RU102817U1 - LUNAR PHASE INDICATION DEVICE FOR THE JEWISH CALENDAR - Google Patents

Abstract

 1. The device for indicating the lunar phases according to the Hebrew calendar, characterized in that it contains a clock mechanism mating with each other, a time indicator with an accuracy of 1 helk, means for indicating the moon phases according to the Hebrew calendar with a period of 765433 Helekim, and means for indicating the lunar phases on the watch dial. ! 2. The device for indicating the lunar phases according to the Jewish calendar according to claim 1, characterized in that the time indicating device with an accuracy of 1 helk is made in the form of a gear pair with a gear ratio of 1 to 18 and a drive from the second wheel of the clock mechanism. ! 3. The device for indicating the lunar phases according to the Jewish calendar according to claim 1, characterized in that the means for indicating the lunar phases according to the Jewish calendar with a period of 765433 helekim is made in the form of a gearbox with a gear ratio of 765433 driven by a second wheel of a clockwork and a gear pair with a gear ratio of 1 to 18.! 4. The display of the lunar phases according to the Jewish calendar according to claim 3, characterized in that the gearbox with a gear ratio of 765433 is made in the form of a multi-stage gearbox with the possibility of obtaining a gear ratio of 765433 by factoring it in simple gear ratios, for example 131 and 5843, as well as with the possibility of integrating smaller gear ratios by means of differential adders, for example with the possibility of integrating gear ratio 131 as the sum of gear ratios 128 and 3, and integrating gear ratio 5843 as the sum gear ratios 5808 and 35, with the final possibility of obtaining a gear ratio of 765433, for example, as a combination of blocks of a multi-stage gearbox with gear ratios (128 + 3) × (5808 + 35). ! 5. Device

Description

The utility model relates to chronology, to mechanical calendar mechanisms and methods for displaying the phases of the moon in time devices, for accurate and realistic display of the phases of the moon in hours, and can be used in the manufacture of wrist watches, pocket watches or desktop clocks or watch devices with indication of the full moon, new moon and intermediate phases of the moon (lunar phases), as well as in chronological and clock mechanisms for determining time, numbers, months, years, in watches or clock devices with indication of Jewish time units and lunar phases other devices using the calculation time of the lunar calendar.

BACKGROUND

Many ancient peoples - the Babylonians, Jews, Greeks, Chinese - previously used the lunar calendar, but subsequently switched to the lunar-solar calendar system, and then to the solar calendar system in the form of the Julian, originally widespread until 1582, and then generally accepted at present Gregorian calendar time.

Lunar calendars are based on the lunar cycle, solar calendars are based on the solar cycle, and lunar-solar calendars are based on the lunar-solar cycle ..

In many countries of the Near and Middle East, for example, Algeria, Indonesia, Morocco, Pakistan, the lunar calendar is officially used, based solely on the visible movement of the moon (lunar cycle) and completely independent of the movement of the sun (solar cycle).

In some countries, in particular in Israel, the solar Gregorian and lunar-solar Jewish calendars are simultaneously used.

The calendar year according to the solar calendar is equal to the duration of one revolution of the Earth around the Sun, is measured by the period of time between two winter solstices and is considered equal to 365 or 366 days.

The calendar year according to the lunar calendar is equal to the duration of 12 synodic months, equal to the time interval between repetitions of the change of phases of the moon.

The lunar astronomical synodic month lasts 29.5305889 sunny days.

The lunar astronomical year is 354.36706668 sunny days.

In the lunar-solar calendar, the duration of a calendar year ranges from 353 to 385 days.

The lunar month lasts 29 or 30 days.

The Hebrew concept, the Torah’s doctrine of time, considers it as a cycle or spiral - just as the Earth moves around its axis and in orbit around the Sun, passing through various phases and the resulting seasons. Jewish time according to the doctrine must be accurate and definite.

The smallest Jewish traditional unit of time is the helk (part).

Helek is 3 and 1/3 seconds or 1/18 minutes.

The hour consists of 1080 helekim.

Explaining this division of time, Rambam in Gilhot kiddush godesh, 6: 2, writes: “Day and night, regardless of the time of the year, is twenty-four hours. And the hour is divided into eighteen parts, because this number can be divided into two, four, eight , three, six, nine, five and ten, "so that you can make a fairly accurate calculation.

According to the teachings of the Torah, daytime is divided into twelve equal parts, which are called shaot zmaniot - "time clocks", that is, hours, parts, the duration of which depends on the time of year.

According to one point of view, daylight hours should be counted from sunrise to sunset.

According to another point of view - from dawn to dark.

In winter, daytime hours are shorter and in summer longer.

This system is necessary to calculate the time for the fulfillment of many Jewish commandments.

For example, alaha (Jewish law) requires that Amida (the main prayer, which is read silently and standing, hence the name amide, which means "standing") was read in the first third of the day, that is, during the first four time hours.

If the duration of daylight hours at this time of year and in this area is, for example, fourteen hours, then the latest time for Amida is approximately four hours and forty minutes after sunrise.

This is determined by the fact that if you divide fourteen hours into twelve, you get one hour and ten minutes.

A day (day) consists of twenty four hours and begins with the sunset - shkiyat ahama. A day is the time of the complete revolution of the Earth around its axis.

A week consists of seven days. God created the world in six days and interrupted work on the seventh day - Shabbat.

The lunar month is the time it takes the moon to complete a complete revolution around the earth. Since this period is a little more than twenty nine and a half days, the year has months consisting of twenty nine and thirty days.

A year is a period during which the Sun, in a complete cycle, returns to its starting point. During this time, the Earth makes a complete revolution around the Sun, which takes about three hundred sixty-five whole and one fourth of the day.

Seven thousand years make up the historical cycle. According to the Sangedrin treatise of the Babylonian Talmud (97a), a thousand years for God is like one day of creation. Here the perspectives change, depending on how it is viewed in a micro or macro perspective. That is, seven thousand years, like His seven days, constitute a separate cycle of human history.

Descriptions of the mechanisms and devices for indicating the Jewish units of time and indicating the lunar phases according to the Jewish calendar in the scope of the search were not identified.

Known calendar devices having a lunar phase indicator, traditionally called the lunar calendar, however, they are mainly designed for domestic or pseudo-astronomical use.

Known electromechanical watches with a moon phase indicator, comprising a case with a dial and arrows placed on it, associated with an electromechanical drive, including a pulse generator stabilized by a quartz stabilizer, a frequency divider, a stepping mechanism and gears of an arrow drive, characterized in that in addition to the numbers on the dial the image of the phases of the moon (the symbol of the new moon, the growing moon, the symbol of the full moon and the waning moon) is plotted, and the electromechanical drive of the additional arrow is adjusted so It means that one turn of the arrow on the dial corresponds to a synodic lunar month equal to 29.530588 sunny days [1].

Known chronometer Geylison William E. (US) for displaying the phases of the moon when indicating the time of day, containing a time indicator located on the dial, and indicator elements of the phases of the moon, in which the indicator elements of the phases of the moon are configured to supply electric power to them to form a contrasting combination light and shadow synchronously with the phases of the moon, in addition, the chronometer contains a controller for selectively supplying electrical power to the indicator elements of the phases of the moon and a microprocessor to control the controller. Moreover, the indicator elements of the phases of the moon contain liquid crystal elements and contain four adjacent discrete indicator sections made with the possibility of sequential supply of electric power to them to display the eight phases of the moon [2].

The closest in technical essence and achieved by using the technical result (prototype) is the mechanical calendar Michel Parmigiani installed mainly in analogue clocks, which shows on a scale consisting of sequentially located digits from 1 to 30 of the month, taking into account 29-day and 30- daytime months and usually made amendments to the 30-year cycles of the lunar calendar through special mechanisms, the first of which provides movement from the rotation part and at the end of each day Changes the month indicator in one step. The second mechanism associated with the first one ensures the transition from the 29th to the 1st day of the next month at the end of each lunar month with 29 days, and the third mechanism temporarily neutralizes the action of the second mechanism at the end of the additional corrections determined by the 30-year cycle in the last day of the twelfth and final month of these years [3, prototype].

The technical disadvantages of the prototype calendar are the technical complexity in implementation and operation, and accordingly, its very high cost and practical inaccessibility for the vast majority of consumers, as well as the inability to measure and display Jewish time units on the solar-lunar Jewish calendar.

TASKS AND TECHNICAL RESULTS

The objective of the proposed utility model and the technical result obtained from its use is to create a device that is simple in design, accurate and reliable in use, cheap to manufacture, and suitable for installation in practically different analog clocks to indicate with high accuracy the periodicity of lunar phases and calendar devices using in its cycle, the periodicity of the phases of the moon, the use for scientific and educational purposes to understand the attitude of ancient peoples to the course and measurement of time.

DISCLOSURE OF A USEFUL MODEL

The tasks are solved and the required technical result is achieved by the fact that the device for indicating the lunar phases according to the Hebrew calendar contains a clock mechanism mating with each other, means for indicating the time with an accuracy of 1 Helek, means for indicating the lunar phases according to the Jewish calendar with a period of 765433 Helekim, and means for indicating the moon phases on the dial of the watch.

The time indicator with an accuracy of 1 helk is made in the form of a gear pair with a gear ratio of 1 to 18 and driven by a second wheel of the clock mechanism.

The Hebrew moon phase indicator according to the Hebrew calendar with a period of 765433 is made in the form of a gearbox with a gear ratio of 765433 driven by a second wheel of a clockwork and a gear pair with a gear ratio of 1 to 18.

A gearbox with a gear ratio of 765433 is made in the form of a multi-stage gearbox with the possibility of obtaining a gear ratio of 765433 by factoring it into simple gear ratios, for example 131 and 5843, as well as with the possibility of integrating smaller gear ratios by means of differential adders, for example with the possibility of integrating a gear ratio 131 as the sum of gear ratios 128 and 3, and the integration of gear ratio 5843, as the sum of gear ratios 5808 and 35, providing the final possibility of obtaining gear ratio of about 765,433, such as a set of blocks of the multi-stage gearbox with gear ratio (128 + 3) × (5808 + 35).

The means of indicating the phases of the moon on the watch dial is made in the form of a window in the dial and located under the dial of the disk with the images of the moon with the possibility of rotation of the disk with the images of the moon with a period of 765433 chelekim and indication of the phases of the moon in the window of the dial.

DESCRIPTION OF DRAWINGS

The essence of the utility model is illustrated by the drawings of figures 1-13.

Figure 1, 2 shows the structural and kinematic diagrams of a multi-stage gearbox with a gear ratio of 765433 with multipliers in the form of a, b, c, d, e, f blocks mating with each other, which together provide the required gear ratio 765433, where a is a block gearbox with a gear ratio of 128, b is a gear unit with a gear ratio of 3, c is an adder block (sums gear ratios of 128 and 3 of blocks a and b), d is a gear box with a gear ratio of 131 × 35 = 4585, e is a gear box with gear ratio 131 × 5808 = 760848, f - adder block sums the gear ratio e number 4585 760 848 and blocks d and e to give the final desired transmission ratio 765,433.

Figure 3 shows the kinematic diagram of block a with a gear ratio of 128, which contains a gear 1 of block a with 56 teeth, wheel 2 of block a with 40 teeth, tribes 3 of block a with 10, mounted on the axis of the drive of the indicator of the phases of the moon 40, teeth, wheel 4 blocks a with 40 teeth. tribe 5 block a with 10 teeth, tribe 6 block a with 10 teeth, wheel 7 block a with 40 teeth, tribe 8 block a with 14 teeth, wheel 9 block a with 48 teeth.

Figure 4 shows the kinematic diagram of block b with a gear ratio of 3, which contains an engaged gear wheel 10 of block b with 72 teeth, wheel 11 of block b with 40 teeth and tribes 12 of block b with 10 teeth, wheel 13 of block b with 48 teeth .

Figure 5 shows the kinematic diagram of the adder block c, which summarizes the gear ratios 128 and 3 of the blocks a and b with the gear ratio 3 and which contains the gear wheel 14 (adder carrier) of the block with 80 teeth, the wheel 15 (central wheel 1 ) a block with 48 teeth, a wheel 16 (a central wheel 2) of a block with 48 teeth, a tribe 17 (satellite) of a block with 14 teeth and a tribe of 18 (satellite) a block with 14 teeth.

Figure 6 shows the kinematic diagram of block d with a gear ratio of 131, which comprises gears 19 of block d with 10 teeth, wheel 20 of block d with 70 teeth, tribes 21 of block d with 10 teeth, wheel 22 of block d with 50 teeth , wheel 23 of block d with 40 teeth and wheel 24 of block d with 48 teeth.

Fig. 7 shows a kinematic diagram of a block e with a gear ratio of 5808, which comprises an engaged gear wheel 25 of a block e with 66 teeth, a tribe 26 of a block e with 6 teeth, a wheel 27 of a block e with 66 teeth, a tribe 28 of a block e with 6 teeth wheel 29 of block e with 60 teeth, tribe 30 of block e with 10 teeth, tribes 31 of block e with 10 teeth and wheel 32 of block e with 96 teeth.

On Fig shows a kinematic diagram of the adder block f, which summarizes the gear ratios 131 and 5808 of blocks d and e and which contains the meshing wheel 33 of block f with 48 teeth, tribes 34 of block f with 14 teeth, wheel 35 of block f with 48 teeth, tribes 36 of block f with 14 teeth, tribes 37 of block f with 14 teeth and tribes 38 (satellite) of block with 14 teeth, and it is also shown that the wheel 35 of block f is mounted on the axis of the regima 39.

Figure 9 shows the layout kinematic diagram of the gearing of the wheel 9 of block a with wheel 15 with 48 teeth of block c.

Figure 10 shows the interface circuit of the block of the 1st multiplier 45, accelerating the speed of rotation by 18 times, with the clock mechanism 44 by means of the second wheel 43, the drive wheel of the regima 53, the axis of the second wheel 41, the axis 42, the axis of the wheel of the regima 42 and the wheel of the regima 54.

In Fig. 11 - see PDM - 11/09/10, the pairing mechanism of the clock mechanism 44 from the block of the 1st multiplier 45, accelerating the rotation speed by 18 times, described above by the gear unit 46, slowing down the rotation speed by 765433 times and the moon phase indicator block, is shown 47 on the dial of the watch.

12 shows a general view of a wristwatch with an integrated device according to a utility model, including a watch case 48, a watch dial 49, a moon phase indicator 50, clock and minute hands 51 and a crown 52.

On Fig shows a General view of a table clock with an integrated device according to a utility model, including a watch case 48, a watch dial 49, a phase indicator of the moon 50, the clock and minutes 51.

IMPLEMENTATION AND INDUSTRIAL IMPLEMENTATION OF A USEFUL MODEL

The device for indicating the lunar phases according to the Jewish calendar is based on the use of the period of the synodic month, which is fundamental in the calculations according to the Jewish calendar.

The period of the synodic month used by Jews to calculate the lunar calendar is incredibly accurate, is the basis of the Jewish calendar and appears in all modern sources describing the Jewish calendar.

This period is mentioned in the Talmud and Almagest: “He told them r. Gamaliel: I received this from the house of my father’s father: the moon can’t be renewed earlier than twenty-nine and a half days, two-thirds and 73/1080 hours ”(Rosh-ha-Shana. 25a)

The Jewish time reference system divides one hour into 1080 equal parts, called helks, in the plural helekim (Hebrew - “part”).

Accordingly, one minute contains 18 helekim.

In turn, one helk is 3 and 1/3 seconds or 76 regs, in the plural - regaim (Heb. - “instant”).

The average for 19 years (the insertion cycle of additional months) the duration of the Jewish calendar year is 29 days 12 hours 44 minutes 3 1/3 sec × 235/19 = 365 days 5 hours 55 minutes 25 8/19 sec, which is 365 days 5 hours 55 25 minutes and 32 regim.

According to the Hebrew calendar, the lunar month or the cycle of changing the phases of the moon is 29 days 12 hours 44 minutes and 3 1/3 seconds or 29 days 12 hours 44 minutes and 1 helek or 29 d 12 h 793 helek or 765433 helek.

Thus, in the practical use of the Jewish time system according to the Jewish lunar-solar calendar, the practical task of indicating the time with an accuracy of 1 heleck arises, and the task of accurately indicating the lunar phases according to the Hebrew lunar-solar calendar is solved by providing an indication of the period 765433 Helekim.

In order to obtain a rotation with a frequency of one revolution in 1 helek (3 and 1/3 seconds) in a mechanical analogue clock, which is necessary to obtain the necessary frequency of rotation of the moon phase indicator with a 765433 helekim cycle, it is possible to use a gear ratio of 1 to 18 for a second a wheel making one revolution per minute (1 revolution for 18 helekim).

For example, if the wheel mounted on the second will work with the tribe with the ratio of the number of teeth of the wheel and the tribe equal to 18, then we get the rotation frequency of the axis of the tribe in 1 helk.

In order to obtain a mechanical analogue clock or other mechanical device required for rotation of the lunar phase indicator and accurate indication of the moon phase cycle with a period equal to 765433 helekim, it is possible to use a gear pair with a direct gear ratio of 1/765433. This is feasible from a technical point of view in the manufacture of a huge gear wheel with a diameter of several meters with 765433 teeth, and may be suitable for use in very large-sized, for example, tower, watches, but this option significantly limits the possible volume of industrial implementation of the utility model.

It is also possible to obtain the required gear ratio 765433 by two factors, for example 131 × 5843, that is, by applying two gear pairs, in one of which the gear ratio is 131, in the other 5843. This solution is also physically feasible, but also so bulky and oversized that taking into account modern technologies, it is really possible in the manufacture of only large floor or table clocks. This also does not exclude, but significantly limits the possible volumes of industrial implementation of this solution.

The basis of the preferred embodiment of the utility model suitable for use in analogue watches is the use of a multi-stage gearbox with the integration of differential adders, in which the prime factors of 131 and 5843 of the required gear ratio 765433 can be decomposed by the product of the sums of lower gear ratios with the possibility of obtaining a mechanism design in a substantially smallest dimensions, for example, a multi-stage gearbox with a gear ratio of (128 + 3) × (5808 + 35) = 765433.

Thus, it is possible to achieve the necessary gear ratio 1/765433 by using differential adders and a group of kinematic chains, allowing to obtain large gear ratios, for example:

56/10 * 40/10 * 40/10 * 40/14 * 48/48 * 0.5 = 128

80/10 * 70/10 * 50/40 * 48/48 * 0.5 = 35

80/6 * 66/6 * 66/10 * 60/10 * 96/48 * 0.5 = 5808

72/10 * 40/48 * 0.5 = 3

One of the embodiments of the utility model for obtaining the necessary gear ratio 1/765433 is the creation of a gearbox that slows down the rotation from the axis of the regima (rotation speed - one revolution in 3 and 1/3 seconds or 1 helk) to the axis of the moon phase indicator at a speed rotation 1 revolution for 765433 chelekim.

The required gear ratio 765433 is decomposed into two prime factors 131 and 5843, which in turn are represented as sums of smaller gear ratios, for example, 131 as the sum of 128 + 3, and 5843 as the sum of 5808 + 35. As a result, we get (128 + 3) * (5808 + 35) = 765433.

To simplify the implementation of the design of the device according to the utility model, each of the gear ratios is implemented as separate kinematic chains of the gearbox:

the number 128 is represented as the product 4 * 4 * 4 * 2,

number 35 as a product of 5 * 7,

number 5808 as a product 11 * 6 * 11 * 8,

and the number 3 remains.

As a result, we get the gearbox in the form of a multiplier with the required gear ratio 1/765433.

Features of the design of the mechanism according to the utility model are shown in detail in the above-described drawings of Figures 1-13.

Thus, the utility model provides the possibility of industrial production and practical use of a compact in design, accurate and reliable to use, cheap to manufacture and suitable for installation in almost any analog clock device for the accurate indication of the lunar phases according to the lunar-solar Jewish calendar.

Individual parts and components of the device can be made of materials commonly used in the watch industry according to conventional technologies known in the watch industry using conventional equipment.

In general, given the novelty and non-obviousness of the utility model, shown in the section "Background" and "The essence of the utility model", the materiality of all the general and particular features of the utility model, proved in the section "Disclosure of the utility model", and also shown in the section "Implementation of the utility model ", the feasibility of a utility model and the solution of the task and the achievement of a technical result, in our opinion, the claimed group of inventions satisfies all the eligibility requirements for a utility model.

Thus, there is every reason to assert that the utility model meets all the requirements of eligibility, and the analysis 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 solve the task and achieve the desired technical result, but also allow you to implement a useful model in an industrial way.

The solution of the general problem and the achievement of a single technical result proves the existence of a single inventive concept and the possibility of combining a group of inventions into one application.

INFORMATION SOURCES

1. RU patent for utility model No. 17373, G04B 47/00, publ. 03/27/2001.

2. Patent RU No. 2144749, G04B 19/26, publ. 01/10/1999, WO 95/07499, 03.16.95

3. Patent EP 0606576, G04B 19/253; G04B 19/00, publ. 02/05/1999 (US 5379272) (prototype).

Claims (5)

1. The device for indicating the lunar phases according to the Hebrew calendar, characterized in that it contains a clock mechanism mating with each other, a time indicator with an accuracy of 1 helk, means for indicating the moon phases according to the Hebrew calendar with a period of 765433 Helekim, and means for indicating the lunar phases on the watch dial. 2. The device for indicating the lunar phases according to the Jewish calendar according to claim 1, characterized in that the time indicating device with an accuracy of 1 helk is made in the form of a gear pair with a gear ratio of 1 to 18 and a drive from the second wheel of the clock mechanism. 3. The lunar phase display device according to the Jewish calendar according to claim 1, characterized in that the lunar phase display device according to the Jewish calendar with a period of 765433 helekim is made in the form of a gearbox with a gear ratio of 765433 driven by a second wheel of a clockwork and a gear pair with a gear ratio of 1 to 18. 4. The display of the lunar phases according to the Jewish calendar according to claim 3, characterized in that the gearbox with a gear ratio of 765433 is made in the form of a multi-stage gearbox with the possibility of obtaining a gear ratio of 765433 by factoring it in simple gear ratios, for example 131 and 5843, as well as with the possibility of integrating smaller gear ratios by means of differential adders, for example with the possibility of integrating gear ratio 131 as the sum of gear ratios 128 and 3, and integrating gear ratio 5843 as the sum gear ratios 5808 and 35, with the final possibility of obtaining a gear ratio of 765433, for example, as a combination of blocks of a multi-stage gearbox with gear ratios (128 + 3) × (5808 + 35). 5. The device for indicating the lunar phases according to the Jewish calendar according to claim 3, characterized in that the means for indicating the lunar phases on the watch dial is made in the form of a window in the dial and located under the dial of the disk with the images of the moon with the possibility of rotation of the disk with the images of the moon with a period of 765433 chelekim and an indication of the lunar phases in the dial window.