CH704080B1 - Watch including an astronomical indication. - Google Patents

Abstract

Watch comprising at least one astronomical indication, said watch comprising determining means controlling display means 13, 14, 20, 21, 22, 23 of the daily solar variation and / or the daily height reached by the sun during the passage to the meridian. The watch may also include means for displaying the months, solstices and equinoxes 15, 16, 17, the offset between the solar time and the legal time 24, 25 and the local latitude 18, 19.

Description

[0001] The invention relates to a watch comprising at least one astronomical indication.

[0002] By watch is meant a timepiece sufficiently small to be worn on the body as opposed to large timepieces such as astronomical clocks.

[0003] Timepieces comprising an astronomical representation mechanism are known, for example the Giovanni Dondi astrarium. Other astronomical clocks exist, such as the astronomical clock in Strasbourg Cathedral or the Clock Tower clock in Bern. However, these clocks were made for local geographic conditions.

[0004] Patent CH 688 171 describes an additional astronomical representation mechanism for a timepiece comprising a first device intended to provide a representation of the appearance of the moon as a function of time at a predetermined geographical location, combined with a second device intended to produce a visualization of the convolutional movement of the moon and a representation of the celestial vault animated by a rotational movement.

[0005] Patent CH 658 763 describes a mechanism providing a representation of the starry sky and making it possible to provide information on the position of the main stars and on certain astronomical phenomena.

[0006] Patent CH 690 516 describes a watch offering a representation of the course of the sun which makes it possible to know the times of sunrise and sunset. However, this mechanism does not give any indication of the daily solar declination and does not indicate the height reached by the sun during the passage through the meridian.

[0007] Thus, the clocks and watches which include an astronomical representation mechanism described in the prior art ignore the elements which govern the seasons and in particular the position of the sun.

[0008] The aim of the present invention is to create a watch which informs its wearer about at least one astronomical information relating to the sun. More specifically, astronomical information about the sun relates to the solar declination or the height of the sun at the meridian.

[0009] This object is achieved by providing a watch comprising an astronomical indication, said watch further comprising determination means controlling means for displaying the daily solar declination and / or the daily height reached by the sun during the passage. at the meridian.

[0010] Another object of an embodiment of the invention is to provide a watch indicating the solstices and the equinoxes. Another object of an embodiment of the invention is to ensure that the indication of the solar declination, the indication of the solstices, of the equinoxes and of the maximum height of the sun for a given day are automatically reset. in the exact angular position after an indefinite stop of the movement by simply setting the time thereof. Another object of an embodiment of the invention is to provide a watch which makes it possible to adjust the latitude of the place as well as the offset of the local legal time with respect to solar time so that these two parameters can be changed by the wearer himself.

[0011] These aims are achieved by a watch as defined in the dependent claims.

[0012] Said daily solar declination display means may consist of a first analog display comprising a needle indicating the daily solar declination on a graduated scale.

The means for displaying the daily height reached by the sun during the passage to the meridian may consist of a second analog display comprising a needle indicating said height on a graduated scale and / or a device for viewing the daily trajectory of the Sun.

[0014] The watch may include means for adjusting and displaying the latitude and / or the offset of legal time relative to solar time.

[0015] The watch can also include an indicator showing the months, the equinoxes and the solstices.

[0016] The determination means may comprise an astronomical mechanism comprising a mechanism for indicating the daily solar declination animating said means for displaying the daily solar declination.

[0017] Said astronomical mechanism may include means for adjusting the latitude and the offset of legal time with respect to solar time and a mechanism for indicating the daily height reached by the sun when passing through the animating meridian said means for displaying the daily height reached by the sun during the passage through the meridian.

[0018] Said daily solar declination indicating mechanism may include a declination cam and first connecting means kinematically linking the declination cam to said daily solar declination display means.

Said cam can be shaped such that the daily declination d indicated by said display means of the daily solar declination for a day j is given by the equation d = arcsin (0.3978 x sin ( 280 + 1.914 x sin (357 + 0.9856 xj) + 0.02 x sin (2 * (357 + 0.9856 xj)) + 0.9856 xj)).

Said mechanism for indicating the daily height reached by the sun during the passage to the meridian may comprise a thirty-one star and second connection means kinematically linking the thirty-one star with said means for indicating the daily height reached by the sun during the passage to the meridian, said means for displaying the daily height reached by the sun during the passage to the meridian comprising a disc comprising a mark representing the sun.

The second connection means may comprise a second cam which actuates a third cam kinematically linked to a first carriage, said third cam making it possible to move the first carriage in translation in the 6 o'clock <-> 12 o'clock direction and thus to move the disc with a mark representing the sun in the same direction.

Said mechanism for indicating the daily height reached by the sun during the passage to the meridian may comprise third connecting means kinematically binding a roadway and the disc comprising a mark representing the sun and allowing said disc to rotate. a complete turn in 24 hours.

[0023] The third connecting means may comprise a second carriage kinematically linked to the first carriage, said second carriage being able to move in translation in the direction 3 o'clock <-> 9 o'clock.

The third connecting means can comprise several movable bridges.

Said mechanism for indicating the daily height reached by the sun during the passage to the meridian can comprise fourth connecting means kinematically linking the means for adjusting the offset of the legal time with respect to solar time and the disc with a mark representing the sun.

The astronomical mechanism may include a reduction gear consisting of 4 wheels and a ratio of 1 to 11.78 resulting in, from a star of thirty-one making a complete revolution every thirty-one days , a wheel making one complete revolution per year carrying the declination cam which actuates the means for displaying the daily solar declination by means of a sensor cooperating with the declination cam under the action of a return spring.

The astronomical mechanism may include a second declination cam performing a rotation on itself at the same frequency as the first declination cam by means of a feeler cooperating with said second cam under the action of a return spring, said feeler setting in motion a third cam whose movement reproduces the evolution of the solar declination, said third cam being cut to make it possible to reproduce the variation in height in the sky of the sun.

The feeler, the third cam and the return spring can be separate parts or be united in a single part.

[0029] The second declination cam, the probe, the third cam and the return spring may be dependent on a movable plate which can turn on itself by a determined value and pivot by the same value as the plate.

The third cam can move a movable member, said movable member moving linearly and returning to its initial position after one year.

The plate can pivot on itself through the action of a corrector actuated by the wearer of the watch, this action making it possible to visualize on the dial the modification of the latitude of the place and to modify the position of the first carriage which moves linearly and returns to its initial position after one year.

[0032] The astronomical mechanism may contain an epicyclic gear between the declination cam and the second cam which oscillates the third cam at the same frequency as the declination cam.

[0033] The plate can change the position of the planet carrier by means of a part comprising two pins.

The astronomical mechanism can include a crank pin which sets the second carriage in motion.

The invention will be better understood by those skilled in the art thanks to the following description of an embodiment in relation to the accompanying drawings in which: FIG. 1 is a top view of a watch according to the invention, FIG. 2 is a graph of the height of the sun during the passage through the meridian as a function of the latitude, FIG. 3 is a top view of the watch without the main dial, FIG. 4 is a top view of the watch mechanism without the disc comprising a mark representing the sun, the bottom of the dial and the moving horizon, FIG. 5 is a top view of the daily solar declination indicating mechanism. fig. 6 is a top view partially showing the mechanism for indicating the daily solar declination, FIG. 7 is a schematic view of the declination cam, FIG. 8 is a top view of the mechanism for indicating the daily height reached by the sun during the passage through the meridian.

In the following description, we will not describe the watch movement in its entirety, but only the functional parts of a mechanism allowing the indication of the daily solar declination, the indication of the solstices and equinoxes, the indication of the daily height reached by the sun during the passage to the meridian, the representation of the course of the sun, the adjustment and display of the latitude as well as the adjustment and display of the offset from the hour solar. Traditionally, this watch movement may include a perpetual calendar mechanism, but may also include a date indication with manual correction or no date indication. The invention uses a watch movement which can be any conventional movement of the mechanical type with automatic or manual winding or of the electronic quartz type. This watch movement provides the temporal reference to the watch according to the invention.

[0037] The watch according to the invention illustrated in FIG. 1 consists of a watch case 1, a bezel 2 with a winding and / or time-setting member 3 and a bracelet 4. The current time is indicated by the hour hand 5 and minute hand 6. Dial 7 has indexes 8 and a timer 9.

[0038] The watch illustrated in FIG. 1 comprises five analog displays and a device for viewing the daily trajectory of the sun arranged in a window 10 in the form of a half-moon.

[0039] The first analog display, located at 6 o'clock, consists of hand 15 and a graduated scale 16, 17.

[0040] This display is used to indicate the months, seasons, solstices and equinoxes. Needle 15 makes one revolution in a tropical year.

The second analog display, located at 7 o'clock, makes it possible to indicate the value of the daily solar declination by means of the needle 22 on the graduated scale 23. The scale is graduated from –23.44 ° for the solstice winter at + 23.44 ° for the summer solstice. The declination of a star is the angle that the direction of the star makes with the celestial equatorial plane (parallel to the terrestrial equatorial plane). In the case of stars this angle varies little; on the other hand, the declination of the Sun varies from day to day except in the vicinity of the solstices.

The third analog display, located at 5 o'clock, makes it possible to indicate the latitude of the place on a scale 19 graduated from 0 ° for the equator to 60 ° north latitude and 40 ° south latitude using needle 18. The latitude of the location can be adjusted by the user as will be explained in the remainder of the description.

[0043] The fourth analog display, located at 8 o'clock, can indicate the difference between legal time and solar time for a certain location using the 24 hand; the value of the offset is indicated on the scale 25. This offset can also be adjusted by the user as will be explained in the following description.

[0044] At 4 o'clock is the fifth analog display whose function is to indicate, for a given day, the maximum height reached by the sun during the passage through the meridian. This indication, which is carried out with the hand 20 and the graduated scale 21, depends on the day of the year and the latitude. Fig. 2 shows a graph which represents the maximum height reached by the sun as a function of the day and the latitude. The time of the zenith is regulated by celestial mechanics and is separate from legal time. Consequently, for a given place, a star like the sun will not necessarily be at the zenith at noon.

The watch according to the invention further comprises a device for viewing the daily trajectory made by the sun in the sky which consists of an opening 10 of the dial which makes it possible to see a disc 13 which comprises a circular mark 14 representing the sun and which performs one turn in twenty-four hours. A part 12 represents the horizon and a back dial 11 hides the movement. As will be explained in the remainder of the description, the disc 13 can move both in the 12 o'clock <-> 6 o'clock direction, thus simulating the variation in the height of the sun, and in the 9 o'clock <-> 3 o'clock direction. .

[0046] FIG. 3 is a partial view of an astronomical mechanism allowing the indication of the daily solar declination, the indication of the solstices and the equinoxes, the indication of the maximum daily height of the sun during the passage to the meridian, the modification and the display of the latitude as well as the modification and display of the offset from solar time. The astronomical mechanism includes a mechanism for indicating the daily solar declination and a mechanism for indicating the daily height reached by the sun during the passage through the meridian. It is seen in fig. 3, the disc 13, which may be of the same color as the main dial and / or the bottom or be made of transparent material, comprising a circular mark 14 representing the sun. The part 12 which represents the horizon is placed above, its function is to hide the imprint of the sun in certain positions of the mechanism and thus make the animation more realistic. The bottom dial 11 is placed below. Its function is to hide the movement by reproducing the appearance of the main dial. The horizon is integral with a carriage 125 (shown in fig. 5), the function of which is described later in the description of the operation of the mechanism.

For reasons of clarity, the description of the astronomical mechanism, all of the components of which are shown in FIG. 4, will be done in the following order: we will first describe the mechanism for indicating the daily solar declination which drives the first and the second analog display, then the mechanism for indicating the daily height reached by the sun during of the passage to the meridian which animates the first and the fifth analogical display as well as the device for viewing the daily trajectory of the sun. The latter mechanism includes the means for adjusting the latitude and the offset of legal time from solar time.

[0048] FIG. 5 shows the mechanism for indicating the daily solar declination and part of the mechanism for indicating the daily height reached by the sun during the passage through the meridian.

On the plate 100 are fixed all the components of this mechanism, the power take-off is constituted, for this embodiment, by a star pinion of thirty-one 102, integral with a star of thirty-one 101. The star of thirty-one can be part of the clockwork movement of the watch, of a perpetual calendar or be independent of it. The thirty-one star is driven in the usual way by one thirty-first of a complete revolution per day and is held in position by the jumper 99. In this embodiment, the watch movement therefore comprises at least one thirty-one star performing a thirty-first complete revolution per day, however other technical solutions are known to those skilled in the art, the function of which is to obtain a change in position every twenty -four hours.

[0050] Through a kinematic chain, the hand 15 which indicates the days, the months, the seasons, the solstices and the equinoxes will revolve around itself in a tropical year.

For this, if we consider the tropical year which corresponds to 365.242 190 517 days, or 365 days 5 h 48 min 45.2606 seconds, according to the measurement made by the French astronomer Pierre Bretagnon, the star thirty-one 101 performs

The transmission ratio of this chain will therefore be:

for the exact tropical year.

To achieve the kinematic chain, the closest combination is

The transmission ratio makes it possible to determine the number of teeth of the gears constituting the kinematic chain.

In this configuration, needle 15 will do

[0054] The error generated by this gear train is less than 90 minutes per year, which is remarkable with four wheels and therefore perfectly economical. The appropriate choice of the number of teeth for each of the wheels will be a multiple of the previously calculated values in order to obtain wheels with dimensions that facilitate their manufacture.

The pinion 102 which comprises twenty teeth is engaged with a wheel of sixty-two teeth 103 secured to a pinion of fifteen teeth 104. This pinion 104 meshes with the wheel of fifty-seven teeth 105. On the axis of the wheel 105 is mounted the hand 15 which gives the indication of the day of the year.

The following description relates to the part of the mechanism which controls the display of the daily solar declination.

[0057] The wheel 105 drives the cam 106 coupled to its axis, the cam 106 being cut to reproduce the evolution of the solar declination. As shown in fig. 6, the lever 107 is in contact with the cam 106, thanks to the action of the part 107b which acts as a spring, and drives the wheel 108 which is integral with the needle 22 which indicates the variation of the daily solar declination on the 23 graduated scale visible on the dial. The tooth ratio between wheel 108 and the toothed portion of lever 107 is 1⁄2, in order to restrict the range of movement of the lever. This also makes it possible to produce a cam the size of which is compatible with a construction to be contained in a watch. The indication of the declination can be achieved by rotating or translating, the person skilled in the art will choose one or the other of the two possibilities according to the technical requirements concerning him. In the embodiment described, the choice is a rotation.

[0058] The needle 22 therefore oscillates from –23.44 ° to + 23.44 °, faithfully reproducing the evolution of the solar declination. The cam 106 is shaped so that for a given day j, j representing the rank of the day in the year, the declination d indicated by the hand 22 solves the equation:

[0059] d = arcsin (0.3978 x sin (280 + 1.914 x sin (357 + 0.9856 xj) + 0.02 x sin (2 * (357 + 0.9856 xj)) + 0.9856 xj) ) Hand 22 indicates 0 ° during the spring and autumn equinoxes, + 23.44 ° during the summer solstice and –23.44 ° during the winter solstice.

[0060] FIG. 7 illustrates some of the peculiarities of the shape of the cam 106. The cam therefore performs one rotation per tropical year. Point 106a represents the 1st day of the year, i.e. January 1, point 106b represents the spring equinox which generally falls on March 20 or 21, point 106c represents the solstice d 'summer which generally falls on June 21, point 106d represents the autumnal equinox which generally falls on September 22 or 23 and point 106e represents the winter solstice which generally falls on December 21 or 22 . The points on the cam that correspond to the spring and fall equinox are an equal distance from the center of rotation. The point on the cam which corresponds to the summer solstice is, depending on the construction chosen, the highest or the lowest point of the cam: the point on the cam which corresponds to the winter solstice is, depending on the construction, the lowest point if the point corresponding to the summer solstice is the highest and vice versa.

The cam is made so that the part of the lever 107 which is in contact with it is opposite the point 106a on January 1. After approximately 78.44 days, it will be opposite the point on the cam corresponding to the spring equinox. After 92.75 days, it will be opposite the point of the cam corresponding to the summer solstice. After 93.66 days, it will be opposite the point on the cam corresponding to the autumn equinox. After 89.86 days, it will be opposite the point of the cam corresponding to the winter solstice.

The cam 106 therefore makes it possible to animate the second analog display comprising the hand 22 and to indicate day after day the daily solar declination.

[0063] The description below relates to the part of the mechanism for indicating the daily height reached by the sun during the passage through the meridian. As described above, this mechanism makes it possible to animate the third analog display indicating the height of the sun and the device for viewing the daily trajectory of the sun, taking into account the height reached at the meridian. This mechanism also includes the means for adjusting the latitude and the offset of legal time from solar time.

The wheel 105 which performs one rotation per tropical year drives the wheel of ten teeth 109 which drives the mobile consisting of the wheels of 20 teeth 110 and 10 teeth 111. The wheel 111 sets in motion the crown of fifty-seven teeth 112 which is on the same axis as the wheel 105 but rotates freely on this axis. The crown 112 and the wheel 105 share the same number of teeth, thus the whole of the gear train 109, 110, 111 and 112 halves the speed of rotation of the crown 112 which makes a U-turn per tropical year .

[0065] The crown 112 contains an internal toothing of forty teeth which is the crown of an epicyclic train. The ring gear 112 transmits torque to the twenty-tooth sun gear 116 via the ten-tooth planet gear 113 which is integral with the planet carrier 115. Thus the planet gear 116 makes one revolution per tropical year.

The sun gear 116 drives the wheel of twenty teeth 117 whose pivot point rests on the plate 118. On the same axis as the wheel 117, there is a second cam 119 which reproduces the evolution of the solar declination and which drives a third cam 120, the shape of which makes it possible to reproduce the maximum height of the sun and that the spring 130 makes it possible to keep in contact.

The plate 118 can pivot on itself by causing in its rotational movement the wheel 117 and the cams 119 and 120. Part of the plate is a gear sector which corresponds to approximately one third of a wheel sixty teeth. The rotation of the plate 118 is controlled by the wheel of thirty teeth 121 which is held in position by the star of seventy two teeth 122 which it is integral with and which is held in position by the jumper 123. To modify the position of the wheel 121 and thus adjust the latitude, the corrector 124 is actuated. The return spring of the corrector 124 is not shown in the figure for the sake of simplicity. Correction of the latitude is possible in this situation in 5 ° steps. The inclination of plate 118 is therefore half that indicated on the dial.

The cam 120 controls the carriage 125 through the finger 127. The movement of the carriage 125 is restricted to the 6 o'clock – 12 o'clock direction by the screw 134 (shown in FIG. 8) and by grooves which are not shown. on the movement plate.

A modification of the value of the latitude has the effect of making the plate 118 pivot, however the cam 119 must keep the same relative orientation with respect to the cam 120 which corresponds to a given day. It is therefore necessary to correct the action of the rotation of the wheel 117 which pivots around the wheel 116. This correction is made by moving the planet carrier 115 by an angular value allowing the wheel 116 to rotate by the same value, but reverse. Thus, the orientation relative to the cam portion 119 relative to the cam 120 will remain the same.

The plate 118 has a groove, in this groove is housed the pin 131 integral with the connecting piece 132. A second pin 133 drives the planet carrier 115 which pivots freely on the axis of the wheel 105. This mechanism allows the modification of the latitude and the orientation of the cam 120 without modifying the value of the declination of the day.

So that the planet carrier is able to pivot by the value calculated with respect to the plate 118, a kinematic connection is made.

If the plate 118 rotates, the wheel 117 is driven and rotates around the wheel 116 which remains stationary. During angular displacement, the wheel 117 changes its orientation and rotates on itself by double the value of the angular offset.

The angular displacement for this mechanism will be equal to:

Center wheel z3n2 Planet carrier z2n1 Crown z1

If the change in latitude is 60 °, the plate 118 rotates by 30 °, the wheel 117 rotates on itself by 60 °, it is therefore necessary that the planet carrier rotates by 20 ° so that the wheel 116 turns 60 ° in the opposite direction to compensate for the offset.

[0075] The size ratios and the size of the various organs are chosen to obtain the most favorable system, the most efficient, the easiest to produce and to operate.

The carriage 125 has a groove perpendicular to the direction of movement, in which the carriage 126 rests, the latter therefore being driven in the 6 o'clock / 12 o'clock direction. Its freedom of movement is thus limited to the 3 o'clock / 9 o'clock direction.

[0077] A pin 128 is fixed on the carriage 125, it is in contact between the teeth of a fork 129 which drives the needle 20 in order to indicate the height of the sun when passing through the meridian.

The description below relates to the part of the mechanism which drives the disc 13 having a mark 14 representing the sun and which also makes it possible to adjust the offset from solar time. This part of the mechanism is illustrated more precisely in FIG. 8.

At the center of the plate 100, the roadway comprising ten teeth 203 makes one revolution in 60 minutes. It is the power take-off for the forty-tooth hour wheel 202 through the kinematic chain consisting of the forty-five-tooth timer wheel 204 and the fifteen-tooth timer pinion 205.

The roadway 203 is also the power take-off for the sun disc 13 through a second kinematic chain which contains the mobile composed of the 60-tooth wheel 206, which has the particularity of being at two levels and which contains an internal star of twenty-four teeth. This internal star drives a spring part 207 with three arms which serve as a jumper and which is coupled to a correction star with thirty-six teeth 208 and a pinion with fourteen teeth 209; the function of this mobile is to modify the offset of the solar time, which will be described later. The pinion 209 drives the fifty-six tooth wheel 210 which makes one revolution per twenty-four hours.

The kinematic chain continues with a cascade of pinions driven by the wheel 210, the latter drives the pinion of fourteen teeth 213 which meshes with the pinion of fifteen teeth 214 and continues with the pinion of fourteen teeth 215 which meshes with the pinion of fifteen teeth 216, followed by the pinion of fourteen teeth 217 which meshes the pinion of fifteen teeth 218 in contact with the pinion of fourteen teeth 219 and ends with the meshing of the crown of fifty-six teeth 220. The wheel 210 and the crown 220 having the same number of teeth combined with the fact that the number of intermediate gears is odd, these wheels complete one revolution in twenty-four hours in the same direction, that is to say clockwise. The pinions 213 and 214 rest on a bridge 211 which pivots around the axis of the wheel 210. The pinions 215, 216 and 217 rest on a bridge 212 which makes the connection between the bridge 211 and the carriage 126, the pinions 218 and 219 and the crown 220 resting on the carriage 126.

On the wheel 210 is fixed a crank pin 221 which is in contact with a groove on the carriage 126. The rotation of the wheel 210 in twenty-four hours is transformed into a linear movement of back and forth of the carriage which makes one go -return in twenty-four hours. At six o'clock in the morning the crankpin position is nine o'clock, at noon the crankpin position is twelve o'clock, at six o'clock the crankpin position is three o'clock and at midnight the crankpin position is six o'clock. The carriage finds its position modified as follows: at six o'clock in the morning, the position of the carriage is shifted in the nine o'clock direction, at noon, there is no longer any shift, the shift will resume and find its maximum point in the direction three to six o'clock. At midnight, the difference is zero as for noon. The reason for this movement of the chariot is to transform the apparent course of the sun's disk into a more natural and above all more realistic elliptical movement instead of a simple rotation.

The center distance between the wheel 210, resting on the movement plate, and the pinion 218 resting on the carriage 126 which moves continuously under the action of the crank pin 221 and of the cam 120 which controls the carriage 125 via finger 127 is variable. This inter-axis problem is solved by the bridges 211 and 212 which are mobile, the carriage 126 modifying its position under the action of the crankpin 221, once a day when the value of the declination is modified, and on request of the wearer of the watch during a change of latitude, this because the carriage 126 rests on the carriage 125 whose position depends on the date and on the latitude. The connection between the bridge 212 and the carriage 126 is concentric with the axis of the pinion 218, thus the carriage modifies the position of the bridge 212. The connection between the bridge 211 and the bridge 212 is concentric with the axis of the pinion 214 and the bridge 211 pivots around the axis of the wheel 210. Each shift of the carriage causes the pinion 213 to advance or lag behind which transmits it to the other pinions of the kinematic chain and compensates for the shift which the crown would have undergone 220 without this mechanism. The bridges have several levels because the height of the wheel 210 and that of the crown 220 are different.

[0084] On the crown 220 is fixed the disk 13 which has a circular mark 14 representing the sun, the assembly performs one revolution in twenty-four hours.

To modify the offset of legal time from solar time, corrector 222 is actuated to advance solar time or corrector 223 to reverse solar time. The return spring 224 returns the correctors to the initial position, the pins 225 and 226 limit the stroke of the correctors. The action on one of the correctors makes it possible to modify the position of the correction star 208 of which the spring 207 and the pinion 209 are integral. For each action on a corrector, the correction star 208 will drive the spring 207 which will move forward or backward by one tooth of the internal star of wheel 206 and therefore modify the orientation of pinion 209 and, through the kinematic chain which connects it to crown 220, the angular position of the sun on the dial. Wheel 206 makes one revolution in six hours, so one tooth offset is fifteen minutes ahead or behind.

[0086] Correction star 208 has thirty-six teeth and the inner star of wheel 206 has twenty-four teeth. To offset the spring 207 by one position relative to the internal star of twenty-four teeth, an angular offset of at least 7.5 ° and at most 22.5 ° is required. The number of teeth of the correction star 208 is 1.5 times that of the inner star, which guarantees to find a tooth of the correction star 208 in front of the corrector's finger.

[0087] The end of this lever rotates the correction star 208 counterclockwise or clockwise which makes it possible to advance or delay the sun disk by fifteen minutes. Finally, as the spring 207 is integral with the correction star 208, each maneuver on one or the other pusher will move the intermediate mobile forward or backward. Those skilled in the art will also understand that if the corrective star has more teeth than the internal star of the wheel 206 which has twenty-four, it is to ensure that the jumpers pass through a gap. to the other of the internal star of wheel 206 when acting on one of the push buttons. We will therefore preferably choose a correction star 208 whose actuation by the end of the lever allows the displacement of the internal star of the wheel 206 by an angle greater than 7.5 degrees (corresponding to half a step of the star of the wheel 206) and less than 22.5 degrees (corresponding to one and a half steps of the internal star of the wheel 206) in order to ensure the movement of one step and one.

Each corrector includes a second finger (not shown), the action of which rotates the correction star 227. The jumper 228 allows the position of this star to be maintained outside of the correction action. On the correction star 227, a pinion secured to twelve teeth 229 turns a wheel of twenty-four teeth 230 which itself drives a second wheel of twenty-four teeth 231. A pin 232 is fixed on the wheel 231 which serves as a crank pin to a connecting rod 233 which is connected to a pin 234 which serves as a crank pin on a wheel 235 which controls the position of hand 24 which indicates the offset between legal time and solar time.

[0089] Those skilled in the art will understand that both analog displays and the solar disk display device can be replaced by digital or digital displays, in particular in the case of quartz watches. In the latter case, mechanisms of the type described above, which is particularly suitable for a mechanical watch, can be replaced by an electronic chip determining the value of the declination, for example by an algorithm, as well as the height of the sun. at the zenith from the coordinates of the place where the wearer is located.

Claims (14)

1. Watch comprising at least one astronomical indication characterized in that said watch comprises determining means controlling means for displaying the daily solar declination (22, 23) and / or the daily height reached by the sun during the passage at the meridian (13, 14, 20, 21). 2. Watch according to claim 1, characterized in that said means for displaying the daily solar declination consist of a first analog display comprising a needle (22), indicating the daily solar declination on a scale (23) graduated. 3. Watch according to one of the preceding claims, characterized in that the means for displaying the daily height reached by the sun during the transition to the meridian consist of a second analog display comprising a needle (20), indicating said height on a graduated scale (21) and / or a device for visualizing the daily trajectory of the sun (13, 14). 4. Watch according to one of the preceding claims, characterized in that it comprises means for setting and displaying the latitude (18, 19, 124) and / or the offset of the legal time with respect to the solar time (24, 25, 222, 223) and / or an indicator (15, 16, 17), showing months, equinoxes and solstices. 5. Watch according to one of the preceding claims, characterized in that said determining means comprises an astronomical mechanism, comprising a daily sun declination indicating mechanism animating said display means of the daily solar declination. 6. Watch according to claim 5, characterized in that said astronomical mechanism comprises means for adjusting the latitude and offset of the legal time with respect to solar time and a mechanism for indicating the daily height reached by the sun during the transition to the meridian animating said display means of the daily height reached by the sun during the transition to the meridian. 7. Watch according to one of claims 5 and 6, characterized in that said mechanism for indicating the daily solar declination comprises a declination cam (106) and first connecting means (107, 108), kinematically linking the declination cam (106) to said display means of the daily solar declination. 8. Watch according to claim 7, characterized in that said cam (106) is shaped so that the daily variation d indicated by said display means of the daily solar declination for a day j is given by the equation d = arcsine (0.3978 x sin (280 + 1.914 x sin (357 + 0.9856 xj) + 0.02 x sin (2 * (357 + 0.9856 xj)) + 0.9856 xj)). 9. Watch according to one of claims 6 to 8, characterized in that said mechanism for indicating the daily height reached by the sun during the transition to the meridian comprises a star of thirty-one (101) and seconds connecting means kinematically linking the thirty-one star (101) with said means for indicating the daily height reached by the sun during the transition to the meridian, said means for displaying the daily height reached by the sun during the passage to the meridian comprising a disk (13) having a mark representing the sun. 10. Watch according to claim 9, characterized in that the second connecting means comprises a second cam (119) which actuates a third cam (120) kinematically connected to a first carriage (125), said third cam (120) allowing moving the first carriage (125) in translation in the direction 6 hours <-> 12 hours and thus move the disc (13) having a mark representing the sun in the same direction. 11. Watch according to claim 10, characterized in that said mechanism for indicating the daily height reached by the sun during the transition to the meridian comprises third connecting means, kinematically linking a roadway (203) and the disk (13). having a mark representing the sun and allowing said disc (13) to rotate a complete turn in 24 hours. 12. Watch according to the preceding claim, characterized in that the third connecting means comprises a second carriage (126) kinematically connected to the first carriage (125), said second carriage being movable in translation in the direction 3 hours <-> 9 hours. 13. Watch according to one of claims 11 and 12, characterized in that the third connecting means comprise a plurality of movable bridges (211, 212). 14. Watch according to one of claims 9 to 13, characterized in that said mechanism for indicating the daily height reached by the sun during the transition to the meridian comprises fourth connecting means, kinematically linking the offset adjustment means the legal time with respect to the solar time (222, 223) and the disc (13) having a mark representing the sun.