CH715772A1 - Watch with display device of intersections of trajectories of stars conducive to the appearance of eclipses. - Google Patents

Abstract

The invention belongs to the field of watches and other timepieces. More particularly, the invention relates to a watch or a mechanical or electromechanical timepiece displaying, in a context of coplanar representation and in geocentric vision, the positions of the sun (22), the moon (24) and a simulation their trajectories in order to determine the favorable moments for eclipses.

Description

The invention belongs to the field of watches and other timepieces. More particularly, the invention relates to a watch or a mechanical or electromechanical timepiece displaying, in a context of coplanar representation and in geocentric vision, the positions of the sun, the moon and a simulation of their trajectories in order to determine the positions. moments conducive to eclipses.

To date, some astronomical clocks indicate the position of the lunar nodes on the ecliptic using a particular needle in the shape of a dragon, called the "draconite needle" or "dragon needle", such a needle indicates the odds of an eclipse happening somewhere in the world at some point.

The invention presented in this document is a simulator produced by means of a mechanical or electromechanical timepiece, comprising at least one housing, a time counting mechanism, as well as a display device on a 24 hour scale having a first plane parallel to the display itself including a marker in the form of a rotating figure corresponding to the view and position of the moon as seen from earth, characterized in that a second partially opaque plane and masking the moon, rotating and concentric in the foreground, this second plane includes a marker in the form of a window corresponding to the position of the sun seen from the earth as well as a third plane, rotating and concentric parallel to the two first shots, which follows the evolution of the lunar orbit with respect to the sun, taking into account its precession of a little over 18 years and comprising two windows corresponding to the nodes characterizing the intersection of the trajectory oire lunar with the plane of the ecliptic, these two nodes allowing to reveal, during the alignment with the two other markers of the sun and the moon, the moments favorable to the appearance of an eclipse.

In order to correct the use of a circle instead of an ellipse corresponding to the trajectory of the moon around the earth, it is practiced a displacement of the axis of the nodes of a magnitude corresponding to a fraction of the eccentricity of the moon's orbit around the earth, the displacement being effected from the center of the circle towards the astral focus.

[0005] One of the embodiments of the sun of the moon markers, just like the 2 windows which materialize the nodes, is the use of circles which can be of the same diameter.

[0006] The device can be supplemented by 2 additional moons and the introduction of two windows on the mask making it possible to materialize the high trajectory of the moon which is above the ecliptic when it is visible in the outer window and the low trajectory of the moon which is below the ecliptic when visible in the interior window.

[0007] Furthermore, the horizon can be simulated by a motionless translucent disc serving as a reference for the other 3 movements. Likewise, it is one of the 3 other variables which are the moon, the sun, and the lunar orbital mask which can be made fixed and serve as a reference.

[0008] The figures below represent, without limitation, an exemplary embodiment: <tb> <SEP> Fig. 1 presents the basics of celestial mechanics. <tb> <SEP> Fig. 2 presents the effect of the precession of the moon <tb> <SEP> Fig. 3 presents 3 discs allowing to simulate the trajectories of the stars <tb> <SEP> Figs. 4 and 5 have elongated elliptical orbits <tb> <SEP> Figs. 6 and 7 have almost circular orbits <tb> <SEP> Fig. 8 shows all the components mounted on a watch <tb> <SEP> Fig. 9 presents a watch with horizon marking <tb> <SEP> Fig. 10 presents various eclipses

Realization of the invention:

Preamble:

[0009] FIG. 1 presents the bases of the celestial mechanics of the 3 stars sun (11), earth (12) and moon (13). The earth orbits the sun (14) in a counterclockwise direction (20). The trajectory of this orbit (14) is called an ecliptic, it is an ellipse, very close to a circle, which is traveled in one year. Likewise, the moon orbits the earth on an elliptical path in a plane inclined at ~ 5 ° (15). Thus, the lunar orbit crosses the plane of the ecliptic (14) at two points called lunar nodes (16) and it is when the axis of the lunar nodes merges with the axis of the sun that the 3 stars are aligned on an axis which is conducive to the appearance of an eclipse, in particular when the alignment is almost perfect. We will speak of a lunar eclipse when the moon is located behind the earth seen from the sun, it is a full moon with visibility of the shadow of the earth which hides part or all of the surface of the moon and we will speak solar eclipse when the moon is located between the sun and the earth it is the black moon or new moon which masks part or all of the sun's surface.

[0010] FIG. 2 shows the precession of the trajectory of the moon whose cycle is about 1 turn or 360 ° in a little over 18 years, which gives an angle of 19.35 ° per year. If we take the position of the nodes on the plane a) as a reference for the start of the cycle, we note that after 3 months, the precession angle (18) has gone from 0 ° to ~ 5 ° visible on the plane b) then at ∼10 ° on plane c) to be at ∼14.5 ° on plane d).

[0011] The important criteria for producing a mechanical trajectory simulator are: <tb> • <SEP> the duration of a day or the duration of a rotation of the earth on itself seen from the sun is 24 hours or 1 day <tb> • <SEP> the duration of 2 successive identical passages of the earth relative to the sun seen by the terrestrial observer (average interval between 2 solstices) is 365.242436 days of 24 hours on average. <tb> • <SEP> the duration of two passages of the moon which separate two identical phases of the moon is 29.530646 days of 24 hours on average. <tb> • <SEP> the period of precession of the nodes that the ancients called "Saros" is 6585.33405 days of 24 hours on average, ie a little over 18 years.

[0012] Neglected influences and approximations: <tb> • <SEP> Coplanar representation in geocentric vision of the movements of the 3 stars that are the sun, the moon and the earth. <tb> • <SEP> Eclipticals are allowed circular <tb> • <SEP> The lunar orbit is simulated by concentric arcs of a circle. <tb> • <SEP> Orbital speeds are taken on average <tb> • <SEP> The variations in apparent and relative dimensions of the stars are adapted to the design

Below is described an embodiment or an embodiment of the invention.

[0014] FIG. 3 presents a display background (21) with a fixed 24-hour scale (10) and 3 rotating disks (23, 27, 21) making it possible to simulate the trajectories of the so-called ecliptic sun (22), the position of which indicates the hour on the 24-hour dial, of the moon (25) reported on the same plane as the trajectory of the sun when in reality, it orbits in a plane inclined by about 5 ° with respect to the plane of the trajectory of the sun. ecliptic as well as a mask (27) to reveal the moments favorable to the appearance of an eclipse.

The speed of rotation of the solar disk (21) is 1 revolution per day. The speed of rotation of the lunar disk (23) is one revolution per 0.966136874 day, this last figure indicating the daily delay that the moon (25) takes in relation to the sun (22). This speed of rotation is obtained by a set of gears starting from the speed of rotation of the solar disk.

The speed of rotation of the disk said mask (27) is 1.002885198 revolutions / day which corresponds to the period of precession of the nodes (16) and which means that it performs one revolution more than the sun during the cycle of precession of more than 18 years. This speed of rotation is also obtained by a set of gears starting from the speed of rotation of the solar disk.

Graphically, the disc (23) carrying the moon (25) is light in color while the moon is pastel. We note that the moon (25) is tripled (24, 26) this making it possible to visualize it outside the times favorable to eclipses. The so-called mask disc (27) is opaque and has 4 transparent windows (28, 29, 30, 31), the 2 windows (30, 31) reveal the moments conducive to the appearance of eclipses while the interior window ( 29) allows you to view the moon (26) when it is in low orbit, i.e. its orbit is below the ecliptic and the outer window (28) allows you to view the moon (24) when 'it is in high orbit, that is to say that its orbit is above the ecliptic. The disc carrying the sun (21) is transparent with an opaque band making it possible to mask the moon (25) and comprising a first window (22) consisting of a warm color filter representing the sun as well as a second window (32) transparent placed in front.

The device reveals a solar eclipse when the moon (25) passes under one of the windows of the mask and that it is visible through the warm color filter (22) which corresponds to an alignment on an axis of the three stars, alignment conducive to the appearance of an eclipse. The eclipse is total when the 3 circles (25, 30 or 31, 22) are in perfect phase, it is partial when they are not in phase. The duration of the phenomenon, which begins with the appearance of growing segments then passes through entire circles to end with lens-shaped segments diminishing then disappearing (Fig. 10). The device reveals a moon eclipse when the moon (25) passes under one of the mask windows and is visible through the window (32) of the solar mask opposite the warm color filter (22).

[0019] Figs. 4, 5, 6, 7 are intended to position the 2 windows in the form of circular holes (30, 31) to mark the presence of eclipses.

[0020] Figs. 4 and 5 present, for the purposes of understanding, elongated elliptical orbits with the astral focus (35) and the other focus (36) marked with a cross and placed on the side of the high culmination. The center of the ellipse (37) is located midway between the two foci. Fig. 5 shows the outer circle (38) tangent to the ellipse, the inner circle (39) and the median circle (40). Thus we can see that if the simulator were built on the basis of an ellipse, the two holes would be located on an axis passing through the center of the star. If, on the other hand, we try to simplify the simulator by building it on the basis of a median circle (40), the center of which is the star, then the axis of the two holes would be very far from the star which does not seem very happy.

[0021] Figs. 6 and 7 have an orbit similar to that of the moon around the earth. It is close to a circle with the minimum earth-moon distance of 356,700 km and maximum of 406,300 km for an average eccentricity of 5.5%. The drawing of fig. 6 and 7, although not very precise, respects the proportions with the center of the star (41) drawn in dotted lines and visible at the end of the arrow, the second focus (42) represented by a cross and the center of the ellipse (43) represented by the small circle (44). In fig. 7, a circle is drawn in dotted lines, it is the middle circle (40) having its center (43) represented by the small circle. Thus, we see that if we simulate the trajectory of the moon by a circle rotating around the earth rather than an ellipse, the rigor requires that the axis of the holes be slightly shifted, more precisely by a value of l order of a fraction of the eccentricity (45).

[0022] FIG. 8 shows all of the components mounted on a watch that displays 10:10 (AM). The components are the sun (22), whose position indicates the time on the 24-hour dial, the moon (24) which is about 4 hours ahead of the sun, the eclipse windows (30, 31) , as well as the windows (28, 29) making it possible to visualize the high (28) and low (29) trajectories of the moon and the window (32) of the solar mask (21) window which is opposite the sun and which makes it possible to visualize moon eclipses.

[0023] FIG. 9 shows a variant of a watch equipped with an additional stationary mask (52) representing the horizon. This mask can be more or less opaque depending on whether or not one wishes to visualize the invisible stars because they are located below the horizon. The watch also features a decentralized 12 o'clock display (53) as well as an adjustable bezel to adapt to time zones (54). The watch displays 2:14 p.m. with the sun set at 2:14 p.m. She is in a situation of total eclipse (65).

[0024] FIG. 10 shows various eclipses with the sun (61) represented by a horizontal hatch instead of the translucent warm-colored filter, the moon (62) by a vertical hatch. The squared hatching is to be seen as the appearance of the moon behind the sun itself translucent. The duration of the phenomenon which begins with the appearance of enlarging segments (63, 64) then passes through a whole circle (65) to end with decreasing segments (66, 67) then disappearing is about 2 days, i.e. 1 day before the appearance of the entire circle then 1 day later. A partial eclipse (68) will remain limited to segments of a circle. The orientation of the eclipse depends on its time of appearance, the segments are radiating like a needle, they are vertical (68) if it is noon (axis ii) or oblique at 45 ° (axis ii) if it is is 3:00 p.m. (69).

The preceding description involves 3 rotating variables, against a fixed horizon background, variables which can be discs or sometimes markers and which are: <tb> • <SEP> The moon <tb> • <SEP> The sun <tb> • <SEP> The lunar orbital mask whose relative angular velocities are adapted to a fixed horizon. Each of the 3 markers can be chosen as a fixed point which gives 3 other presentations of the phenomena.

These watches according to the invention are particularly intended for the luxury watch market.

Claims (7)

1. Mechanical or electromechanical timepiece (fig. 8, 9), comprising at least one case, a time-counting mechanism, as well as a display device on a 24-hour scale (10) comprising a first plane (23) parallel to the display, itself comprising a marker in the form of a rotating figure corresponding to the view and position of the moon (25) seen from the earth, characterized in that a second plane ( 21) partially opaque and masking the moon (25), rotating and concentric in the foreground, this second plane includes a marker in the form of a window (22) corresponding to the position of the sun seen from the earth as well as a third plane (27), rotating and concentric parallel to the first two planes, which follows the evolution of the lunar orbit in relation to the sun taking into account its precession of a little over 18 years and comprising two windows (30, 31 ) corresponding to the nodes characterizing the intersection of the lunar trajectory with the plane of the ecli ptique, these two nodes (16, 30, 31) allowing to reveal, during the alignment with the two other markers of the sun (22) and the moon (25), the moments favorable to the appearance of an eclipse . 2. Timepiece according to claim 1, characterized in that the use of a circle (40) instead of the ellipse implies a correction of the position of the axis of the lunar nodes (16, 30, 31), positioned on the rotating plane (27) and making it possible to characterize the alignment of the stars, of a magnitude (45) corresponding to a fraction of the eccentricity of the lunar orbit around the earth, the displacement (45 ) of the axis being operated from the center of the circle towards the astral focus (41). 3. Timepiece according to claims 1 to 2, characterized in that the window of the sun (22), of the moon (25) as well as the 2 windows (30, 31) which materialize the nodes (16) are circles . 4. Timepiece according to claim 2, characterized in that the circles representing the sun (22), the moon (25), just like the 2 windows (30, 31) which materialize the nodes (16) are of the same diameter. . 5. Timepiece according to claims 1 to 4, characterized in that the first plane (23) comprising the moon marker (25) comprises 2 additional moons (24, 26) and the mask (27) two additional windows ( 28, 29) making it possible to materialize the high trajectory of the moon (24) which is above the ecliptic when it is visible in the exterior window (28) and the low trajectory of the moon (26) which is at the - below the ecliptic when it is visible in the interior window (29). 6. Timepiece according to claims 1 to 5caractériséeen that the horizon is simulated by a translucent disc (52) stationary serving as a reference to the other 3 rotating planes (21, 23, 27). 7. Timepiece according to claims 1 to 5, characterized in that one of the other 3 variables which are the moon (25), the sun (22), and the lunar orbital mask (27) is made fixed and serves as a reference. .