SE507057C2 - Månkompass - Google Patents

Abstract

A device for determining the course direction from a terrestrial observation point to the moon includes two plates (1, 2), of which one, the first plate (1), includes a first series of mutually separated and chronologically ordered reproductions (5) of the phases of the moon through one revolution thereof. The first plate includes a second series of mutually sequential time markings (8) covering one calendar day. The two series are of equal length and are aligned with one another. The second plate (2) includes an angular scale (10) that covers a full circle (0-360 degrees), wherewith the ends (9) of the scale (10) can be read against the ends of the series.

Description

This object is achieved according to the invention with a device according to the appended claim 1.

The device according to the invention can basically consist of a nomogram which is designed to give a connection between the current time of day and the moon's currently observed phase and the moon's momentarily observing angular distance from the north direction.

In a preferred embodiment, the device is based on a nomogram which is based on circular scales so that the nomogram itself can be used to give a direct direction indication of the geographical north direction.

It should be understood, however, that the nomogram device according to the invention can basically be given the shape of a ruler with a slide which is displaceable along it to enable reading of the desired quantity on the basis of the moon's phase and direction to the moon or knowledge of the time of day. With a circular angle scale, you can then accurately read the north direction, when you have evaluated the direction to the moon.

The invention will be described in the following in an exemplary form with reference to the accompanying drawing.

Fig. 1 schematically shows a first embodiment of a device according to the invention, based on discs which are mutually parallel and rotatable around a common center.

Fig. 2 schematically shows a device according to the invention, with linearly displaceable parts.

With reference to Fig. 1, it can be seen that the invented device consists of three superimposed parallel discs 1, 2, 3. The central disc 2 can then be circular and have a slightly smaller radius than the radius of the bottom disc 1. The top plate 3 can be formed of transparent material and has two 10 15 20 25 3 see? 057 radii 6A, 6B which represent mounted summer time and winter time respectively. The three discs 1-3 are centrally connected to each other by means of a rivet 4 or the like so that they are mutually rotatable. The bottom disc preferably has a tongue 18 for gripping or for a fastening hole or the like. Around the center of the disk 1 there is a ring of circumferentially separated markings 5 which depict the phases of the moon during a lunar revolution, the marking / image for the full moon and the marking for the new moon lying at diametrically opposite positions on the disk 1.

The disc 1 also carries time markings around its circumference, the time marking 12 being at the full moon marking of the disc 1 and the time marking 24 being at the new moon marking, and the time markings run clockwise around the circumference of the disc 1 so that a lap of time markings represents a day.

The second disc 2 has a radius 9 marked, and further the disc 2 has around its circumference an angular scale corresponding to one revolution (360 degrees) with the direction 0 degrees / 360 degrees at the radius 9.

The symbols 5 on the disk 1, which represent the phases of the moon, are depicted in correct positions around the circumference of the disk in relation to the full moon being assumed to lie at the north marking of the disk 1.

The lunar phases 5 have phases moving in the clockwise direction from the full moon first, and phases coming in the second half of the revolution.

As an example, 24 different phases / symbols 5 around the circumference of the disc 1 are illustrated.

The lunar compass can be used as follows: The disk 2 is rotated so that its north marking 9 is set to the position of the lunar phase symbol on disk 1 that most closely resembles the actual lunar phase or in an estimated position where a lunar phase symbol would most closely resemble the actual lunar phase. Thereafter, the current time is read, the angle scale 10 on the disk 2 being read at the position for the current time on the scale 8. The read angle on the scale 10 is then the direction to 10 15 20 25 35 507 057 the moon. Thus, if the reading point on the scale 10 is directed towards the moon, the north marking 9 will represent the geographical north direction.

The use of the compass assumes that the time indication is "true" time. The device may, as mentioned above, comprise a third disc 3 which is suitably transparent and provided with two different radii 6A, 6B, which have an angular distance corresponding to the time difference between any summer time and winter time. Assuming that winter time is "true" time, the corresponding radius 6B (winter time radius) is used to align the time scale, while radius 6A is used to align the entire device with the moon.

In the event that summer / winter time is not used in the region in question, the third disc obviously only needs to have a single radius marking 6. But if there is a significant difference between "true" time and official time, it may still be appropriate to provide the disc 3 with an additional radius, which can then be used in the manner just reported. Although the invention has been described above in the form of a compass which uses a time and observed lunar phase and observed direction to the moon to establish the northerly direction, it should be clear that one can use the device to find out the current time, if one know the north direction.

The device according to the invention can of course in an alternative embodiment be designed as a ruler 1 with a slide 2 linearly displaceable along the ruler 1, the ruler 1 along a longitudinal section can have a series of male symbols 5, which show the different moon phases during a moon revolution. , the beginning and end of which are represented by the beginning and end of the length section. Furthermore, the ruler 1 can have a time scale corresponding to one day, starting and ending at the beginning and end of the length section, respectively. The slide 2 can in a corresponding longitudinal section carry an angular scale corresponding to one revolution, where the beginning / end of the revolution represents a north direction. 10 15 20 25 507 857 The embodiment according to Figure 2 can be used by setting the north marking of the slide 2 to the currently observed lunar phase on ruler 1, after which the current time is read on the time scale. The angle, which can then be read on the angle scale of the slide 2 opposite the current time, represents the course direction from the observer to the moon in its observed position. Based on this information, the user can estimate the northerly direction.

The embodiment according to Fig. 2 can of course be supplemented with a transparent runner with a reading line which is perpendicular to the running direction of the slide 2. Furthermore, of course, the ruler can be provided on the back, for example with a compass rose which facilitates reading of the north direction, for example by directing the direction read on the slide 2 towards the current position of the moon, the compass rose's needle marking indicating the north direction.

Those skilled in the art will appreciate that the invented device can be modified in several ways. Instead of providing the transparent reading disc 3 with several reading lines, one can thus design the time scale slidable along the moon symbol scale so that the time scale can be set to a position where "true" midnight falls at the time that can be read in the middle of the new moon marking.

Those skilled in the art further realize that the device according to the invention gives a relatively low directional error even if the official time deviates by about 1 hour from "true" time and that the device according to the invention is therefore useful even without fine correction for difference between official time and real time.

Claims (8)

10 15 20 25 35 507 057 P a t e n t k r a v Device for determining the course direction from an observation point on the earth to the moon, characterized by two disks (1, 2) of which one, first disk (1) carries a first series of separate chronologically arranged images (5) of the phases of the moon during a lunar revolution, that the first disk carries a second series of consecutive time indications (8) during a day, the two series being arranged equally long and directed towards each other, and that the second disk (2) carries an angular scale (10) comprising one revolution (0-360 degrees), the ends (9) of the scale (10) being arranged to be readable towards the ends of the series. Device according to claim 1, characterized in that the device comprises a third disc (3) which is displaceable along the series and the scale, and that the third disc is provided with a reading mark. Device according to claim 2, characterized in that the third disc is transparent. Device according to one of Claims 1 to 3, characterized in that the discs (1, 2, 3) are parallel and mutually displaceable by rotation about a common axis (4) which is perpendicular to the plane of the discs. Device according to claim 4, characterized in that the series of the first disc (1) both extend around a revolution around the axis and that also the angular scale (10) of the second disc (2), which comprises a rotational revolution, extends around a revolution around the shaft (4). Device according to claims 4 and 5, characterized in that the third disc (3) carries two radially directed reading marks 507 (357 rings, which have an angular distance corresponding to the time difference between summer time and winter time on the second series. Device according to one of Claims 4 to 6, characterized in that the second disc (2) carries a fixed north mark at the beginning / end of the angle scale, in that the position of the second series for the time 12 corresponds to the position of the first series for an image of a full moon, in which, in the northern hemisphere, the lunar phase symbols of the first series (5) have a chronological order clockwise and the time series of the second series increase clockwise. Device according to claim 7, characterized in that the first disc carries a mark (12) along a radius extending from the axis (4) through the mark of the first series for the time and through the symbol for the full moon.