EP3333640A1 - Running time equation mechanism controlled by a differential device - Google Patents

Abstract

The invention relates to a walking time equation mechanism comprising a switch whose function is to indicate the solar time or true time by means of a hand of the hours of the civil time (46) and a hand of the minutes of the true time (50) concentric with the hand of the hours of the civil time (46), the switch being devoid of a hand of the minutes of the civil time, the hour hand of the civil time (46) being driven in rotation by a watch movement and in turn driving the minute hand of true time (50), the walking time equation mechanism (44) also including a time equation cam (54) having a profile which is determined by the difference, for each day of the year, between the mean solar time or the civil time, and the solar time or true time, this equation of time (54) being rotated due to a revolution per year by the watch movement, the position of the needle of The minutes of the true time (50) being determined by the position of the time equation cam (54).

Description

Technical field of the invention

The present invention relates to a walking time equation mechanism for a timepiece. More specifically, the invention relates to a walking time equation mechanism driving a minute hand of the true time concentric to an hour hand.

Technological background of the invention

As we know, there is a gap between the true solar time which corresponds to the duration that elapses between two consecutive zenith passages of the Sun at the meridian of the same place, and the mean solar time or civil time which is the average, made over the year, the duration of all solar days true. This difference between the civil time and the true time reaches +14 min 22 s on February 11, and -16 min 23 s on November 4. These values vary little from year to year.

To indicate the time difference between the civil time and the true time, some timepieces include, in addition to the hand which indicates the minute of the civil time, a so-called time equation mechanism which includes a needle which moves next to a graduated scale to indicate the difference between the minute of the civil time and the minute of the solar time for a given day. This minute hand of the true time is actuated by a weather equation cam whose profile is determined by the difference between the mean solar time and the true solar time for all the days of the year.

Another mechanism for indicating the time difference between the civil and the real time is known as the walking time equation. The turnout of a timepiece equipped with a walking time equation mechanism comprises two concentric minute hands, one indicating the minute of the civil time, and the other indicating the minute of the true time. At any moment, the difference between the minute hand of the civil time and the minute hand of the true time is determined by the difference between the mean solar time and the true solar time for the day of the year considered. As in the case of the equation of time mechanism, the minute hand of the true time of a walking equation mechanism is actuated by a time equation cam.

The equation of time cam is rotated at the rate of one revolution per year from a date mechanism that can be simple or perpetual. The simple calendar is a mechanism arranged to indicate the day of the week, the day of the month, the month of the year or the phases of the Moon, but which does not take into account the variation of the number of days in the month. (months of 28, 29 or 30 days). In other words, the user of a watch having a simple date mechanism will have to perform a manual correction every month ends that are less than 31 days. For example, February 28 or April 30 will require manual intervention. With regard to the perpetual calendar mechanism, it allows, as a simple date mechanism, to indicate the day, the date, the month and the phases of the Moon. But unlike a simple date mechanism, a perpetual calendar mechanism automatically takes into account the length of the months (28, 29 and 30 days), without manual intervention. A perpetual calendar mechanism therefore automatically takes into account leap years.

An example of a walking time equation mechanism is disclosed by the European patent application EP 1 286 233 A1 in the name of the Claimant. The figure 1 attached to this patent application is resumption of the European patent application EP 1 286 233 A1 mentioned above and illustrates a walking time equation mechanism driven by a differential device.

In this figure is notably visible an equation cam of time 1 whose profile is determined by the difference, for each day of the year, between the mean solar time or civil time and the true solar time. This equation of time 1 cam is rotated at a rate of one revolution per year from a simple or perpetual calendar mechanism that includes the timepiece. Equation cam of time 1 carries a disc of months 2 which rotates at the same speed as it and which makes it possible to make coincide the position of this equation cam of time 1 with the date indicated by the date mechanism so that the minute hand of solar time 4 indicates the exact offset between the minute of the civil time and the minute of the solar time.

The date mechanism, simple or perpetual, can be of any known type and will not be described here in its entirety. For a good understanding, it suffices to know that this date mechanism drives the equation cam of time 1 at the rate of one complete revolution per year. However, it is shown for illustrative purposes only a date mobile 6 driving a needle 8 which indicates the date (1 to 31). This mobile date of 6 rotates at a rate of one complete turn per month. It is actuated by the date mechanism and drives the time equation cam 1 via an intermediate date wheel 10 which makes it possible to reverse the direction of rotation, and a reduction wheel 12 which makes it possible to reduce the speed of rotation. rotation of one full turn per month to one full turn per year.

The minute hand of the solar time 4 is driven by a differential gear device 14 which has respective inputs a gear train driving a minute hand of the civil time 18, and a rake 20 which cooperates with the time equation cam 1 (on the figure 1 , the rake 20 is represented in its two extreme positions, once in solid line, and the other time in dotted lines). More precisely, as is visible on the figure 1 , the differential gear device 14 comprises at least one and, preferably, two planet gears 22 driven by the timer of the watch movement of the watch. These two planet gears 22 are able to turn on themselves and to roll on the internal toothing 24 of an equation wheel of time 26. The latter also has on its outer periphery a first toothed sector 28 by which it co-operates with a second toothed sector 30 which is provided with the rake 20 at one of its ends. This rake 20 is subjected to the return action of a spring (not shown) attached to the frame of the watch and which tends to apply a feeler 32 forming the other end of the rake 20 against the profile of the equation cam The solar weather display gear includes a sun time display pinion 34 placed in the center of the differential gear device 14. This sun time display pinion 34 meshes with the planet gears 22, and on the other hand a display wheel of the solar time 38 which meshes with a roadway 40 on the barrel from which is driven the minute hand of the solar time 4. This wheel 38, 40 allows to to return the display of the solar minute to the center 42 of the clockwork movement of the watch, so that the minute hand of the solar time 4 is concentric with the minute hand of the civil time 18.

The walking time equation mechanism just described works as follows.

In normal operation of the watch, the time equation cam 1, the rake 20 and therefore the equation wheel of time 26 are immobile. On the other hand, the planet gears 22 are driven by the watch movement of the watch. They therefore turn on themselves and roll on the internal toothing 24 of the equation wheel of time 26, driving the display pinion of the solar time 34 in rotation, which allows the minute hand of the solar time 4 to turn concomitantly with the minute hand of civil time minutes 18. The difference between the minute hand of the solar time 4 and the minute hand of the civil time 18 therefore remains constant over a period of 24 hours.

Once a day, around midnight, the equation cam of time 1 rotates, driven by the date mechanism that moves the calendar from one day to the next. At this precise moment, the feeler 32 which is in contact with the profile of the equation cam of the time 1 rotates the rake 20 in turn. This rake 20, by pivoting, drives the equation wheel of the time 26. rotation. The planet gears 22 being, during this brief time interval, substantially immobile (they turn one on their own in one hour), rotate on themselves while being rotated by the equation wheel of time 26, and in turn drive the sun time display gear 34 so as to again exactly adjust the position of the minute hand of the solar time.

The walking time equation mechanism described above thus allows, by means of a minute hand of the civil time and a minute hand of the solar time, to display at any time the time difference between the mean solar time and the true time.

It has been realized, however, that the reading of civil time, or true time, was not the most convenient. Indeed, if, with a mechanism in which the minute hand of the civil time and the hand of the minutes of the true time are concentric, we can easily appreciate the time difference which separates the minute from the civil time and the minute of the however, it is more difficult to read on his watch the time it is, whether it is the civil time or the solar time. Indeed, the user is often forced to remember which of the minute hands corresponds to civil time and solar time, even if the minute hand of true time carries a symbol to differentiate it from the minute hand of time civil. Then, after identifying the minute hand of the civil time, the user must still make an effort to mentally reconstruct the civil time by identifying the respective positions of the hour hand of the civil time and the minute hand of the civil time. We will understand that this is not very convenient for a user who wants to read the time on his watch at a quick glance. In addition, at certain times of the year, when the difference between the minute of the civil time and the minute of the true time is small, it is difficult to appreciate visually this difference because of the concentricity of the two hands of the minutes of the time civil and minutes of true time.

Summary of the invention

The present invention aims to overcome the problems described above as well as others by providing a walking time equation mechanism controlled by a differential gear device which is particularly easier to read.

For this purpose, the present invention relates to a walking time equation mechanism comprising a switch whose function is to indicate the solar time or true time by means of a hand of the hours of the civil time and a needle minutes of the true time concentric with the hand of the hours of the civil time, the switch being deprived of a hand of the minutes of the civil time, the hand of the hours of the civil time being driven in rotation by a clockwork movement and resulting in turn the minute hand of true time, the equation mechanism of the walking time also including a time equation cam having a profile that is determined by the difference, for each day of the year, between the mean solar time or civil time, and solar time or true time, this time equation cam being rotated at the rate of one revolution per year by the watch movement, the position of the minute hand, u true time being determined by the position of the equation cam of time.

• le mécanisme d'équation du temps marchante comprend également un dispositif à engrenage différentiel dont une première entrée est constituée par une roue de chaussée qui est entraînée par le mouvement d'horlogerie et qui fait un tour en 1 heure, et dont une seconde entrée est constituée par la came d'équation du temps, le dispositif à engrenage différentiel étant agencé de manière concentrique par rapport à l'aiguille des minutes du temps vrai ;
• le dispositif à engrenage différentiel comprend un mobile satellite réducteur via lequel un pignon de chaussée sur lequel est fixée la roue de chaussée entraîne un canon des heures du temps civil sur lequel est chassée l'aiguille des heures du temps civil, et un mobile satellite multiplicateur via lequel le canon des heures du temps civil entraîne un canon des minutes du temps vrai sur lequel est chassée l'aiguille des minutes du temps vrai ;
• le mobile satellite réducteur permet de réduire la vitesse de rotation d'un tour complet par heure à un tour complet par douze heures, et le mobile satellite multiplicateur permet d'augmenter la vitesse de rotation d'un tour complet en douze heures à un tour complet par heure ;
• le mobile satellite réducteur et le mobile satellite multiplicateur tournent sur eux-mêmes en décrivant une trajectoire circulaire centrée sur le canon des minutes du temps vrai ;
• le mobile satellite réducteur et le mobile satellite multiplicateur se trouvent à égale distance du canon des minutes du temps vrai ;
• le mobile satellite réducteur et le mobile satellite multiplicateur sont portés libres en rotation par un bâti de différentiel dont le canon des heures du temps civil est solidaire ;
• le mobile satellite réducteur et le mobile satellite multiplicateur sont montés pivotants autour d'une première goupille, respectivement d'une seconde goupille, fixées dans le bâti de différentiel ;
• le mobile satellite réducteur comprend une première roue de satellite solidaire d'un premier pignon de satellite ;
• le pignon de chaussée engrène avec la première roue de satellite, et le premier pignon de satellite roule sur une première denture intérieure d'une couronne de différentiel fixe, ce qui a pour effet de faire tourner le bâti de différentiel ;
• la seconde roue de satellite engrène avec le canon des minutes du temps vrai, et le second pignon de satellite roule sur une seconde denture intérieure d'une couronne de différentiel mobile qui est reliée cinématiquement à la came d'équation du temps ;
• la couronne de différentiel mobile est commandée en pivotement par un levier d'équation du temps muni d'un bec palpeur par l'intermédiaire duquel le levier d'équation du temps suit le profil de la came d'équation du temps ;
• le levier d'équation du temps est maintenu en appui élastique contre le profil de la came d'équation du temps par un ressort ;
  le levier d'équation du temps est pourvu d'une première dent en prise avec une seconde dent correspondante prévue sur la couronne de différentiel mobile pour commander le déplacement de cette dernière ;
• le bâti de différentiel comprend un bâti supérieur fixé sur un bâti inférieur au moyen d'au moins une vis.

In accordance with other features of the invention which are the subject of the dependent claims:

• the walking time equation mechanism also comprises a differential gear device whose first input is constituted by a road wheel which is driven by the watch movement and which makes a turn in 1 hour, and a second input of which is constituted by the time equation cam, the differential gear device being arranged concentrically with respect to the minute hand of the true time;
• the differential gear device comprises a reduction gear mobile via which a road gear on which is fixed the road wheel drives a gun of the civil time hours on which is driven the hour hand of the civil time, and a satellite mobile multiplier via which the canon of the hours of the civil time causes a canon of the minutes of the true time on which is driven the minute hand of the true time;
• the reducing satellite can reduce the rotational speed of a complete revolution per hour to one complete revolution per twelve hours, and the multiplier satellite mobile can increase the rotational speed of a complete revolution in twelve hours to a lap complete per hour;
• the reducing satellite mobile and the multiplying satellite mobile rotate on themselves by describing a circular trajectory centered on the canon of the minutes of the true time;
• the reducing satellite mobile and the multiplying satellite mobile are equidistant from the minute canon of the true time;
• the reducing satellite mobile and the multiplier satellite mobile are rotated freely by a differential frame whose civil time clock is secured;
• the reducing satellite mobile and the multiplier satellite mobile are pivotally mounted about a first pin, respectively a second pin, fixed in the differential frame;
• the reducing satellite mobile comprises a first satellite wheel secured to a first satellite gear;
• the road gear meshes with the first satellite wheel, and the first satellite gear rolls on a first internal toothing of a fixed differential ring, which has the effect of rotating the differential frame;
• the second satellite wheel meshes with the minutes barrel of true time, and the second satellite gear rolls on a second internal toothing of a movable differential ring which is kinematically connected to the equation cam of time;
• the mobile differential ring is pivotally controlled by a time equation lever provided with a probe nose through which the equation of time lever follows the profile of the equation cam of time;
• the time equation lever is held resiliently against the profile of the equation of time cam by a spring;
  the time equation lever is provided with a first tooth engaged with a second corresponding tooth provided on the mobile differential ring to control the movement of the latter;
• the differential frame comprises an upper frame fixed to a lower frame by means of at least one screw.

Thanks to these characteristics, the present invention provides a walking time equation mechanism whose switch is only formed from a minute hand of the true time concentric to a hand of the hours of the civil time. In the absence of a minute hand of the civil time, the reading of the solar time is therefore immediate. In particular, the problem of reading solar time on days when the difference between the minute of the civil time and the minute of the solar time is small does not arise. Moreover, apart from the switching of solar time, it is possible to provide a referral of the civil time conventionally formed by an hour hand of the civilian time and a hand of concentric civil time minutes. In this case also, the reading of the civil time is immediate and the user does not have to perform mental operation to distinguish the minute hand of the civil time from the minute hand of the solar time, then reconstitute the civil time by appreciating the difference between the hour hand of the civil time and the minute hand of the civil time.

Brief description of the figures

• la figure 1, déjà citée, est une vue d'un mécanisme d'équation du temps marchante selon l'art antérieur mû par un dispositif différentiel ;
• la figure 2 est une vue de dessus du dispositif d'équation marchante selon l'invention ;
• la figure 3 est une vue en coupe d'un mécanisme d'affichage du temps solaire et d'un mécanisme d'affichage du temps civil tous deux situés du même côté d'un cadran d'une pièce d'horlogerie, et
• la figure 4 est une vue en coupe d'un mécanisme d'affichage du temps solaire et d'un mécanisme d'affichage du temps civil situés pour l'un du côté d'un cadran d'une pièce d'horlogerie, et pour l'autre du côté d'un fond de la pièce d'horlogerie.

Other features and advantages of the present invention will emerge more clearly from the following detailed description of an example embodiment of a running time equation device according to the invention, this example being given purely for illustrative purposes and not limiting only in connection with the appended drawing in which:

• the figure 1 , already cited, is a view of a walking equation of time mechanism according to the prior art moved by a differential device;
• the figure 2 is a top view of the walking equation device according to the invention;
• the figure 3 is a sectional view of a solar time display mechanism and a civil time display mechanism both located on the same side of a timepiece dial, and
• the figure 4 is a sectional view of a solar time display mechanism and a calendar time display mechanism located for one side of a timepiece dial, and for the other on the side of a background of the timepiece.

Detailed description of an embodiment of the invention

The present invention proceeds from the general inventive idea of providing a running time equation mechanism including a switch whose function is to indicate the solar time or true time by means of a hand of the hours of the civil time and a hand of the minutes of the true time concentric with the hand of the hours of the civil time, the switch being deprived of a hand of the minutes of the civil time. With such an arrangement, the reading of the true time is immediate since the user does not need to differentiate between the minute hand of the civil time and the minute hand of the true time before being able to read the solar time. or true time. In the case of the present invention, one can even speak of a true display of the solar time or true time since only the minute of the true time differs to a certain extent from the minute of the civil time during the year, while the real time and the civil time are identical. The hour hand of the civil time therefore merges with the hour hand of the true time, so that the indication provided to the user by the switch formed by a hand of the hours of the civil time and a Concentric true time minutes hand corresponds to the exact true time. In addition, the device for displaying the solar time or true time according to the invention can be advantageously completed by a civil time switch comprising an hour hand and a concentric minute hand and which are driven by the same roadway as the display device of the true time. Thus, the user can, at a glance, read the true time and civil time clearly and accurately.

The object of the present invention is to integrate in a timepiece such as a wristwatch a walking time equation mechanism of a new kind whose switch comprises a minute hand of the true time concentric with a hour hand of the civil time. For this purpose, and as can be seen on the figure 2 the walking time equation mechanism according to the invention, generally designated by the general numerical reference 44, comprises a switch whose function is to indicate the solar time or true time by means of a hand of the hours of the civil time 46 and a hand of the minutes of the true time 50, concentric with the hand of the hours of the civil time 46, and which indicates the minute of the true time. To allow the wearer to the watch easily identify the minute hand of the true time 50, the latter may, for example, end with a representation of the astrological symbol of the sun 52. As will be seen in more detail later in this description, the exact position of the minute hand of the true time 50 for a given day can be determined once in 24 hours, around midnight, or be continuously adjusted.

We can also see on the figure 2 a part of the equation of walking time equation 44 according to the invention, and in particular a time equation cam 54 whose profile, let us recall, is determined by the difference between the mean solar time or civil time, and the solar time or true time for each day of the year.

Always in connection with the figure 2 it can be seen that the time equation cam 54 is fixed on an equation wheel of time 56 which is driven at the rate of one complete revolution per year by a simple or perpetual calendar mechanism (not shown) that the timepiece. This date mechanism can be of any known type and will not be described here in detail. It is sufficient, in fact, for a good understanding of the invention, to know that this date mechanism causes the equation wheel of the time 56 on which is fixed the time equation cam 54 at a rate of one complete revolution per year. In the case where the date mechanism is also used to display the date, this date mechanism may include a date wheel 58 which rotates at a rate of one complete revolution per month by driving a date indicator 104. On the other hand the time equation wheel 56 is driven by the date wheel 58 via an intermediate date wheel 60 for reversing the direction of rotation, and a reduction wheel 62 which makes it possible to reduce the speed of rotation of the wheel. one full turn per month to one full turn per year.

According to the invention, the minute hand of the true time 50 is driven by a differential gear device 64 which has respective inputs (see FIG. figure 3 ) a mobile 66 of a finishing gear and a time equation lever 68. The mobile 66 of the finishing train drives the civil time hour hand 46, while the time equation lever 68 cooperates with the time equation cam 54.

More precisely, as visible on the figure 3 a clock of the hours of the civil time 70 is driven by the mobile 66 of the finishing gear of the timepiece of the timepiece via a roadway 72 fixed for example by driving on a road sprocket 74. In turn, the road sprocket 74 drives a reducing satellite mobile 76 formed of a first satellite wheel 78 and a first satellite gear 80 integral with the first satellite wheel 78.

The satellite gear reducer 76 is pivotally mounted around a first pin 82 fixed for example by driving in a differential frame 84 which is secured to the gun hours of civil time 70 on which is driven the hour hand of civil time 46 Driven by the road sprocket 74 via the first satellite wheel 78, the first planet gear 80 rolls on a first internal toothing 86 of a first differential ring 88 which is carried by the clockwork movement and which is fixed . By rolling on the first internal toothing 86 of the fixed differential ring 88, the first satellite gear 80 rotates the differential frame 84 and thus the gun of the times of the civil time 70 which is integral with the differential frame 84. judicious choice of the gear ratios between the pinion 74, the first satellite wheel 78, the first satellite gear 80 and the fixed differential ring 88, a reduction of one twelfth between the minute of the civil time and the time of the civil time and one thus obtains the display of the civil time. In other words, the reducing satellite mobile 76 makes it possible, by a reduction of one twelfth, to go from the minute of the civil time to the time of the civil time.

As also visible on the figure 3 , a multiplier satellite mobile 90 is formed of a second satellite wheel 92 and a second satellite gear 94 integral with the second satellite wheel 92. The multiplier satellite mobile 90 is mounted free around a second pin 96 fixed for example by driving in the differential frame 84 which is secured to the gun of the hours of the civil time 70. When the gun of the hours of the civil time 70 and thus the differential frame 84 rotate, they cause the second pin 96 and, therefore, the multiplier satellite mobile 90 whose second sun gear 94 rolls on a second internal toothing 98 of a mobile differential ring 100 which will be seen below that it is engaged with the equation of time cam 54. The second satellite wheel 92 in turn causes a minute canon of the true time 102 on which is driven the minute hand of the true time 50. By a judicious choice of gear ratios between the gun hours of time 70, the second satellite wheel 92, the second satellite gear 94 and the mobile differential ring 100, a twelve-fold increase is made between the time of the civil time and the minute of the true time and one obtains thus holds the minute display of true time. In other words, the multiplier satellite mobile 90 makes it possible, by a multiplication by twelve, to go from the time of the civil time to the minute of the true time.

It follows from the foregoing that the reducing satellite mobile 76 and the multiplying satellite mobile 90 rotate on themselves by describing a circular trajectory centered on the gun of the hours of the civil time 70. Preferably, the reducing satellite mobile 76 and the mobile multiplier satellite 90 move on the same circle, centered on the gun of the hours of the civil time 70, being angularly spaced.

The mobile differential crown 100 is pivotally controlled by the time equation lever 68 provided with a probe nose 106 through which the time equation lever 68 is in contact with the profile of the cam. Equation of time 54. This time equation lever 68 is held resiliently against the profile of the equation of time cam 54 by a spring 108. This equation of time lever 68 is also provided with a first tooth 110 engaged with a corresponding second tooth 112 provided on the differential ring gear mobile 100 to control the movement of the latter. It is understood that at a time close to midnight when the date mechanism changes date, it controls the advance of a step of the date wheel 58. During this brief moment when the change of date occurs, the differential frame 84 and thus the clock of the hours of civil time 70 can be considered as immobile. By pivoting, the mobile differential crown 100 drives the second satellite pinion 94 and thus the second satellite wheel 92 which, in turn, meshes with the canon of the minutes of the true time 102 on which is driven the minute hand of the true time 50. The position of the minute hand of the true time 50 is thus adjusted for the day to come. In the case of a trailing date mechanism, the position of the minute hand of the true time 50 is continuously adjusted.

Referring to the figure 2 it can be seen that at least one and preferably two screws 114 make it possible to close the differential frame 84 on a lower differential frame 116. The differential racks 84 and lower 116 therefore rotate together when the differential gear device 64 according to FIG. invention works.

As also illustrated in figure 3 , the roadway 72 drives a second roadway 118 via an intermediate return wheel 120. This second roadway 118 is fixedly mounted on a gun of the minutes of the civil time 122 on which is driven a minute hand of the civil time 124. The gun of the minutes the civil time 122 drives via a second reduction gear 126 comprising a reducing wheel 128 fixed on a reduction pinion 130 a second gun of the hours of civil time 132 on which is driven a second hand of the hours of the civil time 134. Through employment of the intermediate deflection wheel 120, the display of the civil time by means of the second hand of the hours of the civil time 134 and the minute hand of the civil time 124 turns in the right direction over a dial of shows 136. The intermediate idler wheel 120 also makes it possible to ensure a sufficient spacing between the display of the time solar and the display of true time so that these two displays do not interfere.

The reading of the civil time is thus also immediate and the user does not have to perform a mental operation to distinguish the minute hand from the civil time of the minute hand of the solar time, then reconstitute the civil time by appreciation of the difference between the hour hand of the civil time and the minute hand of the civil time. In addition, it will be appreciated that the same PTO is used to produce the minute of true time on the one hand, and the civil time on the other hand, which greatly simplifies the assembly.

In the example shown in figure 3 , the solar time display device or true time and the calendar time display device are arranged on the same side of the watch dial 136. In the example shown in FIG. figure 4 , the solar time display device or true time is disposed on the dial side of the watch 136, while the calendar time display device is disposed on the side of a bottom 138 of the watch. It can be seen in this embodiment that it is possible to dispense with the intermediate return wheel 120 because there is no need to correct the direction of rotation of the second display device of the civil time when it is necessary to the other side of the watch.

It goes without saying that the present invention is not limited to the embodiment which has just been described and that various modifications and simple variants can be envisaged by those skilled in the art without departing from the scope of the invention as defined by the appended claims.

Nomenclature

• 1. Equation cam of time
• 2. Disc of the months
• 4. Needle of minutes of solar time
• 6. Mobile date
• 8. Needle
• 10. Intermediate calendar return wheel
• 12. Mobile discount
• 14. Differential gear device
• 18. Hour hand of civil time
• 20. Rake
• 22. Satellite gears
• 24. Inner teeth
• 26. Equation wheel of time
• 28. First toothed sector
• 30. Second sector toothed
• 32. Feeler
• 34. Solar weather display gear
• 38. Display wheel of solar time
• 40. Roadway
• 42. Center
• 44. Equation mechanism of walking time
• 46. Needle of the hours of civil time
• 50. Hour hand of true time
• 52. Astrological symbol of the sun
• 54. Time equation cam
• 56. Equation wheel of time
• 58. Date wheel
• 60. Intermediate calendar return wheel
• 62. Mobile discount
• 64. Differential gear device
• 66. Mobile
• 68. Time Equation Leverage
• 70. Canon of the hours of civil time
• 72. Roadway
• 74. Road sprocket
• 76. Mobile satellite reducer
• 78. First satellite wheel
• 80. First satellite gear
• 82. First pin
• 84. Differential frame
• 86. First internal toothing
• 88. Fixed differential ring
• 90. Mobile satellite multiplier
• 92. Second satellite wheel
• 94. Second satellite gear
• 96. Second pin
• 98. Second internal toothing
• 100. Mobile Differential Crown
• 102. Canon of minutes of true time
• 104. Date indicator
• 106. Probing beak
• 108. Spring
• 110. First tooth
• 112. Second tooth
• 114. Screw
• 116. Differential underframe
• 118. Second floor
• 120. Intermediate return wheel
• 122. Canon of the minutes of civil time
• 124. Minute hand of civil time
• 126. Second reduction gear
• 128. Reducing wheel
• 130. Reducer sprocket
• 132. Second canon of the hours of civil time
• 134. Second hand of the hours of the civil time
• 136. Watch face
• 138. Watch bottom

Claims (16)

Walking time equation mechanism including a switch whose function is to indicate solar time or true time by means of a civilian time hour hand (46) and a true time minute hand (50) concentric with the hand of the hours of the civil time (46), the switch being devoid of a hand of the minutes of the civil time, the hand of the hours of the civil time (46) being driven in rotation by a clockwork movement and in turn driving the minute hand of the true time (50), the walking time equation mechanism (44) also including a time equation cam (54) having a profile which is determined by the difference, for each day of the year, between the mean solar time or civil time, and the solar time or true time, this time equation cam (54) being rotated at a rate of one revolution per year by the motion watchmaking, the position of the minute hand of true time (50) being determined by the position of the time equation cam (54). A walking time equation mechanism according to claim 1, characterized in that it further comprises a differential gear device (64) having a first input constituted by a roadway (72) which is driven by the watch movement and which makes one turn in 1 hour, and a second input of which is the time equation cam (54), the differential gear device (64) being arranged concentrically with the minute hand of time true (50). Walking time equation mechanism according to claim 2, characterized in that the differential gear device (64) comprises a reduction gear satellite (76) via which a road gear (74) on which the roadway (72) is fixed. causes a gun of the hours of the civil time (70) on which is driven the needle of hours of the civil time (46), and a multiplier satellite mobile (90) via which the clock of the hours of the civil time (70) causes a canon of the minutes of the true time (102) on which is driven the minute hand of the time true (50). A walking time equation mechanism according to claim 3, characterized in that the reducing satellite dish (76) reduces the rotational speed from one full revolution per hour to one full revolution per twelve hours, and that Mobile satellite multiplier (90) makes it possible to increase the rotational speed of a complete revolution in twelve hours to one complete revolution per hour. Walking time equation mechanism according to one of claims 3 or 4, characterized in that the reducing satellite mobile (76) and the multiplier satellite mobile (90) rotate on themselves by describing a circular trajectory centered on the barrel minutes of true time (102). A walking time equation mechanism according to claim 5, characterized in that the reducing satellite dish (76) and the multiplying satellite dish (90) are equidistant from the true time minutes barrel (102). Walking time equation mechanism according to one of claims 5 or 6, characterized in that the reducing satellite mobile (76) and the multiplier satellite mobile (90) are rotated freely by a differential frame (84) of which the canon of the hours of the civil time (70) is solidary. A walking time equation mechanism as claimed in claim 7, characterized in that the reducing satellite dish (76) is pivotally mounted about a first pin (82), and the multiplying satellite dish (90) is pivotally mounted around a second pin (96), the first and second pins (82, 96) being fixed in the differential frame (84). A walking time equation mechanism according to claim 8, characterized in that the reducing satellite dish (76) comprises a first satellite wheel (78) integral with a first satellite pinion (80). A walking time equation mechanism according to claim 9, characterized in that the road gear (74) meshes with the first satellite wheel (78), and that the first planet wheel gear (80) rolls on a first internal gear (86) of a fixed differential ring gear (88), thereby rotating the differential frame (84). A walking time equation mechanism according to any one of claims 8 to 10, characterized in that the multiplier satellite mobile (90) comprises a second satellite wheel (92) integral with a second satellite gear (94). A walking time equation mechanism according to claim 11, characterized in that the second satellite wheel (92) meshes with the true time minutes gun (102), and that the second satellite gear (94) rolls on a second internal toothing (98) of a movable differential ring (100) which is kinematically connected to the time equation cam (54). Walking time equation mechanism according to claim 12, characterized in that the movable differential ring (100) is pivotally controlled by a time equation lever (68) provided with a sensing nose (106) by the intermediate of which the time equation lever (68) follows the profile of the time equation cam (54). A walking time equation mechanism according to claim 13, characterized in that the time equation lever (68) is held resiliently against the profile of the time equation cam (54) by a spring (108). ). Walking time equation mechanism according to claim 14, characterized in that the time equation lever (68) is provided with a first tooth (110) engaged with a corresponding second tooth (112) provided on the crown movable differential (100) for controlling the movement of the latter. Walking time equation mechanism according to one of Claims 7 to 15, characterized in that the differential frame (84) comprises an upper frame fixed to a lower frame (116) by means of at least one screw ( 114).

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