cause one rotation of the driven wheel 6. Thus, with each revolution of the driven wheel 5, only two rotational movement minima and only one rotational movement maxima or two torque maxima and only one torque minima arise. Fig. 8 finally shows a speed ratio of 3, in turn an eccentrically mounted, driven wheel 7 acting on a non-circular abrading wheel 8 and the driven wheel 7 having to make three revolutions for one revolution of the aborting wheel 8. Correspondingly, only one rotation maxima and one rotation movement minimum or two torque minima and one torque maximum arise in one revolution of the driven wheel 7.

FIG. 9 finally shows a view of the pair of wheels in which a larger tooth 9 is provided in a gear 1, each of which has a correspondingly larger gap 10 as taking into account the gear ratio corresponds to several such gaps 10 in the meshing wheel 2 with it. This ensures a clear adjustment of the meshing gears (1/2, 3/4, 5/6 7/8) as well as simple assembly.

Claims (7)

1. Wristwatch, preferably an electrically (electronically) operated wristwatch, the display elements of which are driven by a clockwise rotating drive (balance wheel, stepper motor), the display elements on the one hand constantly rotating hands (second, minute, hour hands) and on the other hand, signal rings (signal disks, special pointers) which change their position are used only at certain times via adjusting mechanisms, characterized in that a non-uniform abortive gear is inserted between the adjusting mechanism of these signal rings and the gear train. 2. Wristwatch according to claim 1, characterized in that the non-uniform abortive gear is an elliptical gear train (1, 2). 3. Wristwatch according to claim 1, characterized in that the non-uniformly abortive gear is an eccentrically mounted circular wheel (3, 5, 7) cooperating with a non-circular counter wheel (4, 6, 8). 4. Wristwatch according to one or more of the preceding claims, characterized in that the speed ratio between the cooperating wheels (1/2, 3/4, 5/6, 7/8) of the non-uniform abortive gear 1 or a multiple thereof. 5. Wristwatch according to one or more of the preceding claims, characterized in that the driven wheel (1, 3, 5, 7) of the non-uniformly abortive gear with one revolution within a period corresponding to the usual time unit (minute, hour, half day, day , Week, month, year). 6. Wristwatch according to one or more of the preceding claims, characterized in that the rotational speed of the driven wheel (2, 4, 6, 8) of the non-uniformly driven gear reaches an extreme value at the time of changing the signal ring. 7. Wristwatch according to one or more of the preceding claims, characterized in that one of the wheels (1, 3, 5, 7) of the cooperating pair of wheels (1/2, 3/4, 5/6, 7/8) of the non-uniformly abortive Gear a tooth (9) with a larger tooth height relative to the other teeth and the other gear (2, 4, 6, 8) at the point corresponding to the correct mutual position of the two wheels of this pair of wheels a correspondingly larger gap (10) or more has such gaps (10).

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