DE202021001851U1 - sundial - Google Patents

Abstract

Sundial (1) with a time display device (7) driven by an electric motor (4), characterized in that two solar cell units (5a, 5b) connected to the electric motor with reversed polarity are shaded by a covering device (6a) in such a way that the solar cell units ( 5a, 5b) have a voltage difference driving the electric motor (4) in sunlight when they do not point in the direction of the sun.

Description

I.

The present invention relates to a sundial according to the preamble of claim 1.

The sundial is a measuring instrument with which the time of day can be determined from the course of the sun. The equatorial sundial is particularly suitable for this. It has a polar axis aligned parallel to the earth's axis with an imaging device, for example a shadow rod or a pinhole. The sun apparently wanders around the imaging device as a result of the earth's rotation and projects an image of the imaging device as light or shadow onto the display device, which is parallel to the equatorial plane and perpendicular to the polar axis. The display device has a time scale with uniform angular intervals of 15 ° per hour, on which the time can be read.

Another variant of the equatorial sundial is the use of a diopter, which consists of a pinhole and an opposing projection surface with a marking. The diopter is rotated around the polar axis until the point of light generated by the pinhole falls on the marking on the projection surface. Then the diopter points to the sun. The time can be displayed on a time scale from the angle of the diopter.

Philipp Matthäus Hahn (1739-1790) implemented this principle in what he called an "eye sundial". He calls the pinhole an eye. Hahn linked the rotation of the diopter to a 12-hour clock with minute and hour hands, so that the time could be read off like on an ordinary clock.

The disadvantage is that the diopter must always be turned towards the sun before the time can be read.

In the utility model DE 295 08 935 U1 the use of solar cells for a sundial in connection with one or two electric motors is proposed. The use of the solar cells in an equatorial sundial is not described. The disadvantage is that a direct time determination from the rotational movement of the solar cells is excluded.

The present invention is therefore based on the object of providing a sundial according to the preamble of claim 1, in which the sundial ( 1 ) automatically follows the course of the sun and the time of day is derived from the rotation.

It is particularly expedient that the solar cell units also have solar cell units on the rear, so that it is ensured that one of the two sides is always illuminated by the sun.

Furthermore, according to the invention, the rotation of the solar cell units in the equatorial plane is assumed so that they always follow the rotation of the earth in regular time segments regardless of the different seasons of the sun and thus meet the requirement for a correct display of the time of day.

It is particularly advantageous that a 12-hour clock with hour and minute hands is driven by the electric motor via a suitable gearbox, so that the time can be read off like a conventional clock.

A particularly expedient embodiment provides that the longitude of the location of the sundial can be taken into account in the time display, so that any zone time can also be displayed.

The embodiment is particularly preferred that the date-dependent time equation can also be taken into account in the time measurement, so that any zone time can be displayed with even greater accuracy.

It is particularly advantageous that the solar cell units rotate about an axis parallel to the roof, called the polar axis, which can be aligned for the latitude of the location.

The embodiment is particularly preferred that the polar axis can be aligned parallel to the roof with a support device that can be displaced on the stand.

Further advantages, features and possible applications of the present invention will become clear on the basis of the following description of a preferred embodiment and the associated figure.

• 1 zeigt eine beispielhafte Ausführung der erfindungsgemäßen Sonnenuhr.
• 2a-c zeigen schematisch das Funktionsprinzip der erfindungsgemäßen Sonnenuhr.
• 3 zeigt die Grundstellung der erfindungsgemäßen Sonnenuhr zur Anzeige der wahren Ortszeit.
• 4 zeigt ein Einstellungsbeispiel der erfindungsgemäßen Sonnenuhr zur Anzeige der Zonenzeit.

Show it:

• 1 shows an exemplary embodiment of the sundial according to the invention.
• 2a-c show schematically the functional principle of the sundial according to the invention.
• 3 shows the basic position of the sundial according to the invention for displaying the true local time.
• 4th shows a setting example of the sundial according to the invention for displaying the zone time.

1 shows an exemplary embodiment of the sundial according to the invention 1 that is suitable for the northern hemisphere. The stand 2 is aligned to the north celestial pole and is parallel to the earth's axis. By moving the support device 3 can the stand 2 oriented at the latitude of the location. This is also the axis of an electric motor enclosed in a casing 4th aligned parallel to the roof and the solar cell units 5a - 5d and the covering devices 6a and 6b lie parallel to the equatorial plane. The electric motor 4th drives the time display device 7th at. The energy supply to drive the electric motor 4th takes place through the solar cell units 5a - 5d . The front solar cell assembly 5a is with the front solar cell unit 5b connected in opposite polarity. This means that the positive pole of one solar cell unit is connected to the negative pole of the other solar cell unit. The electric motor 4th is parallel to the solar cell units 5a - 5d switched. With uniform lighting of the two solar cell units 5a and 5b Their electrical voltages cancel each other out and so do the electric motor 4th stand still. In front of the solar cell units 5a and 5b is a covering device 6a tense. When the solar cell units 5a and 5b and the covering device 6a are directed exactly in the direction of the sun, throw the sun's rays on the two solar cell units 5a and 5b a shadow on each inner edge S1 . Because the shadowing on both solar cell units 5a and 5b is the same, the tensions cancel each other out. If the sun moves further to the west due to the rotation of the earth, the eastern solar cell unit becomes 5a always more covered while the western 5b receives more and more sunlight. This increases the voltage difference continuously. Reaches the voltage on the electric motor 4th a certain minimum voltage, it starts to run and moves the solar cell units 5a and 5b and the covering device 6a clockwise until the covering device 6a both solar cell units 5a and 5b again covers evenly and the electric motor 4th stop. Then show the solar cell units 5a and 5b exactly to the sun again. Now the cycle starts all over again.

2a-c show schematically the functional principle of the sundial according to the invention. In 2a illuminate the sun's rays S2 the two solar cell units 5a and 5b evenly. In 2 B the sun has moved westwards, the lighting of the solar cell unit 5a has decreased and the lighting of the solar cell unit 5b has gained weight. This puts the voltage on the electric motor 4th grown so far that it starts up and the solar cell units 5a and 5b and the covering device 6a turn in a westerly direction until they point back to the sun and the voltage on the electric motor 4th becomes zero again and remains ( 2c ). The electric motor 4th drives the clock hands on the time display device via a corresponding gear 7th at. The time is advanced according to the hour angle covered by the sun.

3 shows the basic position of the sundial according to the invention for displaying the true local time. The direction of view is perpendicular to the equatorial plane. 4th shows a setting example of the sundial according to the invention for displaying the zone time. The location chosen as an example is Frankfurt am Main. The longitude of the location is 8.7 ° East by rotating the longitude ring 8th with the help of the inner scale on the marking M. set. On the longitude ring 8th the scale of the time differences between the time zones and the coordinated universal time (UTC) can be found on the outside. Central European summer time CEST takes two hours (+ 2h) ahead of UTC. The corresponding marking on the longitude ring 8th is used to set the equation of time. The equation of time is obtained by rotating the ring of the equation of time 9 set. The value of the equation of time is taken from table T, for example +3 minutes for May 1st. This value is in 4th set.

The sundial follows in daily operation 1 the course of the sun from east to west. The sundial remains after sunset at the latest 1 stand. The next day the solar cell units are in place 5a and 5b no longer in the direction of the sun. In the winter months, when the angle between sunrise and sunset is relatively small, the sun's rays hit the solar cells sooner or later. The eastern solar cell unit 5a is illuminated more than the western solar cell unit 5b . As a result, the sundial rotates counterclockwise until the solar cells point fully towards the sun again.

In the summer months it can often happen that the sundial 1 turned so far west that the front solar cell units 5a and 5b the next morning cannot be reached by the sun's rays. In this case, the rear solar cell units take over 5c and 5d and the shield 6b the control of the sundial.

This principle is made possible by the pairs of solar cells attached on both sides and the 12-hour display, because this allows the sundial to move 1 around the polar axis twice in 24 hours P. turn.

The invention is not restricted to one of the embodiments described above, but can be modified in many ways.

All of the features and advantages arising from the claims, the description and the drawing, including structural details, spatial arrangements and method steps, can be essential to the invention both individually and in a wide variety of combinations.

List of reference symbols

1

sundial

2

Stand

3rd

Support device

4th

Electric motor

5a, 5b, 5c, 5d

Solar cell unit

6a, 6b

Covering device

7th

Time display device

8th

Longitude ring

9

Equation of time ring

P.

Polar axis

S1

the shade

S2

Sunbeams

M.

mark

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 29508935 U1 [0006]

Claims (9)

Sundial (1) with a time display device (7) driven by an electric motor (4), characterized in that two solar cell units (5a, 5b) connected to the electric motor with reversed polarity are shaded by a covering device (6a) in such a way that the solar cell units ( 5a, 5b) have a voltage difference driving the electric motor (4) in sunlight when they do not point in the direction of the sun. Sundial (1) Claim 1 , characterized in that the two solar cell units (5a, 5b) have two further solar cell units (5c, 5d) connected to the electric motor (4) with reversed polarity, which are shaded by a cover device (6b) in such a way that the solar cell units (5c, 5d) have a voltage difference driving the electric motor (4) in sunlight when they do not point in the direction of the sun. Sundial (1) Claim 1 , characterized in that the solar cell units (5a-d) move parallel to the equatorial plane and it is therefore an equatorial sundial. Sundial (1) according to one of the preceding claims, characterized in that the electric motor (4) drives clock hands by means of a gear in such a way that the time can be read from a 12-hour display with hour and minute hands. Sundial (1) according to one of the preceding claims, characterized in that the longitude of the location can be taken into account when displaying the time of day with a rotatable longitude ring (8). Sundial (1) according to one of the preceding claims, characterized in that the equation of time can be taken into account when displaying the time of day with a rotatable time equation ring (9). Sundial (1) according to one of the preceding claims, characterized in that the solar cell units (5a-d) and the covering devices (6a, 6b) move about a polar axis (P) aligned parallel to the earth axis. Sundial (1) according to one of the preceding claims, characterized in that the polar axis (P) for the latitude of the location can be aligned parallel to the roof. Sundial (1) Claim 8 , characterized in that the polar axis (P) can be aligned by shifting a support device (3) for the latitude of the location.

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