RU146127U1 - CLOCK WITH MECHANICAL DEVICE FOR DISPLAYING THE MOVEMENT OF THE MOON AROUND THE EARTH REGARDING THE SUN - Google Patents

Abstract

1. A mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun, coupled with the details of the clock mechanism, characterized in that the Moon model (25) is configured to move relative to the Earth model and is constantly in the same orientation relative to the line of the Earth-Sun models while the movement of the moon model (25) is carried out by kinematic connection with the clockwork. 2. The device according to claim 1, characterized in that the mechanical device for displaying the actual movement of the moon around the earth relative to the sun consists of daily wheels (21), daily disk (22), moon wheels (23), lunar disk (24), model of the moon (25 ), the differential mechanism (26) and the Earth model (27) .3. The device according to claim 1, characterized in that the mechanical device for displaying the actual movement of the moon around the earth relative to the sun consists of a diurnal wheel (21), a diurnal disk (22), lunar wheels (23), a lunar disk (24), a model of the moon (25 ) and cargo 36.4. The device according to claim 1, characterized in that the Moon model (25) is divided by a straight line into two equal parts of different colors, while the rotation of the Moon model (25) around the Earth relative to the Sun is carried out in such a way that this straight line is constantly perpendicular to the line connecting centers of the Earth and the Sun. 5. The device according to claim 2 or 3, characterized in that the model of the Earth (27) makes one full revolution per day around its axis. The device according to claim 2 or 3, characterized in that the names, signs or symbols of cities with the ability to determine the time in these cities are marked on the Earth model (27) or on the drive element of the Earth model. The device according to claim 2 or 3,

Description

Technical field

The utility model relates to the field of watch industry and can be used in the manufacture of watches, additionally equipped with a mechanical device for displaying the visible movement of the Moon against the background of stars (the actual movement of the Moon around the Earth), which is accompanied by a continuous change in its appearance.

State of the art

Indices (indicators) of the lunar phases in watches have been developed since ancient times.

Descriptions and watches are known dated to the 14th century, where the function of indicating the phases of the moon was used.

Indication of the lunar phases on the clock, which is the first astronomical function in clockwork, appeared shortly after the advent of mechanical clocks.

This clock function is still in demand in various situations, in particular when using lunar calendars.

To this day, there are many known designs and solutions of indicators (indicators) of the lunar phases, however, only a few solutions are suitable for practical use in ordinary mechanical watches.

There are various indicators (indicators) of the lunar phases in terms of design, construction and accuracy of indications, but most of them have certain disadvantages that limit their use in watch movements.

Known indicators of the phases of the moon in hours, made in the form of windows in the dial of various shapes and disks with printed images of the moon, rotating under the indicated windows, which leads to geometric distortion of the moon phases.

There are designs of the voluminous Moon, when the pointer is made in the form of a ball rotating in one lunar month, half painted in light, half in dark colors (see, for example, RU 2426165 C1, 08/10/2011). These structures have one significant drawback associated with the fact that the Moon does not rotate relative to the Earth, but is always located on one side to the observer, therefore, these structures do not allow to realistically display the surface of the Moon and use a real map of the lunar surface.

Known patent document FR 2679052, GHIRIMOLDI JUAN CARLOS, 01/15/1993. It reveals a planetarium watch. From the side of the watch dial, models of the Earth, the Sun and the Moon are made, where the Earth is located in the middle, and the Moon and the Sun rotate around it. The Earth, the Moon and the Sun have one axis of rotation, where the Earth makes one revolution in 2 minutes, the Moon in 1 hour, and the Sun in 12 hours.

The disadvantage of this solution is that it does not display the actual motion of the moon, does not display the phases of the moon, and also carries astronomically incorrect information.

Known patent document JP 2009216547, SEIKO EPSON CORP, 09.24.2009. It reveals a watch where the phases of the moon are displayed on the surface of the dial. To display the phases of the moon, two disks are used, one of which rotates and the other is stationary. A hole symbolizing the moon is made on the surface of the movable disk. The surface of the fixed disk is painted in dark and light colors, which symbolizes a change in the phase of the moon. When the movable disk rotates, a stationary disk is visible in the hole on the movable disk. The transitions between dark and light colors on the surface of a stationary disk, displayed in the hole of the moving disk, create a visual effect of a change in the phases of the moon.

A disadvantage of the known solution is that it is cumbersome in execution and takes up additional space in the watch case, while the phases of the moon are displayed only in the form from the Earth, and the actual movement of the moon is not displayed.

Known patent document WO 2004013708, ULYSSE NARDIN SA, OECHSLIN LUDWIG, 02/12/2004. It reveals a watch where the moon, earth and sun are made on the surface of the dial. The display of the phases of the moon is carried out similarly to the invention described above, except that in this embodiment both disks are movable, and the change in the phase of the moon displayed on the surface of the dial is made relative to the sun, located on the dial for about 12 hours.

The disadvantage of this solution is that it does not reflect the actual motion of the Moon and the Earth (the Earth is motionless), difficult to manufacture and takes up additional space in the watch case, which thickens and aggravates its design.

Known patent document CH 627042, VAN DER LELY, C, NV, 12.31.1981. It reveals a watch where the phases of the moon are displayed in a window on the dial. Under the window of the dial, a disk rotates, on the surface of which the moon is graphically made. The shape of the window creates a visual effect of the waning and waning moon. An astronomical map is made on the back of the watch, where planets revolve around the sun.

A disadvantage of the known watches is that the Moon is displayed separately from the Earth and does not display the full real picture. The complex mechanism heavily loads the internal space of the watch case, thickens and makes it heavier.

Known patent document CH 706600, MANUFACTURE ET FABRIQUE DE MONTRES ET CHRONOMETRES ULYSSE NARDIN LE LOCLE S.A., 12/13/2013. It reveals a clock displaying the corresponding position of the Sun, Earth and the Moon, as well as the phases of the moon. The position of the Sun and the Moon is displayed using two coaxially arranged disks, where the Earth is located on the axis so that the Sun and Moon rotate around it. On the first disk, the Sun is made and a window for displaying the phases of the Moon, in which the Moon is displayed on the second disk. The first disk makes one revolution in 24 hours, and the second disk in one lunar month relative to the first disk.

The disadvantage of this watch is that the model of the Earth is stationary, which does not allow to determine the visibility of the Moon in one or another part of the Earth. Also, the disadvantage of this solution is that the Sun and Moon revolve around the Earth, which does not allow us to display a real astronomical picture. The clock also shows the phases of the moon, visible only from the Earth.

Famous mantel clock company Franz Hermle & Sohn, which are called Hermle Tellurium III. [1] Modern watch technologies used in the development of the Tellurium series make it possible to observe the motion of the planets. At the top of the watch is a miniature model of the solar system: in the center of it stands the figure of the powerful god of the Sun supporting the solar disk, and next to it is the globe, accompanied by its satellite - the Moon. At the same time, the date, month and zodiac sign are displayed on the disk around the planetary group (12 signs are made in the form of elegant figures). The rotating structure shows the passage of the Sun, Moon and Earth through all the zodiac signs for twelve months. The clock mechanism allows you to move the lunar ball around the Earth in 29 and a half days, which corresponds to the lunar month.

The disadvantage of this device is the complexity of its manufacture and the bulkiness of the design, which does not allow its use in a portable (wristwatch, pocket watch, etc.) watch.

Based on the foregoing, it can be concluded that, in general, all known astronomical clocks with an indication of the lunar phases have one significant drawback - the cumbersomeness of the clock mechanism, which does not allow its use in a portable watch. In the case of the display of the lunar phases on a portable clock, the indication of the phases of the moon is based on the observation of the moon from the earth, which in turn does not allow us to determine the location of our satellite relative to the earth and its visibility at one point or another on the earth.

Thus, the objective of this utility model is to create a design coupled with the details of the clock mechanism, which is configured to display the visible movement of the moon against the background of stars, which occurs due to reflection of the actual movement of the moon around the earth, which is accompanied by a change in the appearance of our satellite. Moreover, this design can be used both in a stationary clock (floor, mantelpiece, etc.), and in a portable watch (wristwatch, pocket watch, etc.).

To date, the prior art has not identified watches and clock mechanisms equipped with a mechanical device for displaying the visible movement of the moon against the background of stars with a continuous change in its appearance, i.e. the actual movement of the Moon relative to the Earth with a change in the phase of the Moon, where the model of the Moon is made with the possibility of movement relative to the model of the Earth and is constantly in the same orientation relative to the line of the Earth-Sun models.

To understand the objectives of the claimed solution, I would like to provide some clarifications.

It is known that the Moon during the stellar month always moves among the stars in the same direction - from west to east, or in direct motion. The visible path of the Moon in the sky is not a closed curve, constantly changing its position among the stars of the zodiac constellations. The apparent movement of the moon is accompanied by a continuous change in its appearance, characterized by the phase of the moon. On some days, the moon is not visible at all in the sky. On other days, it has the appearance of a narrow sickle, a semicircle and a full circle. The lunar phases are explained by the fact that the Moon, like the Earth, is a dark, opaque spherical body and, when moving around the Earth, occupies different positions relative to the Sun. Because of the remoteness of the sun, the sun's rays falling on the moon are almost parallel and always illuminate exactly half of the lunar ball; the other half remains dark. But, since part of the bright hemisphere and part of the dark are usually facing the Earth, the Moon most often seems to us an incomplete circle.

There are four main phases of the moon, which gradually pass one into another in the following sequence: new moon, first quarter, full moon, last quarter.

During the new moon, the moon passes between the sun and the earth, i.e. is in conjunction with the sun. In this case, the phase angle f (the angle between the directions from the Sun to the Moon and from the Moon to the Earth) during the new moon, the Moon passes between the Sun and the Earth, i.e. It is in conjunction with the Sun, and is equal to 180 °. The dark side of the moon is facing the earth and it is not visible in the sky.

Two days after the new moon, the Moon is visible in the form of a narrow sickle in the west, in the rays of the evening dawn, shortly after sunset, the Moon sickle, convex to the Sun, gradually expands from day to day and takes about a semicircle approximately 7 days after the new moon. The phase called the first quarter sets in. At this time, the moon is in the eastern quadrature, i.e. 90 ° east of the Sun, the phase angle is f = 90 °, and half of the illuminated and half of the unlit hemisphere of the Moon are facing the Earth. During this phase, the moon is visible in the first half of the night, and then goes beyond the horizon.

Every day, more and more of the illuminated hemisphere of the moon is visible from the Earth, and about 7 days after the first quarter, the full moon sets in when the moon looks like a full circle. During the full moon, the moon is in opposition to the sun, f = 0 °, and the entire illuminated hemisphere of the moon is facing the earth. The full moon is visible in the sky in the opposite direction to the sun (its ecliptic longitude differs from the ecliptic longitude of the sun by 180 °). Therefore, the full moon is visible in the sky all night; it rises around the time of the sunset, and sets around the time of its rise.

After the full moon, the Moon begins to “decrease”, “damage” appears on the western side of its disk, which gradually grows, as every day from the Earth you can see a smaller part of the illuminated hemisphere of the Moon. About 7 days after the full moon, the moon is again visible in the form of a semicircle. The last quarter is coming. At this time, the Moon is in the western quadrature, f = 90 °, and half of the illuminated and half of the unlit hemisphere of the Moon are again facing the Earth. But now the Moon is already 90 ° west of the Sun and is visible in the second half of the night, right up to the rising of the Sun.

Gradually, the damage to the lunar disk increases, the Moon again takes the form of a narrow sickle and is visible in the east, in the morning light, shortly before sunrise. After 2-3 days, the lunar sickle disappears, and the moon is again not visible in the sky, since approximately 7 days after the last quarter, a new moon again sets in.

Task and technical result

The objective of the proposed utility model and the technical result obtained from its use is to create an accurate and reliable to use, cheap to manufacture and suitable for installing in almost any analog watch (stationary or portable) a mechanical device for displaying the visible movement of the Moon against the background of stars, which occurs due to the reflection of the actual movement of the moon around the earth, which is accompanied by a change in the appearance of our satellite, the model of the moon is made with the possibility of two zheniya relative to the earth model and is always in the same orientation with respect to the line model of the Earth-Sun. It also allows you to determine the location of the moon relative to the earth and its visibility at one point or another on the earth.

Utility Model Disclosure

The problem is solved, and the required technical result when using the utility model is achieved by the fact that in the mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun, coupled with the parts of the clock mechanism, the Moon model (25) is configured to move relative to the Earth model and is constantly located the same orientation relative to the line of Earth-Sun models.

In this case, the mechanical device for displaying the actual motion of the moon consists of daily wheels (21), daily disk (22), moon wheels (23), moon disk (24), model of the moon (25), differential mechanism (26) and model of the Earth (27 )

In this case, the mechanical device for displaying the actual motion of the moon consists of a diurnal wheel (21), a diurnal disk (22), lunar wheels (23), a lunar disk (24), a model of the moon (25) and cargo 36.

In this case, the Moon model (25) is divided by a straight line into two equal parts of different colors, while the rotation of the Moon model (25) around the Earth relative to the Sun is carried out in such a way that this straight line is constantly perpendicular to the line connecting the centers of the Earth and the Sun.

In this case, the Earth model (27) makes one full revolution per day around its axis. In addition, names, signs or symbols of cities with the ability to determine the time in these cities are plotted on the Earth model (27) or on the drive element of the Earth model.

In addition, the Earth model (27) makes one full revolution per day, and the moon model (25) makes a complete revolution around the Earth model (27) in one synodic period.

In this case, the differential mechanism (26) rotates the moon model (25).

The differential mechanism (26) includes a carrier (30), freely rotating on the axis of rotation of the moon model, which is meshed with a stationary wheel (28), while the carrier (30) has a hole in which the axis of rotation of the first satellite (32) is fixed ) and the second satellite (33), the first differential wheel (31) is rigidly fixed on the axis of rotation of the moon model, and the moon model (25) is rigidly fixed on the hub of the second differential wheel (34), freely rotating around the specified axis.

At the same time, a mechanical device for displaying the apparent motion of the Moon against the background of stars with a continuous change in its appearance can be used both in a portable watch and in a stationary watch.

The Earth model (27) may take the form of a disk, sphere, or hemisphere, making one complete revolution in 24 hours.

During the rotation of the Earth model (27), one half of it can be darkened, while the other can remain light with the help of partially darkened glass or a plate with holes.

Also, the Earth model (27) can be set in motion by a clock mechanism, through a gear transmission.

Also, the Moon model (25) may take the form of a disk, sphere, or hemisphere.

In this case, the moon model (25) can be set in motion by a clock mechanism through gears.

In addition, the moon model (25) can be constantly located on one side to the direction of gravity due to the fact that one side of the moon model (25) is heavier than the other.

At the same time, a flat ring is located over the trajectory of the movement of the moon around the earth relative to the sun, partially overlapping the model of the moon, which can be made of a transparent or translucent material, perforated material or a solid opaque material.

The problem is solved, and the required technical result when using the utility model is achieved by the fact that a watch containing a clock mechanism, a dial, an analog time indicator additionally contains a mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun.

In this case, the clock may additionally contain a lunar phase indicator, which allows you to simultaneously observe the view of the moon during its actual movement around the earth and the view of the moon from the earth.

In this case, the model of the Sun can be in the center of the dial, and the model of the Earth with the model of the Moon rotating around it, rotate around the Sun.

The clock mechanism can be basic, commercially available, both in a standard version and with additional refinement, for example, a clock mechanism for watches with a 24-hour dial, a clock mechanism for watches with the ability to display time in different cities of the world.

Also, the clock mechanism can be either mechanical or electromechanical.

At the same time, a mechanical device for displaying the apparent motion of the Moon against the background of stars with a continuous change in its appearance can be used both in a portable watch and in a stationary watch.

In addition, the model of the Sun located outside the orbit of the Moon can be performed as a movable structure or element, or as a fixed element or pattern.

In this case, a mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun can be installed both on the side of the watch dial and on the back side of the watch.

Brief Description of the Drawings

The essence of the utility model is illustrated by drawings.

In the preferred, shown in the drawings, embodiments of a device for displaying the actual movement of the moon around the earth relative to the sun, there are the following structural elements:

1 - drum

2 - tribes of the central wheel,

3 - 1st central wheel,

4 - tribes of the intermediate wheel,

5 - an intermediate wheel,

6 - tribes of the second wheel,

7 second wheel

8 - tribe of the anchor wheel,

9 - anchor wheel,

10 - anchor fork,

11 - balance

12 - dog

13 - drum wheel,

14 - clockwork wheel,

15 - 2nd central wheel (friction),

16 - tribes of the gear wheel,

17 - gear wheel

18 minute drive

19-hour drive

20 - bill wheels

21 - daily wheels

22 - daily disk

23 - moon wheels

24 - moon disk

25 is a model of the moon,

26 is a differential mechanism

27 is a model of the Earth,

28 - fixed wheel

29 - crown

30 - drove

31 - 1st central wheel of the differential mechanism,

32 - 1st satellite,

33 - 2nd satellite,

34 - 2nd central wheel of the differential mechanism,

35 - bearing

36 - cargo

37 - The Sun,

38 - dial

39 is a flat ring,

40 is a variant of the phase of the moon visible from the Earth,

41 is an additional moon display element,

42 - tinted glass

43 - index of cities in the world.

In FIG. 1 shows a diagram of a clock mechanism with a device for displaying the actual movement of the Moon around the Earth relative to the Sun, which shows: drum 1, tribes of the central wheel 2, 1st central wheel 3, tribes of the intermediate wheel 4, intermediate wheel 5, tribes of the second wheel 6, second wheel 7, tribes of the anchor wheel 8, anchor wheel 9, anchor fork 10, balance 11, dog 12, drum wheel 13, clockwork wheel 14, 2nd central wheel (friction) 15, gear tribes of the gear wheel 16, gear wheel 17, 18 minute disc howl disk 19, bill wheels 20, diurnal wheels 21, diurnal disk 22, lunar wheels 23, lunar disk 24, model of the Moon 25, differential gear 26, model of the Earth 27, fixed wheel 28 and crown 26. In doing so, in FIG. 1 dashed line indicates a mechanical device for displaying the visible movement of the moon against the background of stars, which occurs due to reflection of the actual movement of the moon around the earth and is accompanied by a change in its appearance.

In FIG. 2 shows a diagram of a differential mechanism 26, which contains the lunar disk 24, the moon model 25, the stationary wheel 28, drove 30, the 1st central wheel of the differential mechanism 31, the 1st satellite 32, the 2nd satellite 33 and the 2nd central wheel differential mechanism 33.

In FIG. 3 shows a diagram of a device for displaying the movement of the Moon around the Earth relative to the Sun, where the constant location of one of the sides of the Moon’s model to the area of the Sun’s location is achieved due to the influence of gravitational forces, which show: the lunar disk 24, the model of the Moon 25, bearing 35 and load 36.

In FIG. 4 shows a variant of a stationary clock with a device for displaying the movement of the Moon around the Earth relative to the Sun, which shows: the lunar disk 24, model of the Moon 25, model of the Earth 27, the Sun 37 and dial 38.

In FIG. 5 shows the main positions of the model of the Moon on a stationary clock with a device for displaying the movement of the Moon around the Earth relative to the Sun, which shows: the lunar disk 24, the model of the Moon 25, the model of the Earth 27, the Sun 37 and the dial 38.

The arrows indicate the direction of movement.

In FIG. 6 shows the principle of displaying the main moon phase with a device that contains the lunar disk 24, the moon model 25, the Earth model 27, the Sun 37, the dial 38 and the moon phase variant visible from the Earth 40.

In FIG. 7 shows a stationary clock with a device for displaying the movement of the Moon around the Earth relative to the Sun, made with a flat ring 39, which shows: the model of the Moon 25, the model of the Earth 27, the Sun 37, the dial 38 and the flat ring 38.

In FIG. 8 shows the principle of displaying the main phases of the Moon with a device made in the embodiment with a flat ring 39, which shows: the lunar disk 24, the model of the Moon 25, the model of the Earth 27, the Sun 37, dial 38, the flat ring 39 and the variant of the moon phase visible from the Earth 40 .

In FIG. 9 shows a stationary clock with a device for displaying the movement of the Moon around the Earth relative to the Sun, made in the embodiment with an additional display of the Moon, which shows: the lunar disk 24, the model of the Moon 25, the model of the Earth 27, the Sun 37, the dial 38 and the additional display element of the moon 41.

In FIG. 10 shows a stationary clock with a device for displaying the movement of the Moon around the Earth relative to the Sun, made in the embodiment with the dimming of a part of the Earth’s model 27, which shows: the moon disk 24, the Moon’s model 25, the Earth’s model 27, the Sun 37, dial 38 and tinted glass 42.

In FIG. 11 shows a wristwatch with a device for displaying the movement of the Moon around the Earth relative to the Sun, made in the embodiment when the Sun is located in the center of the dial, and the model of the Earth and the Moon move around it, which shows: daily disk 22, lunar disk 24, model of the Moon 25, Earth model 27, crown 29, Sun 37 and dial 38.

In FIG. 12 shows a wristwatch with a device for displaying the movement of the Moon around the Earth relative to the Sun, made in the world time display option, which shows: the lunar disk 24, the Moon model 25, the Earth model 27, the crown 29, the Sun 37, dial 38 and the index of world cities 43.

Utility Model Implementation

The utility model is a watch with a device for displaying the actual movement of the moon around the earth relative to the sun.

The design is based on the model of the Moon, divided by a straight line into two equal parts of different colors, rotating around the Earth relative to the Sun so that the direct dividing model of the Moon into two equal parts is constantly perpendicular to the straight line connecting the centers of the Earth and Sun models.

In FIG. 1 is a diagram showing one embodiment of a clock mechanism with a device for displaying the actual movement of the moon around the earth relative to the sun.

As shown in the diagram shown in Fig. 1, the wound spring of the drum 1, while unrolling, drives the main wheel system of the clock mechanism, that is, the tribes of the central wheel 2 and the 1st central wheel 3, which is engaged with the tribe 4 of the intermediate wheel 5 where the intermediate wheel 5 is meshed with the tribe 6 of the second wheel 7, and the second wheel 7 with the tribe 8 of the anchor wheel 9, the release of which is determined by the anchor fork 10 and the balance unit 11. On the axis of the 1st central wheel is located the 2nd central wheel (fr IK), which, rotating, drives the tribes 16 of the gear wheel 17 and the gear wheel 17 itself, which is in engagement with the minute disk 18. The minute disk 18, through the bill wheels 20, drives the clock disk 19, which drives the daily disk 22, on the hub of which a model of the Earth 27 is fixed, by means of daily wheels 21.

It is worth noting that the daily wheels 21 allow one full revolution of the daily disk 22 for twenty-four revolutions of the minute disk, so that the Earth model 27 makes one full revolution per day.

The daily disk 22 is meshed with the lunar wheels 23, which are meshed with the lunar disk 24. The lunar disk 24 has a hole in which the axis is fixed which is the center of rotation of the moon model 25.

It is worth noting that the lunar wheels 23 make it possible to make one full revolution of the lunar disk 24 for twenty nine and a half turns of the daily disk 21, so that the model of the moon 25 makes a full revolution around the model of the earth 27 for twenty nine and a half earth days.

The rotation of the model of the Moon 25 is carried out by means of a differential mechanism 26, the design diagram of which is shown in FIG. 2.

As seen in FIG. 2 drove 30, freely rotating on the axis of rotation of the moon model, be engaged with the stationary wheel 28 so that when the lunar disk 24 rotates, drove 30 is driven. The carrier 30 has a hole in which the axis of rotation of the 1st satellite 32 and the 2nd satellite 33 is fixed. On the axis of rotation of the moon model the 1st central differential wheel 31 is fixedly fixed, which is meshed with the 1st satellite 32, so that during the rotation of carrier 30, the first satellite 32 rotated. Since the first satellite 32 is rigidly fixed with the second satellite 33, which is meshed with the second central differential wheel 34, rotation from the first satellite 32 is transmitted to 2 -th central differential wheel 34, on the hub of which is rigidly fixed model of the moon.

In order for the model of the Moon 25 to always remain in the same orientation relative to the Earth-Sun line, it is necessary that its angular velocity relative to the lunar disk ω _l be equal to the angular velocity of the lunar disk ω _d , but have the opposite direction. For this, a differential mechanism 26 is used, the circuit of which is shown in FIG. 2. The differential mechanism 26 consists of a carrier 30, the 1st central wheel of the differential mechanism 32 and the 2nd central wheel of the differential mechanism 34 having the number of teeth z _c1 and z _c2 , the 1st satellite 32 and the 2nd satellite 33, which rigidly fixed to each other, with teeth z _c1 and z _c2 . The carrier 30 rotates about the axis of the moon model 25 and is made in the form of a gear wheel with a hole for the axis of rotation of the satellites. The carrier 30 has gearing with a fixed gear 28 and has an angular velocity relative to the lunar disk, which can be calculated by the following formula:

ω _in = ω _d * z _nk / z _in ,

where ω _in is the angular velocity of the carrier, ω _d is the angular velocity of the lunar disk, z _nk is the number of teeth of the stationary disk, z _in is the number of teeth of the carrier.

It is worth noting that the 1st central gear of the differential mechanism 31 is rigidly fixed to the lunar disk 24, while the 2nd central gear of the differential mechanism 34 is free and connected to the model of the Moon 25. Then, according to the Willis formula, you can calculate the gear ratio from the carrier 30 to the 2nd central gear of the differential mechanism 34 relative to the moon disk (i.e., the moon model ω _l ):

U _is = ω _a / ω _n = ((z _{^ 2} * z _c1) / (z * z _{u1 c2))} / (1- (z _{^ 2} * z _c1) / (z _u1 * z _c2))

or

U _ow = ω _in / ω _l = (ω _d * z _nk / z _in ) / ω _l

And since ω _d = ω _l , we have the following relation:

_nc -z / z _in = ((z _{^ 2} * z _c1) / (z * z _{u1 c2))} / (1- (z _{^ 2} * z _c1) / (z _u1 * z _c2))

where U _ow is the gear ratio, z _c1 is the number of teeth of the 1st central wheel of the differential mechanism, z _c2 is the number of teeth of the 2nd central wheel of the differential mechanism, z _c1 is the number of teeth of the 1st satellite, z _c2 is the number of teeth 2- go satellite.

By constructing the number of teeth satisfying this ratio by design conditions, we obtain the desired motion of the lunar disk.

It is also worth noting that if the mechanism operates in a stationary state, a variant is possible where a constant location of one of the sides of the model of the Moon to the area of the location of the Sun is achieved due to the influence of gravitational forces. As shown in FIG. 3 this is achieved by weighting one of the halves of the moon model.

A device for displaying the movement of the Moon around the Earth relative to the Sun can be performed with both a stationary clock and a portable one.

In addition, a device for displaying the movement of the Moon around the Earth relative to the Sun can be performed both on the side of the watch dial and on the back side of the watch.

Also, a device for displaying the movement of the Moon around the Earth relative to the Sun can be made with the Earth located in the center of the Earth and the Moon moving around it.

It is worth noting that the device for displaying the movement of the Moon around the Earth relative to the Sun is made so that the model of the Sun is located outside the orbit of the Moon and can be made as a movable structure or element, or as a fixed element or pattern.

Also, the model of the Earth may take the form of a disk, sphere or hemisphere, making one complete revolution in 24 hours.

In addition, during the rotation of the Earth's model, one half of it can be darkened, and the other can remain light with the help of partially darkened glass or a plate with holes of a given shape, and the bright side is constantly facing the Sun.

It is worth noting that the model of the Earth can be set in motion by a clock mechanism, through a gear transmission.

The Moon model makes one complete revolution in a period approximately equal to one lunar month or synodic period, approximately equal to 29.5 days.

In this case, the model of the moon may take the form of a disk, sphere or hemisphere.

It is worth noting that the model of the Moon can be driven by a clock mechanism through gears.

It is worth noting that in one embodiment, the moon model can always be located on one side to the direction of gravity due to the fact that one side of the moon model is heavier than the other.

It is worth noting that the surface of the moon model is visually divided into two equal parts, where one is light and the other is dark.

It is worth noting that the bright side of the Moon model is constantly directed towards the location of the Sun so that the straight line dividing the Moon model into two equal parts is constantly perpendicular to the straight line directed from the center of the Sun model to the center of the Earth model.

In addition, a flat ring is located over the path of the moon around the earth relative to the sun as shown in FIG. 7, a half-overlapping model of the moon, which may be made of a transparent or translucent material, a perforated material, or a solid opaque material.

It is worth noting that the clock may have an additional indicator of the lunar phases, allowing you to simultaneously observe the view of the moon during its actual movement around the earth and the view of the moon from the earth.

It is worth noting that the Sun can be in the center, and the Earth with the Moon rotating around it, rotate around the Sun.

It is worth noting that the device for displaying the movement of the Moon around the Earth relative to the Sun can be used in any mechanical and electromechanical watches.

It is worth noting that the device for displaying the movement of the Moon around the Earth relative to the Sun allows not only to determine the phases of the moon, but also to determine the visibility of the moon at one point or another on the Earth.

The description discloses one possible embodiment of the utility model, which in no way limits the possible variants of its execution.

The watch can be both stationary and portable.

The clock mechanism can be basic, commercially available, both in a standard version and with additional refinement, for example, a clock mechanism for watches with a 24-hour dial, or a clock mechanism for watches with the ability to display time in different cities of the world.

As options for the execution of individual elements of the case, parts, watch assemblies, various known and traditional for watch production technologies, materials and design solutions commonly used in watchmaking can be used [2-5].

This ensures the achievement of the required technical result, namely: increasing accuracy and reliability in use, the ability to install in almost any analog clock (stationary or portable) a mechanical device to display the visible movement of the moon against the background of stars, which occurs due to reflection of the actual movement of the moon around Earth, which is accompanied by a change in its appearance. This additionally allows you to determine the location of the moon relative to the earth and its visibility at one point or another on the earth.

The analysis also shows that all the general and particular features of the utility model are essential, since each of them is necessary, and all together they are not only sufficient to achieve the goal of the utility model, but also allow you to implement the utility model in an industrial way.

Information sources:

1. The magazine “My watch. Everything about watches and style ”, No. 5, November-December 2008, pp. 78-79.

2. Kharitonchuk A.P. Reference book for watch repair, M., 1977, p. 18, 21.

3. Romanov A.D. Designing time devices. M., 1975, p. 140.

4. Tarasov S.V. Technology of watch production, M., 1963.

5. Popova V.D., Goldberg N.B. Device and assembly technology of watches. M., 1989).

Claims (25)

1. A mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun, coupled with the details of the clock mechanism, characterized in that the Moon model (25) is configured to move relative to the Earth model and is constantly in the same orientation relative to the line of the Earth-Sun models , while the movement of the moon model (25) is carried out by kinematic connection with the clockwork. 2. The device according to p. 1, characterized in that the mechanical device for displaying the actual motion of the moon around the earth relative to the sun consists of diurnal wheels (21), diurnal disk (22), lunar wheels (23), lunar disk (24), model of the moon (25), differential mechanism (26) and Earth model (27). 3. The device according to p. 1, characterized in that the mechanical device for displaying the actual movement of the moon around the earth relative to the sun consists of a diurnal wheel (21), a diurnal disk (22), lunar wheels (23), a lunar disk (24), a model of the moon (25) and cargo 36. 4. The device according to claim 1, characterized in that the Moon model (25) is divided by a straight line into two equal parts of different colors, while the rotation of the Moon model (25) around the Earth relative to the Sun is carried out in such a way that this straight line is constantly perpendicular to the straight line connecting the centers of the Earth and the Sun. 5. The device according to p. 2 or 3, characterized in that the model of the Earth (27) makes one full revolution per day around its axis. 6. The device according to claim 2 or 3, characterized in that the names, signs or symbols of cities with the ability to determine the time in these cities are plotted on the Earth model (27) or on the drive element of the Earth model. 7. The device according to claim 2 or 3, characterized in that the model of the Moon (25) makes a complete revolution around the model of the Earth (27) in one synodic period. 8. The device according to p. 2, characterized in that the differential mechanism (26) rotates the moon model (25). 9. The device according to p. 8, characterized in that the differential mechanism (26) includes a carrier (30), freely rotating on the axis of rotation of the moon model, which is engaged with a stationary wheel (28), while the carrier (30) has a hole in which the axis of rotation of the first satellite (32) and the second satellite (33) is fixed, the first differential wheel (31) is rigidly fixed on the axis of rotation of the moon model, and on the hub of the second differential wheel (34), freely rotating around the specified axis, firmly fixed model of the moon (25). 10. The device according to claim 1, characterized in that it can be used both in a portable watch and in a stationary watch. 11. The device according to p. 1, characterized in that the model of the Earth (27) may be in the form of a disk, sphere or hemisphere, making one complete revolution in 24 hours 12. The device according to p. 11, characterized in that during the rotation of the Earth model (27) one half of it can be darkened and the other remains light with the help of partially darkened glass or a plate with holes. 13. The device according to p. 11, characterized in that the model of the Earth (27) can be driven by a clock mechanism through a gear transmission. 14. The device according to claim 1, characterized in that the model of the Moon (25) may take the form of a disk, sphere or hemisphere. 15. The device according to p. 1, characterized in that the moon model (25) can be driven by a clock mechanism through gears. 16. The device according to p. 3, characterized in that the moon model (25) can always be located on one side to the direction of gravity due to the fact that one side of the moon model (25) is heavier than the other. 17. The device according to p. 1, characterized in that on top of the trajectory of the moon around the earth relative to the sun, in addition to determining the phases, there is a flat ring partially overlapping the model of the moon, which can be made of transparent or translucent material, perforated material or solid opaque material. 18. A clock comprising a clock mechanism, a dial, an analog time indicator, characterized in that it further comprises a mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun according to any one of paragraphs. 1-17. 19. The watch according to p. 18, characterized in that it can additionally contain an indicator of the lunar phases, allowing you to simultaneously observe the view of the moon during its actual movement around the earth and the view of the moon from the earth. 20. The watch according to claim 18, characterized in that the model of the Sun can be in the center of the dial, and the model of the Earth with the model of the Moon rotating around it, rotate around the Sun. 21. Watches according to claim 18, characterized in that the clock mechanism can be basic, commercially available, both as a standard version and with additional refinement, for example, a clock mechanism for watches with a 24-hour dial, a clock mechanism for watches with the ability to display time in different cities of the world. 22. Clocks according to claim 18, characterized in that the clock mechanism can be either mechanical or electromechanical. 23. The watch according to claim 18, characterized in that the mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun can be used both in a portable watch and in a stationary watch. 24. The watch according to claim 18, characterized in that the model of the Sun, located outside the orbit of the Moon, can be made as a movable structure or element, or as a fixed element or pattern. 25. The watch according to claim 18, characterized in that the mechanical device for displaying the actual movement of the Moon around the Earth relative to the Sun can be installed both from the side of the watch dial and from the back of the watch.