DE3918647A1 - Astronomical year timepiece showing sun and moon positions - has sun disc visible only within elliptical section of dial eccentric to central axis - Google Patents

Abstract

The timepiece displaying the daily and annual movement of the sun, moon, planets and stars has mechanical or quartz clockwork for wristwatch, pocket, table, mantlepiece, wall or standing clock. It consists of three independent basic types combinable as desired. The sun clock shows the daily course of the sun according to the time of year against the background of starts in the sky. The moon clock shows the daily and annual movement of the moon as well as its exact phase through a spherical shape. Two radical movements at right angles to each other are combined. A circulating masking ring is used in another moon clock for indication in flat form. The ring serves as a carrier for the phases of the moon presented by overlapping interval jumps. ADVANTAGE - Clear, easily understandable astronomical information displayed on ordinary type timepiece without sacrificing scientific accuracy.

Description

Astronomical year clock

The invention relates to a clock to represent the daily and annual movement of the sun, moon and stars with mechani schematic or quartz-controlled drive, applicable for bracelet, Pocket, table, wall or grandfather clocks.

Astronomical clocks serve to display the position and explanation the movement of the sun, moon, planets and fixed stars relative to Movement of the earth around the sun and the self-rotation of the earth.

Since the Middle Ages, according to the state of astronomical Sciences astronomical clocks to understand the world picture of the built. It was mostly quite complex and correspondingly voluminously constructed individual pieces, which today are considered muses exhibits are admired. Have in everyday use astronomical clocks were never found. Once was the technology was too complex and costly; on the other hand, astrono not popular. Even more recently than the technical ent display complex processes in the smallest of spaces watchmakers would have made possible up to a Middle Ages Lich naive moon phase display, which is also wrong and a laughing Sun, which rises and sets in a small window, nothing advanced. Recently, a star wristwatch is made from Japanese Production available that have been well-known and have been sponsoring for decades "Rotatable star map" reduced to small format and with one Movement drive provides - a watch for professionals who can read need a magnifying glass.

The object of the invention is not a special instrument for astronomers to create but elements of celestial mechanics in an ordinary liche use watch so that it is easy to look at understandable and appealing to the general public without being scientifically accurate dispense. It is conscious of the advertising effect of the watch on the other hand to the still widespread ignorance of the movement processes of the celestial bodies that surround us.

This object is achieved by the characterizing note paint 1-3 according to the demonstration objects "Sun on Fix star sphere "," moon 3-dimensional "and" moon 2-dimensional "with the Subclaims "Fixed star sphere alone", "Zodiac signs alone", "3-dimensional moon with sun", "3-dimensional moon stationary", "Moon 2-dimensional stationary" solved, whereby the individual main and sub-characteristics can be partially combined with each other, these combinations, however, are not deemed to be independent claims be cured.

The advantages of the invention reside in the large number and clarity the demon station of movements of celestial bodies, the as part of ordinary utility watches the different Meet the needs of users and through their novel and obvious appearance of the inclusion of cosmic processes can serve in everyday life.

The individual claims and subclaims are shown in the drawings with the same numbering as shown in the outline and described below.

• 1.1 The representation of the sun on a fixed star sphere enables
  • a) showing the daily movement of the sun, zodiac signs, constellations,
  • b) reading their exact rise, culmination and sunset times,
  • c) showing the annual migration of the sun through the zodiac,
  • d) the demonstration of increasing and decreasing day lengths as the seasons change,
  • e) the movement of the star sphere over the course of the year,
  • f) the display of twilight times, due to the diameter of the sun disk, and visibility times of constellations.
• 1.2 The systems operated here are reduction on individual features of system 1.1.
• 2.1 This system shows
  • a) the exact position of the moon relative to the location of the viewer,
  • b) the exact phase of the moon,
  • c) approximately the zones of visibility and invisibility,
  • d) the culmination time of the moon,
  • e) the change in the position and phase of the moon over the course of the year.
• 2.2 Including the sun in system 2.1 results in a powerful interplay, which is demonstrated as follows
  • a) the sun rushes ahead of the moon and catches up with it (= sequence of apparent movements),
  • b) the phase of the moon corresponds to the respective constellation from sun to moon,
  • c) when the two stars conjunct (new moon), the sun is covered by the moon (solar eclipse),
  • d) in addition to position 2.1 the position of the sun.

The incorrect representation in c) was due to the demon consciously accepted. Taking the Orbital inclination of the moon to the earth orbit and migration of the moon knots would be technically solvable, but would be the framework of the on blow up position.

• 2.3 The system 2.1 and 2.3 here is based on the pure representation of the exact phase reduced:
• 3.1 and 3.2 correspond to systems 2.1 and 2.3 with the difference that
  • a) the moon is represented in two dimensions by the mask ring technique,
  • b) the phase change is not continuous, but takes place in jumps,
  • c) the number of jump intervals depends on the chosen size of the moon and the clock.

This technique also enables use in very flat watches, which, of course, is not the case with a 3-dimensional representation of the moon is possible.

Claims (3)

1. Astronomical clock with mechanical or quartz-controlled clockwork drive for vivid representation of the relative movement of the sun, moon and fixed stars in conjunction with the usual analog time display as a wristwatch, pocket, table, wall or grandfather clock for everyday use by everyone , consisting of 3 basic types that are independent and can be combined with each other, namely

• 1 sundial, characterized in that
• 1.1 the sun is mounted in the form of a disk on a central pointer so as to be radially displaceable,
• 1.2 the sun makes 1 turn counterclockwise in 24 hours,
• 1.3 the plane of rotation lies below the cover dial,
• 1.4 the sun is only visible within an elliptical section of the dial (eccentrically to the central axis) (= horizon),
• 1.5 below this plane of rotation a further circular dial as a carrier of the celestial sphere (z. B. constellations, Milky Way, zodiac signs with 12 degrees of longitude (30 °) and the celestial equator) rotates at 1 + _^1/365 revolution in 24 hours in a counterclockwise direction,
• 1.6 on this fixed star dial the apparent annual sun orbit is shown as an ellipse in the form of a raised groove eccentrically arranged to the fulcrum,
• 1.7 the sun glides through 2 small guide rollers hidden under the disc on the groove of the apparent sun track, so that due to the different rotational speeds of the star dial and sun, this changes its radius and thus its height above the horizon over the course of the year,
• 1.8 in a mechanical clockwork, the rotation of the star dial, which deviates only minimally from the 24-hour movement, can be achieved by a modified planetary gear, apart from conventional reduction drives, as characterized in that
• 1.8.1 two loose gear wheels Z 1 and Z 2 arranged one above the other on the central axis with the number of teeth X for Z 1 , where X60 should be, and X-1 for Z 2 are driven jointly by a drive gear Z 3 in the manner, that Z 1 rotates counterclockwise in 24 hours,
• 1.8.2 Z 1 is connected by a hollow axis to a circulation web arranged via Z 1 and Z 2 , which thus moves synchronously with Z 1 ,
• 1.8.3 the revolving web carries on one side a reduction gear connected in series, the inner gear wheel of which runs on Z 2 , the outer drives a hollow ring gear which is fastened to the underside of the star dial,
• 1.9 the end of the circulating bridge, which is extended beyond the middle, is connected to a ring-shaped dial which rotates at the top of the dial near the edge of the clock and is divided on the top into 12 sectors with the names of the months to the left,
• 1.10 the monthly sector is again divided into 6 sections of 5 days each (correspondingly longer or shorter for months with 31 or 28 days),
• 1.11 a pointer attached to the 6-hour longitude is visible from the edge of the cover dial to the minute scale,
• 12.01 different rotational speed from month ring (1 U / 24 h) and star dial (1 + _^1/365 U / 24 h) this pointer as the year progressed over the months hiking leaves, which thus indicating month and approximately the date
• 1.1.3 the minute scale allows a vernier reading of the exact date (flow date), so that a constellation-appropriate setting of the clock is guaranteed.
• 1.2 Sternuhr as described under 1.1, characterized in that
• 1.2.1 the representation of the sun is omitted or
• 1.2.2 in addition, the installation of the monthly ring is omitted or
• 1.2.3 In addition, the representation of the sky is limited to the 12 zodiac signs in annual movement, which are visible through a circular segment window in the lower cover dial.

2. Moon clock, characterized in that

• 2.1.1 a sphere, representing the moon, attached to the end of a central hand, rotating to the left in the outer dial area,
• 2.1.2. the plane of rotation is below the cover dial,
• 2.1.3 the orbital speed of the moon is 57/59 U / 24 h, i.e. the moon makes 28.5 revolutions in 29.5 days (= sy nodic orbital period of the moon),
• .2.1.4 the cover dial has an annular cutout in the area of the orbit, the width of which corresponds to the diameter of the ball,
• 2.1.5 the upper half of the ring-shaped section is marked as the invisible zone of the moon, the rise and set points are labeled "East" and "West",
• 2.1.6 the moon's ball describes a self-rotation, the axis of rotation lying in the extension of the moon's pointer in the form of a hollow axis which is pushed onto the moon's pointer and carries the ball at the end,
• 2.1.7 the spherical surface is half light and half black, to achieve a continuous phase change,
• 2.1.8 the moon pointer is driven in the manner described under 1.8 with the change that
• 2.1.8.1 gear Z 1 = 59 teeth and gear Z 2 = 57 teeth,
• 2.1.8.2 the output gear of the gear chain of the circulating web drives a spur gear which is connected to the hollow axle under 2.1.6,
• 2.1.9 make conventional calendar displays such as day of the week and / or date and month relate to the annual change of position and phase of the moon in order to ensure an exact setting,
• 2.2 the sun is additionally integrated in the system described under 2.1 in such a way that
• 2.2.1 the sun rotates to the left in the form of a disk at the end of a central pointer,
• 2.2.2 the plane of rotation lies below that of the moon,
• 2.2.3 the radius of the orbit corresponds to that of the moon,
• 2.2.4 the disc has the same diameter as the moon's ball,
• 2.2.5 the sun makes one revolution in 24 hours,
• 2.3. as described in 2.1, but reduced to that
• 2.3.1 the moon is stationary only visible in the lowest point of its (imaginary) orbit,
• 2.3.2 a window at this point in the cover dial with the diameter of the moon lets the moon ball protrude by almost half,
• 2.3.3 the self-rotation of the moon on the stationary moon pointer is generated by a worm gear reduced according to the required speed of rotation.

3. Moon clock, characterized in that

• 3.1 a disc, representing the moon, attached to the end of a central pointer, rotating left-handed in the outer dial area,
• 3.2 the axis of rotation lies below the cover dial,
• 3.3 the circulation speed as determined under 2.1.3,
• 3.4 the cover dial has a ring-shaped cutout in the area of the orbit, the width of which corresponds to the diameter of the disk,
• 3.5 a mask ring is fitted in the annular cutout, characterized in that
• 3.5.1 a sequence of continuously successive phase moments is punched into a circular dark plate to the left,
• 3.5.2 the circular addition of the phases corresponds to the moon diameter,
• 3.5.3 the individual imaginary circles are almost touching each other,
• 3.5.4 the mask ring has a side reinforcement hidden under the dial for reasons of stability,
• 3.5.5 the number of phase moments that can be represented depends on the mean radius of the mask ring and the diameter of the moon (= width of the ring) and these sizes should be selected so that a number divisible by 4 arises in order to ensure continuity of the phase change to reach,
• 3.6 the background of the moon's orbit is the same dark color as the mask ring,
• 3.7 the mask ring rotates counterclockwise at the same speed as the moon,
• 3.8 the mask ring by a separate clockwork, the output speed of 29.5 divided by the number M of phase moments used per 24 hours, per 29.5 / M revolution per 24 hours by a driver jumps back by one mask, so that the mask ring has passed once in 29.5 days (= synodic orbital period of the moon),
• 3.9 the upper half of the ring-shaped section is marked as the invisible zone of the moon, the rise and set points are labeled "east" and "west",
• 3.10 Establish conventional calendar displays such as day of the week and / or date and month in relation to the annual change in position and phase of the moon in order to ensure an exact setting.
• 3.2 as described under 3, but reduced to that
• 3.2.1 the mask ring is hidden from the cover dial except for a window,
• 3.2.2 the mask ring does not move daily,
• 3.2.3 the mask ring is transported in a step-like manner as described in Section 2.3.8, similar to the conventional technique of data jump,
• 3.2.4 the window in the cover dial is circular and the size of the mask mode is arranged directly above the lowest phase,
• 3.2.5 the stationary moon is represented by a corresponding colored background in the window under the mask.