NO771685L - GLOBUS. - Google Patents

Description

This invention particularly relates to a star globe capable of displaying luminous stars and other astronomical data, as well as a combination of one such star globe with a terrestrial globe made of translucent material, and surrounded

of a transparent star globe. I-this compilation or J<<3orbiLnation is

both the star globe and the earth globe made so that they can rotate.

Globes have been known for centuries. The principle of arranging a manually operated partial screen which makes it possible to illuminate only one half of the globe while taking into account the real seasonal variations is known, e.g.

from the U.S. Patents 1,515,135 and 2,492,785 and from French patent 836,450. More specifically, the U.S. Patent 3,305,946 a globe in an arrangement simulating the sun's illumination of the earth at any time and date.'

This famous arrangement includes a globe of which the half of. the surface illuminated at any given time corresponds to the half of the earth exposed to the sun's rays, and in such a way shows the time of sunrise and sunset for all places on earth, in accordance with that date and time.

which is shown on a data cylinder, and also the place on earth that at any given time

has the sun at the zenith shown a moving point of light on the surface of the globe.

This can be achieved automatically, continuously and without manipulation by the user or the spectator.

To a certain extent, the previously discussed U.S. Patent 3. 305,946 is taken as . starting point for the improvement which this invention brings about. On the other hand, reference is also made to German patent application DOS 2,426,754 which applies to a star globe or star sphere that is illuminated from the inside.

_S7^^^G_AV_OPPFI^^^S_a11F^G_._

A star globe which, according to this invention, has devices for the luminous display of stars and other astronomical data or indications, can essentially be characterized by an in principle spherical shell, made of transparent material. a support for the spherical shell, light source arranged so that it can radiate light between the surfaces' of the shell, so that the light rays travel to essentially all parts of the shell due to total reflection, and that at least one surface of the shell is equipped with markings indicating stars and other astronomical data when struck by deyended light rays.

Such a star globe or sphere is, in addition to its inherent advantages in displaying stars and: other astronomical data, particularly suitable for combining with a terrestrial globe so that together they form a universal and complete picture or simulation of the earth , the sun and the stars with the relative movements built into the whole system..

. In the arrangement described above, the star sphere will show the exact position

of the stars relative to the Earth. Driven by an engine, the earth and the stars will make one revolution in relation to each other in 23 hours, 56 minutes and 4 seconds, while the earth will rotate a full revolution in relation to the sun in 24 hours. In this case, one would see a movement of the sun (the sun's point on the earth's surface) between the stars along the ecliptic (the zodiac), one revolution in one year. The data cylinder will at all times show the correct sidereal time for each time zone on Earth, regardless of the star sphere. mounted, or not.

The globe can be equipped with a horizon ring, either

a) marked on or attached directly to the globe in the correct position relative to a selected location on the globe or b) the globe can be equipped with a separate and adjustable horizon ring that attaches to the base of the globe...

If now the globe is set in the correct position in relation to the horizon line,

crossing the projection of the sun (or any star on the astral sphere) either ascending or descending, will show the time of rising or setting of the sun (or for'stars) on the date shown on the data cylinder, for the selected location on earth. The time of sunrise (sunset) that can be observed at this facility will correspond to the time when the dividing line between illuminated

and unlit globe passes the selected location. A degree division on the horizon line will show the sky direction for sunrise and sunset.

The half of the globe that is on the same side of the horizon ring as the selected location will accurately illusion the sky visible from the selected location with respect to the position of the sunspot on the globe. The altitude of the sun at any time on any date can be measured directly on. the globe by setting the date and time on the data cylinder to the desired time. With regard to the astral sphere, the same applies to them. marked stars. Astronomical data which

e.g. declination, right ascension, hour angle, azimuth, etc. can be easily measured and demonstrated in an easy-to-understand way with the star sphere and horizon ring. The Jorc3globus' can also be constructed ■ to show the correct duration of twilight and

damring at the different latitudes at different times of the year.

If a spectator wishes to rotate the globe to see the back of it, he can do so without displacing the relative positions of the sun, earth and stars. " The sun, sky and data cylinder will follow the earth if the globe is rotated manually, and if desired the globe can be left in this free or floating state and continue to show the correct relative position between earth, sun and stars.

By pressing a switch on the globe's support frame.or foundation,

. the spectator can choose between the following ways for the globe to operate:

!!BETOAKT_J0RDEN_FRA_A_STASOJÆR_SATELLITE" :

The globe will in this case stand still and the sun will rotate (i.e. the sunlit part of the earth will rotate.: around the earth from east to. west once in 24 hours. The same side of the globe will continuously point towards a spectator who -is at rest, but the illuminated part of the globe will rotate

'24 hours.

2) "BETRAOT_JOP£^

In this case the globe will rotate once in a little less than 24 hours (23h.56 min. and 4 sec. = 24 sidereal hours) from west to east like the earth

makes in relation to the universe, and in such a way performing 366 revolutions per year.

. The sun (the illuminated part of the globe) will in this case be almost stationary

and only rotate once around the earth in a year, corresponding to the earth's annual movement around the sun, and in the same direction as the daily rotation of the globe which will result in 365 revolutions of the globe in relation to the sun. During this revolution, the sun will change its declination on Equator from

+23.5 to - 23.5 and back to +23.5 starting at midsummer.

.3)'"§ETRACT_JOæEN_F^_SOI£N^_:_

In this case, the globe will make one revolution in 24 hours, as the earth does in relation to the sun. In this case, the solar projection will make an approximate vertical movement along a meridian on the earth with a period of 1 year. Properties and operation described above are within the tolerances that can be achieved by extremely precise fabrication, with built-in compensation for the uneven movement of the sun in relation to the earth (equalization of time). On February 29 in a leap year, the globe must be rotated one revolution backwards or stopped for 24 hours to get the correct reading on the calendar. Before this is done, the astral sphere will be approximately 0.5 degrees (about 1.5mm at the equator on a 300mm diameter globe) too far east compared to Earth. After adjusting the date, the stars will be half a degree ahead. far west. This means that the stars will appear and cross a meridian 2 min. too early or 2 min. too late. for the most part. In the middle of a leap year, the globe will show the position of the stars theoretically correctly. One can easily set the star sphere to avoid even this small theoretical error, but it is superfluous to do so as the reading on a small globe cannot be made so accurately that this error is visible. According to the above and also as will be explained in more detail below, one has here a universal geobus system that shows the earth, sun and stars synchronized in such a way that it automatically shows the exact position of the universal elements at the time shown on a clock and calendar system which is part of the globe system and which can be moved by hand or, with a motor (clock motor). Thus, the globe is automatically illuminated on 50% of its surface at any given time exactly corresponding to the date and time shown on a. calendar and clock scale attached to the globe. Compensation for the time equalization is built in, and it is achieved with the help of a ran with uneven teething. The combined geobus system can: a) depict the earth as standing still as it appears to man with the sun and stars rotating around it with daily and annual motions, or b) depict the universe as standing still with the earth rotating around the sun and also on its own axis , and c) can also be rotated by hand without disturbing the correct relationship between the sun, earth and stars.

The date and time can be set in seconds with less than a rotation of the calendar ring and of the watch ring, to depict an exact relative position of the earth, sun and stars for any selected minute of the year, as well as the rise and set of the sun or stars for a selected point of the earth at a selected time....

§ES^IVE^E_OF_DRAWINGS

Figure 1. (composed of drawings 1A and 1B) partially shows in section a complete and combined globe arrangement, consisting of a globe and star sphere with associated rotatable mechanisms, and Figure 2 shows a modified version of the star sphere. Figures 3A and 3B show details of the arrangement in Figure 1B. Reference markings used on drawings and text are letter codes according to the system below:

§5§55IY5t§§_ AY_E9B5T5yKKET_EXECUTION.

The design of the globe with the so-called data cylinder and with the star sphere in combination consists, in accordance with the invention, of main components as described below: 1) The globe is divided into two parts, preferably at the Equator, so that it gets a

upper part GU-and a lower part. GL, and the lower part is attached at its south pole to the upper end of a hollow earth axis D1, which, at the other lower end, is attached to two parts in the data cylinder D, described under point 3 II below. Between the1 lower part (south pole) of the globe GL and the data cylinder D, the earth axis (and thus the globe) is supported by a bearing GB, fixed to the foundation F of the globe, through a frame FF. The frame is extended to the North Pole with a brace FB which can help support the globe. The bracket is hinged at FBH to make insertion of the star sphere easier. The globe can be made without the hoop FB being extended to the north pole, since the globe can be sufficiently supported only by means of its south pole storage.

2) ^^ M- ELJ^ I^ ÆÆ^^^^.

a) An opaque dividing screen GS, mainly of circular shape and with clearance to the inside of the globe and also with clearance to the support arms GA andGUA

on screen ac^fec^efss - GSSU, which enables the screen to rotate freely around this axis, without touching the inside wall of the globe when it rotates. The screen GS has in its center a depression or recess GSR (e.g. of hemispherical shape) which enables the screen to rotate around the light fixture GLF and the bulb GLB,

which is placed exactly in the center of the globe, and which is attached to the top of the hollow shaft GSS, around which the screen has an annual rotation. For rotation around the shaft GSS-GSSU, the screen is equipped with bearing GSB, which is mounted with suitable clearance^GSS-GSSU. The screen GS is attached to a drive GSG, which can also rotate around the shaft GSS. This shaft is permanently mounted to an arm GA.

A converging lens GSL is attached to the screen GS by means of strut GSF. and the lens

will form a point of light, hereafter called the Zenith point GZ on the surface of the globe.

Since this lens is placed perpendicular to the perpendicular on the center of the screen GS, this zenith point will .always be in the center of the deft sunlit part of the globe. The lens arrangement will also serve the purpose of balancing the screen, which is advantageous in terms of obtaining one uniform load during rotation.

QSS.

The screen axle is permanently mounted to an upper screen axle GSSU with one or more brackets GSC between the upper part of the GSS and the lower part of the GSSU.

The brackets have clearance to the light source GLB on the inside and to the recess GSR on the screen GS on. the outside. This clearance makes it possible to change the light bulb and for the screen GS to rotate on the total axis. The top of the axle GSSU does not point. at the north pole of the globe but with a deviation of approx. 23.5°. The top of the axle. GSSU is fixedly mounted to an arm GUA which is parallel to GA, and arm GUA points towards the north pole, and will always do so when the full-axis complex GA,GSS,GSC,GSSU and GUA rotates together with shafting D3. The north pole shaft GXN, which is attached to the arm GUA will therefore rotate with the bottom GL of the data cylinder, to which the shaft D3 is attached.

B.. The screen shaft GSS is permanently attached to the arm GA at an angle of

23.5 o with the shaft D3 which is attached to the other end of this arm. The shaft. D3 can rotate inside two other hollow shafts D1 and D2, and all these three shafts together make up the ground axis. ■ These three shafts are cocentric and ex. main components of a rotatable storage rack for the globe and star sphere. A shaft is mounted in the middle of arm GA and can rotate freely in this arm. Two drives GAX1 and GAX2 are attached to this shaft, one on each side of the arm GA. Drive GAX1 engages drive GSG while drive GAX2 engages drive S2G. A relative movement between the shaft D2, which is attached to the drive D1G, and the shaft D3, which is attached to the arm GA, will, therefore, produce a rotation of the drives GAX1 and 2, therefore also of the drive GSG and thus the beam GS in relation to arm GA. The gear on either the driven GSG'or D2G has a slightly varying modulus in its circumference to produce a non-uniform annual rotation of the screen GS relative to a uniform rotation a<y>stellar sphere to 'compensate for the annual variation in the angular velocity of the Earth' in its orbit around .the sun. The drives GSG and D2G will both make a revolution of "one year". preferably by having the same number of teeth.

From the above, it will appear that the shafts GSS and GSSU with associated parts form a shaft complex inside the globe that represents

the movements of the earth in relation to the sun and the universe..

3. DATA CYLINDER D CONSISTS OF:

I. An outer shell as divided. in three parts'namely

DU, DM and DL which can rotate in relation to each other, and each of these shares

has one or more scales marked on it.

a) The upper part of the data cylinder DU shows the 24 time zones on Earth, where the name of the country in each zone or the name of the zone (e.g. Central European

or U.S. Pacific) may be marked. One or more pointers DUM can be attached to a scale DUS which is marked on the part DU and the pointer or pointers point to the scales DMUS and DLS described below.

b) The middle part DM of the data cylinder has three scales, namely:

i) A time scale DMUS divided into 24 hours and subdivided into minutes.

One (or more) pointer(s) DUM, which is attached to the DU, will against this scale show the time for places in the time zone to which the pointer(s)

is attached.

ii) A calendar scale DMLS which is divided into 365 days with months and dates,

marked on this. A marker DLM. which is marked or affixed to the honorable part DL on the data cylinder (described in point C. below), will on this

the scale shows the date which corresponds to the relative position of the universal elements of the globe complex.

iii) Ehskala DMMS showing the zodiac in the sky. This scale is fixed in relation to scale DMLS... On this scale, the marker DLM will show the position of the sun in the ecliptic, its declination and also the equalization of time at this time.

c) The lower part DL of the data cylinder has a scale DLS, divided into 24 hours. with. subdivision into minutes. This scale will show sidereal time. The sage STUPID,

attached to the upper part of the data cylinder DU, and pointing to the scale DLS, will show the correct sidereal time for the center of the time zone to which the pointer is attached. As described under point 3 r b ii) above, the lower part DL of the data cylinder has a fixed marker, which points to scale DMLS and DLS and provides data as described above.

II COMPONENTS INSIDE THE DATA CYLINDER

A. The upper part DU of the data cylinder is equipped with the drive DUG, cg will, when acted upon by another drive DMG, which is driven by a clock motor DMM,

which is attached to the middle part DM of the data cylinder, rotate relative to part DM with a revolution of 24 hours. Since the part DU is attached to the globe GL by means of the hollow shaft D1, the globe will rotate relative to the central part of the data cylinder. The scales DUS and .DMUS on the outside of the data cylinder will therefore have a relative movement that follows the relative movement of GL and DM, whereby these can show the time. A disk DUD is also attached, to the hollow shaft D1, which will thereby have a relative rotation of one revolution of 24 hours in relation to DM. The disk DUD has in its periphery helical threads DUDT which engage

with a drive DXU which in turn is attached to a shaft DX. This shaft can rotate in the bearing DXB which is attached to the bottom DMB of the middle part DM of the data cylinder.

B. This'bottom piece DMB is concentrically attached to another hollow shaft D2, which can freely rotate inside the shaft D1 and which protrudes through,

the top of this externally in the globe, where shaft D2 is attached to a drive D2G

which is described earlier. Also attached to the shaft DX described above is a worm screw DXL,- which engages a worm gear DLG, which is attached to (or is part of) the lower part DL of the cylinder.. C. ' The lower part DL of the data cylinder is concentrically attached to a third hollow shaft D3, which can freely rotate inside the second shaft D2.

The shaft D3 can also be moved axially within the shaft D2, so that the parts

DL and DM on the data cylinder are moved apart sufficiently to disengage the engagement between drives DXL and cDLG to shift the date that the globe is to illustrate. The drives D2G" and DAX2 inside the globe will continue to be coupled during such an operation (when the shaft D3 is or is displaced axially in the shaft D2). The shaft D3 runs through the entire length of the shaft D2 and is attached to the arm GA inside the globe which described previously. When; the lower DL of the data cylinder rotates, the arm GA will make the same movementTV

D. Electric current is led into the data cylinder from the globe foundation FF or a commutator DLC. Electric current for the globe light in GLB is led from this commutator through the shaft D3 inside the globe and along the arm GA and up through the hollow shaft GSS to the light fixture GLF. Power for the light source SSL for lighting the star sphere is led along the same path, but is carried on via

• the hoop GSC and through the shaft GSSU and the arm GUA to the norpol's shaft GXN. Power to the clock motor DMM is supplied from the commutator GLC via another commutator DMC between the parts DL and DMB, which has a relative movement of one revolution per year. and further through the bottom piece DMB to the clock motor. These three circuits

can have individual switches FS1, FS2 and FS3 on the globe foundation F.

E. On the globe frame FF there is a locking device consisting of the movable elements FLU and FLL. By moving the switch FLS, the upper part DU or the lower part DL of the data cylinder will be locked to the frame with the element FLU and FLL respectively. • The entire data cylinder can rotate freely if the switch FLS is set

in neutral position The middle part DM of the data cylinder can also be locked to the foundation in the same way.

F. The clock mechanism DMM can be released from its attachment in part DM through an opening in the side wall of DM which can be closed with a lid DOL. The lid has a hole DOH for adjusting the clock's speed from the outside. The drive shaft of the clock motor is connected to the shaft for the driven DMG, e.g. using a friction clutch. A device to solve this link from the outside for quick changing of the time that is. shown on scale DMUS, can be made. For adjusting the time, the drive DMG may have a flange that protrudes through the opening between the parts DU and DM. This flange may have a scale showing minutes. '

The globe can be equipped with another, fast-running motor as in a simple way

can replace the ordinary clock engine so that within a short time it can demonstrate the annual cycle in the universe. for educational or exhibition purposes.

4. THE STAR SPHERE p.

The globe G is surrounded by a star sphere S which can be removed and is made of relatively thin transparent material. I. the purpose of being removable or to at least make it possible to remove the upper part GU

on the globe for maintenance, e.g. to change the light bulb, the star sphere is divided into two halves; Division of the star sphere is done vertically, through its north-

■and South Pole. ^Semicircular openings on the halves of the astral sphere at the poles

has flanges SFN and SFS that fit into the flanges SFU and SFL that are attached

the soil plowing. The lower flange SFS on the star sphere fits into the flange.

SFL which can freely rotate around the south polar axis of the globe.

The release flange SFU is locked to the ground shaft GXN and will rotate together with the globe shaft GSS, the arm GA and the part DL of the data cylinder. This flange should be attached to the flange SFN on the star sphere in such a way that the connection between the two is triggered if the moment between it were to exceed a desired limit, - this to avoid breaking or bending elements in the globe complex. The top of the star sphere is, in the area of the hall SNH covered by a circular lid SNL guided by the globe hoop FB at the bearing FBB. " The lid will primarily serve the purpose of covering the light source SSB, described below.

A light fixture with the light source SSB is attached to the north pole Q£N,

This light source lies in the same plane as the hole SNH in the star sphere's north pole.

When the light source is lit, its light will travel almost invisibly between the inner and outer surfaces of the astral sphere (due to total reflection) from the north pole, and, due to the vertical division of the astral sphere, all the way to the south pole. However, where the trasjnparent star sphere has markings SM of stars, 'lines or , names, these will be illuminated by the otherwise invisible shelter. This will enable the display of illuminated stars together with a globe with a dark side and a light side.' When the light bulb SSB concerning the star sphere is turned off, stars, names etc. marked on the sphere will be almost invisible and will not interfere with the reading of names, etc. on the globe through the transparent star sphere.

Figure 1 shows markings SM on the inner surface of the star sphere, but it

is also possible as shown in figure 2 to have such markings SMM on the outer surface of the star sphere'. This is of special interest when the astral sphere is not combined with the terrestrial globe. In this case, it may be appropriate to apply an opaque cover SMC on the inner surface,

as shown in Figure 2.

Illumination of the star sphere can be done with ordinary light, fluorescent or black light or in another way and the markings on the star sphere can be made with the stars and letters engraved or embossed in the material of the star sphere, e.g. a synthetic plastic material, from which the star sphere is made. This gives a very good lighting effect. The markings can also be printed on the sphere in white or it can be printed with a fluorescent substance.

The star globe or sphere described with the particular form of illumination obviously implies an interesting and advantageous solution in itself and can be made with or without means for rotation as a separate object not connected to the globe.

5-. A circular horizontal ring FH which can be moved on the foundation bracket FB and fixed to the bracket with a screw FHS can be mounted on the globe. The horizon ring can be set with different declinations to the earth's axis.

Hsle globe arrangement including the data cylinder can be adjusted so that the earth axis can be given any inclination with the foundation from vertical to horizontal and locked with screws FIS

OPERATION OF THE GIX>BUS ARRANGEMENT:

A. Using switch FS1, the light in the globe can be switched on. The half of the globe, which is on the same side of the light screen GS and the light screen GLS, will then be illuminated. Which part of the world will be illuminated will depend on the relative position of the three rotating parts DU, DM and DL on the data cylinder, ie the date and time, which are shown by the markers DUM and DLM.

B. The time can be adjusted by rotating the part DU relative to -.' DM by hand. The flange DMGF and the drive DUG which barely protrudes through the opening between the parts DU and DM can be rotated to adjust the time.

The time hand(s) DUM, which can be moved, are preferably fixed in the fixing area for

the time zone in which the owner is located, or the pointer can be placed in the attachment device^other time zones for which the owner wants a time indication. The time in all world time zones can be easily read even without the hands.. C. The date can be adjusted by lowering the base piece DL on the data cylinder by releasing the screw DLA enough to disengage the worm drive DLG from the worm screw DXL whereby the parts DL or DM can be rotated until the marker DLM points to the desired date on the scale DMLS. The relative position of the earth, sun and stars will, during rotation of the parts DL or DM, be continuously correct.

After changing the dates), the part DL is raised to its original position with the screw DLA. The auger-driven DLG' can only be engaged in the auger DXL at 5-day intervals (since each tooth on the driven DLG represents 5 days).. Engagement is therefore done on the date closest to the desired date. It will never be more than two days earlier or later than the desired date. In such cases, the clock ring must therefore be rotated by hand one or two revolutions to obtain the desired reading on the date scale DML. Instead of using a set screw DLA, the bottom part DL can be spring-loaded for frequent and quick changes of the date. D. Turning on an electric switch FS2, the clock motor DMM will start to run, and through the transmission DMG-rDUG cause a relative movement between all parts attached to DM and parts attached to DU. The relative movement is one revolution per 24 hours. Since the disc DUD.makes a revolution of'24 hours relative to the disc DMB, and the disc DUD has spiral threads on its circumference, which in turn meshes with the drive DXU with a turnover ratio of 1:5, the shaft DX will make a fifth rotation of 24 hours.

The worm screw DLX, which is attached to the shaft DX, will thereby make one revolution in 5 days. Since the DXL engages the worm-driven DLG, which has 73 teeth, the DL

make a revolution of 5 x 73 .= 365 days in relation to DM. This rotation has the opposite direction,; of the daily rotation of DU in relation to DM. Share/) YOU

will therefore make 366 revolutions in relation to DL during one year.

The time hand DUM which is attached to DU will therefore show sidereal time on the DLS scale at the same time as it shows solar time on the DMU scale, since 365 x 24 solar hours make up

- 366 x 24 sidereal hours.....

E. To explain in detail how a combined sun and star globe device. according to the invention works, the starting point is that the lower part DL of the data cylinder is locked to the frame FF with the locking device FLL. In the course of one year, the middle cylinder part DM' of the data cylinder will make one revolution' to the east, while the upper cylinder part DU, including the globe, will do.

366 revolutions to the east (but again YOU will only do 365 revolutions in relation to DM). Since DL is now locked, the arm GA which is attached to DL through the shafts D3 will not move.

However, the drive D2G which is attached to the shaft D2, which. is again attached to the part DM, make one revolution in one year relative to the arm GA and with a 1:1 revolution ratio between the drive D2G and the drive GSG, the drive D2G will cause the screen GS to make a full turn eastward. of one year, at the same time as the globe G will make 366 revolutions in the same direction. The sun's zenith point, which is tied together with the screen GS, will therefore be passed e.g. of the Greenwich meridian on the surface of the globe only 365 during one year and you get 365 "solar days".

During this period, the zenith point will gradually change its declination on the globe's equator between + 23.5° and minus 23.5o, due to the 23.5o inclination of the globe axis relative to the screen axis, around which the zenith point rotates .

F. If the right part DU of the data cylinder is instead locked to the frame with FLU, the globe cannot rotate. In this case, the arm GA will make 366 revolutions per years to the west and the screen GS will make a revolution around this shaft on the arm GA in the opposite direction. The zenith point on the illuminated globe will then make 365 revolutions from east to west around

.! • - ■ '■ '

the earth that stands still.

G. When the part DL is locked to the frame, the star sphere S will stand still^and the globe G will rotate eastward under the star sphere, 366 times in a year (a revolution of 23 h. 56'min. and 4 sec.) . The projection of the sun on the globe

•will correspond with its proper position in the zodiac on the star globe.

But if the element FLU of the locking mechanism is connected to the upper part DU of the data cylinder, the globe will not move. The lower part DL of the data cylinder and the arm GA, and therefore also the star sphere, will now rotate to the west at 366 revolutions per year. Since the screen GS will make one revolution relative to GA in the opposite direction during one year, the sun's projection (the zenith point)

make only 365 revolutions around the Earth and a retrograde motion in relation to the ecliptic on the astral sphere. Also when the globe arrangement runs in eri'neutral position (see description 3..II.E.), the relative movements of earth,, sun. and stars be correct.

Claims (14)

1. Star globe - which has a device for luminous display of stars and other astronomical data and indications, characterized by an essentially spherical bowl made of light-transparent sheet material, a lighting device arranged so that it sends light into the interior of the sheet material, - so that, due to total reflection, it travels to basically everyone. parts of the shell, and that at least one surface of the sheet material forming said shell, one equipped with markings indicating stars and other astronomical data when these are illuminated by said radiated light. 2.. Star globe according to claim 1, characterized in that it is divided along a universal meridian plane through said light source. 3. Star globe in accordance with claims 1 and 2, characterized in that said markings are made on the inner or outer surface of the shell. 4.. Star globe in accordance with claim 1 or 2, characterized in that said markings are made on the outer surface of the shell and that the inner surface is equipped with an opaque coating.. 5. Star globe in accordance with claim 1 3, in combination with a globe made of translucent plate material and surrounded by a star globe, in that both the star globe and the globe are rotatable, characterized in that the axis of rotation of the star globe coincides with the axis of rotation of 'jo| the globe and that the axle device on the inside of the globe - which causes the sun's movement - is extended to the north pole region of the globe and bears the shield for the star globe at the same time that <-d.> makes up for the star globe's rotation and has a connection for operation of the star globe. . 6. Globe combination in accordance with claim 5, characterized in that said axle system comprises hollow parts (GSS, GSC, GSSU, GUA) through which electrical conductors for said device for 'illuminating the star sphere SSB can be passed, and around which a screen which illusions the sun can rotate.■• 7. Globe combination according to claim 5, in which said support] comprises 1.,2. and 3. concentric shafts (D1, D2, D3) which can rotate in relation to each other and produce movement of the globe, illumination device for the movement of the sun and the star sphere respectively, the first concentric shaft (Dl) which surrounds said 2nd and 3rd shafts in such a way that the 1st shaft (pl) can freely rotate in a bearing (GB) and so that the non-rotating foundation (F^) of the globe assembly carries said storage. 8. Globe combination according to claim 7, on which a first flange (DUJ for showing time is mounted on said first shaft (D1), dg another flange (DM^ for showing time and date is mounted on the second concentric shaft ( D2) and a third flange (DL) for displaying the time and date are mounted on the third concentric shaft (D3), while the 1st, 2nd and 3rd flanges for displaying the time and/or date are arranged so that they work together and that the rotation device for these three flanges has a dependency relationship, and characterized by locking devices (FLL, FLU) to lock at least one of said time indicating flanges to prevent rotation in relation to said non-rotating foundation (F.FF^ 9. Globe combination according to claim 8 characterized in that said 3rd flange (DL) for displaying the time and date can be moved axially from said second flange (DM) in order to thereby be able to trigger the joint rotation coupling (DUD, DXU, DXL, DLG ) between the third flange and the other two flanges to thereby make it possible to change the angle between these, (the date). 10. Globe device according to claim 9, characterized in that said rotational connection between the third flange (DL) and the other flanges comprises a wheel (DUD <j> which has spiral threads (dudt) which through the flange (DU$) is attached to the first concentric shaft (Dl), a drive (DXU) with engagement in said spiral threads (DUDT^and mounted on a shaft supported on the other flange (DM^through the bearing (DMB_) in the said shaft at the other end is equipped with a worm screw (DXL) which engages a worm gear (DLG) attached to it third flange (be 11. Globe combination according to claim no. 5, comprising a drive device within the globe to produce a rotating movement on the devices that illustrate the movement of the sun, characterized in that at least one drive (D2G) or (GSG) said collection of drives has an uneven toothing or varying modulus. 12. Globe combination in accordance with claim 11 characterized in that said device; for illustration of the sun's/ movement includes a lens (GZL~) / arranged in such a way that it creates a point of light on the inner surface of the globe and made so that it balances the rest of the arrangement that illustrates the sbl movement in relation to the axis of rotation (GSS,GSSU) 13. Globe combination according to claim 5 characterized by eh horizon ring (fhJcarried by a semi-circular hoop (fhm) as - this can be displaced around the globe sliding on another hoop (fb) which runs concentrically around the globes' from said non-rotating foundation. 14. Globe combination according to claim 13 characterized in that said non-rotating foundation and frame as a whole can be inclined around a horizontal axis (FTS) in relation to a main foundationfFS^.-'