The present invention relates to chronograph mechanisms, and more particularly to the chronograph mechanisms which are designed to equip mechanical timepieces.
The object of the prevent invention is to provide a chronograph mechanism which is entirely mechanical, and makes it possible to measure durations with high precision, and preferably a precision greater than a hundredth of a second, for example a thousandth of a second, whilst maximising the power reserve of the mechanism and avoiding premature wear of its components.
At the end of March 2011, the brand Tag Heuer presented a mechanical chronograph design (named the Mikrotimer Flying 1000) which is reputed to be capable of measuring and displaying thousandths of a second. According to the information available, this chronograph mechanism comprises a regulator unit in the form of a spring which oscillates at a frequency of 500 Hz, i.e. 3,600,000 alternations per hour. The chronograph display comprises two central hands. The first hand performs 10 rotations per second, indicating the thousandths and hundredths of a second on a scale of 100 graduations around 360°. A second, smaller, central hand indicates the minutes and twelfths of a minute on a scale of 150 seconds.
However, this chronograph mechanism is very complicated, since it differs from the conventional horological regulator in the form of a spring balance. Also, because of the high frequency of the oscillator, the chronograph mechanism uses a large amount of energy, resulting in the fact that it has a power reserve of only 150 seconds. This high frequency can also give rise to premature wear of the components of the chronograph mechanism. In addition, since the display of the chronograph counter is not produced entirely on a decimal basis, it is difficult for the user to read easily and immediately the time which has passed.
In order to alleviate these disadvantages, the object of the present invention is a chronograph mechanism comprising a control device and chronograph gear train which are designed to be driven directly or indirectly by a barrel, this chronograph gear train comprising a second-counter mobile and a mobile with a first precision corresponding to a first fraction of a second; this chronograph mechanism also comprising at least one indicator which displays the seconds and first fractions of a second of the duration measured; the chronograph gear train comprising an additional mobile with a second precision corresponding to a second fraction of a second, which is driven by the mobile for the first fraction of a second by means of a mobile compensating the backlash; and the chronograph mechanism also comprising an indicator for the second fractions of a second, which are smaller than the first fractions of a second, of the duration measured, which indicator is actuated by the said additional mobile.
The object of the present invention is also a mechanical timepiece, for example a pocket watch or a wristwatch, provided with a chronograph mechanism according to that described in claim 1.
The appended drawing illustrates schematically and by way of example a part of the chronograph mechanism according to the invention, and a wristwatch provided with a chronograph mechanism of this type.
The present chronograph mechanism comprising a control device with one or two push-buttons which permit control of the start, stop and resetting functions, and chronograph gear train which drive the different counters, i.e. minute counters, second counters etc., can be of the type with a column wheel or cam. Furthermore, this chronograph mechanism can be designed to equip either a conventional timepiece, in which case the chronograph gear train is driven indirectly by the drive barrel of the timepiece, or a timepiece such as described for example in document CH 697433, in which case the chronograph gear train is driven directly by a chronograph barrel which is separate from the drive barrel of the timepiece.
In fact, the present chronograph mechanism is distinguished from the existing chronograph mechanisms in that it is designed such as to be able to measure and display durations with a first precision corresponding to a first fraction of a second (for example hundredths of a second) as well as with a second precision corresponding to a second fraction of a second which is smaller than the first one (for example thousandths of a second), the mobile used to count the first fractions controlling an additional mobile which is used to count the second fractions by means of a mobile compensating the backlash. By this means, the mechanism can comprise a regulator unit which oscillates at a frequency corresponding to the first precision, without needing a regulator unit which oscillates at a higher frequency.
A preferred embodiment of the chronograph mechanism makes it possible to measure durations with precision of a thousandths of a second on the basis of a counter for hundredths of a second.
The present chronograph mechanism is differentiated from the known chronograph mechanisms in that its gear train and control device comprise novel and original characteristics.
Consequently, hereinafter only the chronograph gear train and part of the control device of the chronograph will be described in detail, the remainder of the chronograph mechanism being conventional and well known to persons skilled in the art.
The chronograph gear train of the present chronograph mechanism is illustrated as a whole more particularly in
The multiplication ratios of this chronograph gear train is such that, if the second-counter mobile 1 is driven at the rate of one revolution per minute, the hundredths mobile 3 performs one revolution per second.
Up to this point these chronograph gears are conventional, and are well known to clock and watch makers.
The essential and novel characteristic of the present chronograph gear train consists in the fact that they also comprise a mobile 4 compensating the backlash, which connects the plate 3.2 of the hundredths mobile kinematically to the pinion 5.1 of an additional or rapid mobile 5. This additional mobile 5 (sometimes called the thousandths mobile hereinafter) comprises a shaft 5.2 which is integral with the pinion 5.1 and a plate 5.3 of this additional or rapid mobile.
The multiplication ratio between the plate 3.2 of the hundredths mobile and the plate 5.3 of the thousandths mobile is such that this additional mobile 5 performs a revolution in a tenth of a second, i.e. ten revolutions per second in the example illustrated. The plate 5.3 of the additional mobile 5 comprises a toothing consisting of a hundred teeth in the example illustrated.
The shaft 5.2 of the additional mobile 5 bears a hand 6 which co-operates with a graduation 7 of the dial, this graduation 7 comprising a hundred divisions which correspond to thousandths of a second. Thus, this display 6, 7 makes it possible to display the hundredths and thousandths of a second, as can be seen in
This mobile 4 compensating the backlash comprises a central shaft 4.1 which is integral with a support pinion 4.2 and a support plate 4.3.
Sandwiched between the support pinion 4.2 and the support plate 4.3 there are fitted in a non-integral manner, i.e. freely, a free pinion 4.4 and a free plate 4.5.
The free pinion 4.4 has dimensions and a number of teeth which are identical to the support pinion 4.2, and the free plate 4.5 has dimensions and a number of teeth identical to the support plate 4.3.
The free pinion 4.4 is integral with a balance 4.6 whereas the free plate 4.5 is integral with a hub 4.7. A helical spring 4.8 is secured by means of its inner end to the hub 4.7 and by means of its outer end to the balance 4.6.
The free pinion 4.4 and the support pinion 4.2 both engage with the toothing of the plate 3.2 of the hundredths mobile 3, whereas the free plate 4.5 and the support plate 4.3 both engage with the pinion 5.1 of the additional mobile 5.
This mobile 4 compensating the backlash has three specific functions.
The first function is useful during stoppage of the chronograph mechanism. In fact, since the additional mobile 5 can be stopped between two steps, tension in addition to the normal tension may occur in the chronograph gear train. Since the mobile 4 compensating the backlash permits a certain angular offsetting, consisting of at least the value of one step of the pinion 5.2 of the additional mobile 5, the additional tension can be avoided.
The second function is that since the additional mobile 5 is at the end of the gear train and is not subjected to stress, it is important for it to be engaged with a mobile compensating the backlash, otherwise uncontrollable jumps would occur because of the backlash of the gear train and stoppage of the additional mobile 5 would then be random.
More particularly, if during assembly the support plate 4.3 and the free plate 4.5 are coupled by means of the pinion of the thousandths mobile 5.1, then the free pinion 4.4 is rotated by X°, and finally the support pinion 4.2 and the free pinion 4.4 are coupled by means of the plate of the hundredths mobile 3.2, it will be found that the free pinion 4.4 and the free plate 4.5 will tend to return to the neutral position they were in before the free pinion 4.4 was turned by X°, and consequently an angular difference will be created between the support pinion 4.2 and the free pinion 4.4, and also between the support plate 4.3 and the free plate 4.5. This fact compensates the gear backlash.
The third function is to convert the jerky rotation caused by the escapement into continuous rotation by means of the inertia of the additional mobile 5, and complementarily by means of the first function of the mobile 4 compensating the backlash. This third function results in the fact that the thousandth (in this case) will be regulated between each step.
Thus, any variation of the thousandth caused by an impact, or any other disturbances of the watch, will be reset and reinitialised in the following step, thus avoiding any cumulative error.
According to the invention, by incorporating a mobile compensating the backlash in the chronograph gear train, it is possible for the chronometry of a high-precision chronograph to form the basis of a regulator unit which oscillates at a lower frequency (for example from 18000 to 400000), which makes it possible to increase the power reserve of the mechanism. For example, in the examples illustrated, the power reserve of the chronograph mechanism is at least 15 minutes, despite its precision to a thousandth of a second.
According to variants, the mobile compensating the backlash could be produced in a manner different from that previously described.
According to other variants of the chronograph gear train, it is possible to display by means of the hand 6 and the graduation 7 a value other than thousandths of a second, i.e. the second fraction of a second measured and displayed by the chronograph mechanism is different from a thousandth of a second. It is sufficient for this purpose to modify the multiplication ratio between the hundredths mobile 3 and the additional mobile 5 in order for the latter to rotate at a speed other than ten revolutions per second, for example five or twenty revolutions per second; the fraction of a second displayed by the graduation 6, 7 will no longer be a thousandth of a second but another value.
More generally, according to yet other variants, the mobile 4 compensating the backlash can be positioned between the additional mobile 5 and a first mobile which is used to count a first fraction of a second which is different from a hundredth of a second. For example, the first fraction can be a tenth of a second and the second fraction can be a hundredth of a second, the mobile compensating the backlash being positioned between a mobile for tenths of a second and an additional mobile for hundredths. In this case, a chronograph mechanism according to the present invention can use a regulator unit which performs 36,000 alternations per hour, whereas the mechanical counters according to the prior art which are capable of providing precision of a hundredth of a second typically use a regulator unit which performs 360,000 alternations per hour. Consequently for a given precision, the power reserve of a chronograph according to the present invention can be increased substantially, whilst preventing premature wear of its components. It will also be noted that in the preceding example, a single hundredths hand can display the first and second fractions of a second.
According to a variant embodiment, the display of the second fraction of a second could be carried out in a sectorial form. In the example in
When the chronograph is in the “resetting” phase, the sensing pin 9 is raised, and the hand 10 is placed on a neutral area of the graduation 12 (before the zero in
When a sectorial display as previously described is selected, tenths and hundredths of a second will be displayed by a hand which is integral with the shaft of the hundredths mobile 3, which co-operates with a corresponding graduation supported by the dial.
The chronograph mechanism also comprises a control device with one or two push-buttons which control the starting, stoppage and resetting of the chronograph mechanism. This control device is conventional, and can be of the column wheel or cam type.
In the case of the present chronograph mechanism, this control device also comprises clips 13, 14 which are pivoted at O, and each comprise a control sensing pin 13.1, 14.1 which co-operates with the column wheel 15 or the cam of the control device and a retention nose 13.2, 14.2 which co-operates with the toothing of the plate 5.3 of the additional mobile, in order to keep it stopped in a specific stable position.
The column wheel 15 can be the same as that of the chronograph mechanism, or it can be an independent column wheel, but in this case actuated by the same push-button of the control device.
According to a variant embodiment, the clips 13, 14 can be replaced by a locking device which is controlled by the column wheel 15.
In the embodiment described of the chronograph mechanism, the additional mobile 5 or rapid mobile returns to the zero position by means of the ratio which exists between the hundredths mobile 3 and the additional mobile 5, and because of the fact that the chronograph gear train rotate to return to zero.
According to a variant, the mobile 4 compensating the backlash and the additional mobile 5 can be assembled with a conventional chronograph gear train, but in this case it will be necessary to add a lantern core onto the additional mobile in order to ensure that it is reset by a hammer.
A mobile compensating the backlash as previously described could also be used in other applications where it is desirable to compensate backlash and/or avoid additional tension in the gear train of a horological movement.
Number | Date | Country | Kind |
---|---|---|---|
0641/11 | Apr 2011 | CH | national |
Number | Name | Date | Kind |
---|---|---|---|
1350131 | Anderson | Aug 1920 | A |
4270197 | Minowa | May 1981 | A |
5339293 | Kamiyama et al. | Aug 1994 | A |
6567345 | Furukawa et al. | May 2003 | B1 |
7974156 | Papi et al. | Jul 2011 | B2 |
8066428 | Behling | Nov 2011 | B2 |
20080106979 | Bron et al. | May 2008 | A1 |
20090103398 | Robin | Apr 2009 | A1 |
20110096635 | Calabrese | Apr 2011 | A1 |
20110164477 | Jolidon | Jul 2011 | A1 |
20120243386 | Semon | Sep 2012 | A1 |
Number | Date | Country |
---|---|---|
697433 | Oct 2008 | CH |
Entry |
---|
First Look: Mikrotimer Flying 1000, Mar. 24, 2011, Calibre 11, <http://www.calibre11.com/tag-heuer-mikrotimer-flying-1000/>, pp. 1-5. |
Number | Date | Country | |
---|---|---|---|
20120257480 A1 | Oct 2012 | US |