DE1950418U - GLOBE. - Google Patents

Description

RA.298 935 * -8.6.66

Pataitfonwllfe Dr .. | n0. by Kreisler Dr.4ng. SchfinwaW

Or.-Infl. Th. Meyer Dr. Fuei

Cologne, D.lchmamih.u »

1966

Sch / lla.

Hans-Uolfgang Arnold; 152 Pretoria Road, Rynfield, Benoni. Transvaal (South Africa)

globe

jb.s are very different. Replicas of the earth, hereinafter referred to as globe · _{5 known} in the form of wood, cardboard, pressed material, metal or 'glass balls The oldest such globe comes from Martin Behaim from 1492 _o While the oldest globes only around a fixed axis rotatable were "known more recently globes arranged freely on one foot with gauge which _{area-length-9} and conformal mißto, which consist of a glass globe globes are 221 usually inside illuminated to Here globes have become known, which in the unlit state reflect the political division of the earth's surface ^ in the illuminated state the geographical conditions ο Globes that reflect the geographical "conditions" are also known as so-called relief globes, in which the elevations and depressions of the earth's surface are vividly represented =,

So far, globes are not known for which the actual Lighting conditions; like them through the

Orbit of the earth around the sun arise. ,, are reproduced in which therefore one half of the. Earth "is irradiated _5, the other is in the sun shade ₀ The invention has for its object to remedy this Hangel, d _o h" from the sun to create a _globe? In which illuminates not just the entire globe or not illuminated j but at the according to the actual conditions on the ground illuminates the one hemisphere and the other is not illuminated ₀ in a globe having disposed in its interior Belsuchtungsoinr ±:;:?.!. · "■) ■ ^ the stated object is achieved in" that the lighting device and / or the globe can be driven in such a way that the movement of the earth around the sun is simulated and that the lighting device

• jK is designed such, "that is each die.augenblicklich illuminated by the sun-drenched hemisphere on the globe," One of the invention trained globe offers the greatest possible clarity for playback of the actual conditions on the ground ₀ It is therefore particularly for educational purposes excellently suitable

The clarity of the reproduction of the actually prevailing conditions on the earth to increase even further., 'In another embodiment of the invention, the globe ₅ is characterized in that the Dunk the earth. _? over which the sun is currently perpendicular, appears as a point of light and that a penumbra area is provided at the transition from the illuminated half of the globe to the illuminated half of the globe _. which corresponds to the length of twilight at the associated locations on the surface ο Due to this configuration of the globe according to the invention, the location of the sun is special

on the other hand are the twilight zones, indicated, lighting of the half of the globe, indication of the respective location? at which the sun is perpendicular ₅ and the twilight sz one η can change _s as it corresponds to the actual conditions ₅ namely within twenty-four hours _s which corresponds to the change of the illuminated and non-illuminated half of the globe ₅ . and within 365 days of the inclination of the earth's axis relative to the solar radiation, ie the change of places from 23 IT to 23 ° S ₅ at which the sun is at its zenith over the course of a year. It is, however, for demonstration purposes _s globe and lighting device is increased in particular for education, possible to cut ₉ this time ■ considerably, characterized in that the relative movement ζλνίsehen so that in the course, for example, can be demonstrated a _lesson} the relative motion between the sun and earth in the course of a whole year »

Further features of expedient configurations of the invention emerge from claims 4 to 20 °. The advantages of these configurations are shown in the following description of exemplary embodiments _{3 shown} in the drawings.

Pig 1 is a view of a globe according to the invention;

Pig, 2 those provided inside the hollow sphere of the globe Parts; ■

Pig. 5 and 3a with the Puss belonging to Pig, 1 and 2 Transmission in section;

FIG. 4 shows the geared structure according to FIG. 3 in a top view;

5 shows a second exemplary embodiment for the gloftus according to the invention in a position corresponding to FIG. 2;

FIG. 6 shows the connection to the globe according to FIG. 5 .. belonging foot; ... Figo 7 ■ -: 9 individual parts of the Gloftus according to the invention »

In the example illustrated in Figures 1 und.2 Gloftus goes from one foot 1 centrally by-often a Hohlstaft 2, on the outside, a semicircular bracket 3 is secured ₀ The Hohlstaft 2 has externally circular cross-section, so that a hollow shaft. 4 can be rotated on it and can be grounded ₀ - The Ηοΐιΐλ / elle 4 is connected to the actual Gloftus. more precisely with a hollow ball 5, which is thus rotatable around the hollow rod 2 by means of the hollow shaft 4 ₀ A shaft 6 runs centrically in the hollow rod 2, which is divided into a lower shaft 6a and an upper shaft often ₅ the after a 'connecting piece 7 are rotatably connected to one another and electrically separated. the lower part 6a is stranded with a hat in which a control rod 13 can slide ₀ On the lower part 6a of the wool 6 is ... a.; lighting device 95 consisting of a point light source 8 ₅ a cover _{screen 9a 5} a darkening ring 9ft ₃ a ground mirror ring 9c and zv / ei: bracket 9d by means of a pivot bearing .befestigt _s so that the entire lighting device 8 ₃ 9 follows every rotation of the lower shaft 6a. The bearing 10 is located in the center of the hollow ball 5c. The shaft parts - 6a and 6b are used

_ C

In addition to the storage of the hollow ball 5 and the rotation of the lighting device 8 ₅ 9, it is also used to transmit power for the light source 8 via the bracket 9d and contacts on the shaft parts 6a and 6b "

The lighting device 8 _P 9 is designed so that the direct rays emanating from the point-like light source 8 impinge on an area of the hollow sphere 5 which corresponds to exactly one half of the hollow sphere 5 o The hand rays of the illuminated area are labeled B in the drawing The darkening ring 9b arranged in a ring around the cover screen 9a is only partially translucent, so that only part of the rays impinging in this area pass through this darkening ring and define an annular area C. "on the hollow sphere 5, which thus designated a twilight zone"

The mirror ring 9c is ground so that it is the incident Deflects rays so that

firstly in the extension of the axis of the lighting device 8, 9 a bright point of light "appears and denotes a location A on the surface of the globe; this

He (? - ■ ■
Place A is the place on the surface where the sun is at its zenith;

a circle of light the locations of the globe surface

,1

'2

denotes where the sun is 2? ~ degrees

above the horizon has -

and thirdly, another circle of light, the locations on the surface of the globe j denotes where the sun is one

_ 6 - ■■ '■■'

66 ρ degrees above your horizon. These circles of light should "when used in the classroom, the explanation of night sun, pole lighting," climatic zones etc facilitate ο

The effect of the lighting device is thus ₅ . that one half of the hollow sphere 5 is illuminated by the point light source 8 " _? This area is the one ₅ on the day that is" on the not "illuminated half of the cabbage sphere is just Kaeht", the one from the light source 8 on the mirror ring The rays that strike it are partially bundled at point Λ and produce a bright spot of light there, which indicates the place on earth where the sun is just at its zenith

-] _ ς mirror ring to meet = deflected so that they yovo at an angular distance of 2Z ~ and SS- degrees . The zenith of the sun forms circles of light. The rays impinging in the area of the darkening ring 9b are only partially let through and designate a twilight zone ₉ which extends on the edge of the illuminated area at a width of approximately 75 degrees and thus each denotes a twilight length of τ, hour in the lease of the sun's path

Lighting device 9 and hollow sphere 5 are relative rotatable to each other with the shaft 6 as the axis of rotation «In addition is the lighting device with the help of the control rod 13 and a Z \; ischenstange 13a around the pivot point 10 starting from a putty layer by 23 · ^ degrees the two poles of. Cabbage ball 5 can be swiveled, Lurch this movement becomes the relative change in the inclination of the earth's axis; relative to that in the center of the earth's orbit standing sun, over the course of a year

simulated "The illumination means passes through over the year Winker area twice _s näralich once in one direction and then the intermediate rod in the opposite direction ,, To a winkeltroue possible guide of the illumination device reach su is guided by a spacer 13h 13a ₅ that the intermediate rod 13a forcing to a vertical movement, wherein a bearing 11 connecting the intermediate rods 13a and the lighting device 9 is designed as an elongated hole on the lighting device side _s into which a pin of the intermediate rod 13a engages ο

As will be explained in more detail later =, the relative movement of the hollow ball 5 and the lighting device S ₅ 9 is controlled by a gear inside the globe base 13 · which runs in the groove of the lower shaft 6a and the intermediate rod 13a connected to it and the spacer 13b make the same rotation. In this case, the lighting device makes. tung 9 per day, a full rotation about the shaft 6 as a rotation axis and performs the same time in the course of a year the pivotal movement of the IJittellage to an L _o ge described by 23-q degrees in the direction of a pole on the Kittel location to a location of 23- ^ Degree in the direction of the other pole back to the cement layer.

In the other case, the lower shaft 6a with the lighting device 8 _S 9 does not rotate _? but the hollow ball 5 "makes one rotation in the course.

~ 8

one day, while the lighting device only performs the pivoting movement described above in the course of one hour ο In the sera trap, the lower shaft 6a is held in place in the gearbox, while: a hollow shaft 12 via an intermediate piece 3a ₅ that is firmly connected to the hollow shaft 12 and on the other hand "in. Grooves of the hollow shaft 4 engages »the hollow shaft 4 and so drives the hollow ball 5. in the opposite direction«

It is still possible to drive the "globe like this", that a rotation of the hollow sphere or lighting device does not take place within a day, but in a much shorter time the latter is planned to to be able to demonstrate the course of a year within one lesson »- ■

The control of the movements described above *

EoBo is possible with the aid of the - ■ = - .. gear shown in Figo 3 and 4. In the gear shown, the hollow shaft 12 or ~ ^; in the opposite direction - the lower shaft 6a are driven,

The gearbox is driven by a clock shaft. .14 through

a clock or a Kotorelle 15 through a Kotor _o -. Clock and Ko tor are together with a transformer for transforming the mains voltage to the supply voltage;. for clock, Kotor5 lighting device and control. The clock and motor, housed in a housing 16, are optionally provided to drive the gearbox. As a rule, the clock will drive the gearbox, with this drive the actual conditions - sun-earth simulated. The motor has a higher value Drive speed,

it is therefore used to drive the gear ₉ if, for reasons of demonstration, the globe and mirror device are to be rotated and swiveled faster than the actual relationship between earth and sun corresponds to. which has a toothing on its outer rim, in which the toothing attached to the clock shaft and ICotor shaft engages, ITit the time disk 17 ₅ which rotates once in the course of twice 24 hours when driven by the clock shaft; in gear ratio 1; 2 connected in one direction of rotation is a drive wheel 18 for driving the lighting device _β. Also connected to the zoom disk 17 - but via a further bevel gear set anchored in the housing is a drive wheel 19? which is used to drive the globe in the opposite direction of rotation; the transmission ratio between time slice 17 and drive wheel 19 is also 1: 2 _C. The globe drive wheel 19 is firmly connected to the hollow shaft 12 ₅ the drive wheel 18 for driving the lighting device 8 ₅ 9 is with '

_ .._ dgr lower shaft 6a firmly connected »Commissioning

either the drive for the ball 5 or the drive for the lighting device 8 ₅ 9 takes place via brakes j, of which one brake shoe 20 blocks the drive wheel 18 for the lighting 8, 9 if the lighting device is not to be driven; of which a brake shoe 21, the Globusantriebsrad 19 blocked _s if the hollow ball 5 should not be driven.

To control the day and hour display, each Half-rotation of the time slice 17 through one of two on the underside of the one connected to the time slice 17

Bevel gear carrier 17a provided. Squat ITd a lever 22a deflected by a certain angle from the horizontal position; This lever 22a Toev / egt the wheel 22 by a certain angle (here 7 ₅ 5 °) via a sawtooth-shaped ring gear attached to the top of a gear wheel 22. . 22b transferred to a year wheel 23, wherein the translation than.The from the lever 22a wheels 22 - 22b - 23 is selected so _"; that the gear 23 one full turn per year? or, more precisely, in the course of 366 days, “Near the outer rim of the annual wheel 23 are. on the top. this wheel incorporated twelve recesses 23a, in which the arm can be a of a later explained control body 24 engage "The distances of said circularly arranged recesses 2JA sindso selected to be the full Winkelsurame of R _a of 23 von.360 degrees relative 31: 29 : 31 ..: 30: 31: 30: 31: 31: 30: 31: 30; 31 divide «, ■ display the different lengths of the individual months ₅ whereby February is calculated with 29 days for the sake of simplicity _o In total, this results in 366 days ₀

The STC uerkörper 24, - s, Figo. 7 - is designed so that the arm a _s can slide along the surface of the annual wheel 23 whereby it. can snap into the twelve recesses 23a in the surface of this Hades, the arm b with each further rotation of a day wheel 31 by a day number into a sawtooth-shaped one. The ring gear engages on the top of this wheel and prevents this wheel from turning back; the arm c slides along the underside of the day wheel-31; and the arm d about.

on the underside of the time disc 17 represents =. The control body 24 is further supported so as to be rotatable about a small angle in the vertical direction about a horizontal axis and by a small amount Winker in the horizontal direction about a vertical axis ο

The day wheel 3I _5, which shows the day numbers from 1-31 on the outer rim and has an empty field in front of the first number, so that the wheel is divided into thirty-two roughly equal parts, has a sawtooth-shaped toothed rim on the top with two / thirty-one teeth, in 31c engage an attached to a lever 31a spring ;, may around the day wheel to a respective day _T loetrag v / pus turn ₀ the booklets 1 31a has dieselfte axis as the day wheel 31 and lies in the direction of the axis of the Zeitscheifte 17 on the underside of Time disc 17 * Kit _{firmly connect the T a} gesrad and rotatable about the same axis is a wheel 31b provided with an EOcken, the

~ to move a push rod 26- This push rod 26 lies on the upper side of the wheel 31b, which is firmly connected to the day wheel 31 and provided with a cam, has a recess on the side facing the axis of the day wheel 31 into which the mentioned cam of the can engage Radteiles 31b "the push rod 26 may be a movement in the direction of a run next to the T _a gesrad arranged Konatsrad 30, wherein it is held in the two end positions by a spring 26a ₀ month wheel 3O ₅ carrying at the bottom a ring gear, which consists of twelve sawtooth-shaped teeth, is also part of the date display ο On the outer rim, the Konatsrad 30, assigned to the twelve teeth, bears the Konatsnames-

The mode of operation of the date display is now as follows;

Regardless of the movement of the annual wheel 23 ₉ but synchronized with it, with a small time interval, a cam 17b - again one of the two opposing clocks ₅ on the underside of the time disc around the single rotation, this cade in the course of twice 24 hours to consider - the planer 31a deflected from the normal position by a small angle, the spring 31c engages in the ring gear on the top of the ^ age wheel 31 and ^ turns this day wheel by about 1/32 of a full turn _o The arm b _: the control body 24 hält.das day wheel 31 are respectively fixed in the new position, the day wheel 31 is not free to rotate about its axis, but only rotatably supported to almost 360 degrees and is cushioned that of 0 Grad.bis about 352 degree rotating a internal peder tenses and when released by arm b of the control body. 24 runs back to the starting position or ₀ -turns /

Depending on the length of the month, on 29 °? 3O "or 31 ° days. one month one of the "depressions 23a in the surface of the annual wheel 23 come to stand" so that the arm a of the control body 24 can snap into this recess = The upward pressure of a spring 25 on the arm d of the control body 24 v / ird now the arm a snap into the recess 23a and thereby the entire

² ^ Turn the control body by a small angle in.vertical-direction α Through this movement, the arm d of the "control body 24 is raised and thereby comes into a position _? Which allows the ÜTocken'iYc, which - again in pairs on the underside of the Time slice is attached, j enables the arm d of the control body at the next approximation and thereby the entire control body through a small angle in the horizontal: direction around its axis

to rotate ο P ^ reh this rotation of the control body 24 λ '/ ird the "previously held by the arm I) T _a gesrad 31 released and rotates, since the spring has now been tensioned in the course of the" already completed month ^: in his Starting position back, with the push rod 26 being taken from position 26 / l to position 26/2 ο During this shift of the push rod, the other end of the push rod engages in a ring gear 30a of Konatsrad.es 30, rotates this month wheel by l / l2 one full rotation, thus showing on the month wheel a new month, and stops temporarily in this position, wherein the leather 26a of the push rod 26 in this position _o thus holds is the month display now in the new month, while the T _a gcsanzeige has run back to the starting position and in the display window the already mentioned blank field at the beginning of the day numbers shows <> After the monthly position just described, one of the KOs should cken l? b again reach the position which is provided for advancing the day wheel 31 ₀ How

Usually the time slice 31 now switches over the lever 3Ia _5, influenced by the lock 17b, to the next day also ^1;. where the display dated. Empty field is indexed to the day of the new month _o By for days ■> as indexing the day wheel of the month is now looking forward to spring located inside the day wheel 31 again in the course, the push rod 26 from the position 26/2 to the position 26 / l pushed back and thereby the entire facility prepared for switching to the next month =

To enable the facility to work smoothly, the arm b of the control body 24 must be slightly "

- 1A - ■ '

be cushioned in order to "easily jump out of the gear rim of the bearing wheel 31 during the rotational movement of the control body 24 caused by a crouching 17c and not be able to engage in another. tooth of the same. gear rim; the" spring 25 ■> die on the Arn d of the control body 24 exerts a pressure towards the top, must be designed so that the Arn d of the control body after the deflection by the cam 17c in the. deflected position engages and only then released again when the cam 17c has overrun the arm α-Furthermore, _{a control cam 31d is attached to the underside of the T a} gesrades 31, which the arm c of the control body in the first 28 days of the month pushes down und.somit prevented ^_5: d in that the arm; "- this time is in the region of the cam 17c, also is in the running back of the l'agesrades 31 at _Konats-. end of the control body 24 immediately returns to its normal position brought and thus; lifted out of the depressions 23a ″; it is also prevented that the. Arm a continuously grinds on the top of the year wheel 23 »

A sun elevation wheel 29 is still driven by the annual wheel 23 in a rotation ratio of 1: 1 via a toothed ring on the underside, on whose outer ring the respective angle "deflection of the lighting device" and ^{2 ;?} so that the respective position of the sun can be read """

Furthermore, the year c-srad 23. the bottom one Toothed ring 32 which meshes with a toothed wheel 28 “The toothed wheel 28 drives a crank 33 which, via a slider 27 with your lower part of the control rod 13 in connection The slider 27 transmits the crankshaft movement the crank. 33 in an axial movement of the control

rod 13 »ring gear 32 and gear 28 are designed ao» that "with one revolution of the Jaliresrades 23 one revolution of the cure" takes place at 33 «.

The diameter of the crank circle is designed so ₅ that the propriety front top to the bottom dead center, as axial movement on the control rod 13 _5, the intermediate rod 13a and the bearing 11 transmit 'a swivel movement of the illumination device 8 ₃ 9 of each 23-p degrees up and below causes _s calculated from an IQ starting position perpendicular to the globe axis ₀

The slider 27 runs in parallel on both sides! Guides ₉ in the upper part, the control rod 13 is rotatably mounted and has an elongated hole in the cement, the width of which corresponds to the crank circle and the height of which corresponds to the diameter of the smock part of the crank 33 "

The brakes 20 and 21 are so constructed that opened by the switch 36 on the front side of the housing 1 respectively a "of the brakes and the other is closed ₅ wherein the respective braking respectively, blocking brake is pressed by spring pressure _o? While the other is held apart by a linkage (not shown in the drawing) ο The closing springs are designed so that in the event of a violent rotation of the globe 5, the respectively closed brake allows the braked drive wheel to spin and thus the rotary movement of the globe over the Hollow shaft 12 ₉ transmits the drive wheel 18j the transmission, the drive wheel 19 transmits to the lower shaft 6a and thereby damage the transmission and an adjustment of the relative position

prevents ο In such a case the . Lighting device 9 with the same rotary movement,

In the front panel at the front; of the housing the following display and operating elements are visible:

The time disc 17 has on its outer rim the number of hours c-n from 1 -24 twice, according to the holding speed of this wheel in relation to the lighting device 8 ₉ 9 or to the hollow ball 5 _3, moreover, the time circumstances of 5 to 5 minutes are through Lines indicated. These numbers are to be seen in semicircular windows 51 above the faceplate, so that the times for different time zones can be read off in these windows.

The above-mentioned display wheel 29 for the height of the sun is driven by the annual wheel 23 in a window 52 becomes, visible ο.

In Windows53 they are each indicated by the date set days and months - ■ applied to the Outer crown of loges wheel 31 and IConatsrad-30 visible

For this purpose, the front panel can have a clock face 34 » Switch 36 for the actuation of brakes, clock, .Motor and lighting and light displays 35 in connection

with the mentioned adjustment buttons 36 included.

In the exemplary embodiment according to FIGS. 5 and .0, the as is common today, "with his iolachse

inclined in relation to the vertical, ma. to show the inclination of the earth's axis as it revolves around the sun. Otherwise, the parts of this exemplary embodiment, insofar as they are identical to the parts preceding the first exemplary embodiment, are provided with the same reference number and are not "described in more detail" below.

The exemplary embodiment according to FIGS. 5 and 6 differs from the first exemplary embodiment essentially in that the lighting device no longer has to be pivoted, but only need to be rotated Globe axis to the axis of rotation of the lighting device in the course of a year to hike point A ₅ at which the sun is at its zenith. " in a horizontal plane by a full rotation of 36o degrees and thus to a migration of point A, due to the inclination of the globe axis at the angle of the ecliptic, of 23 ~ degrees ITord

² ^ 23— South ο This achieves the same effect as by swiveling the lighting device in exemplary embodiment 1 "

The design according to this embodiment is held by a foot 41, which supports the bracket 3. The bracket 3 contains bearings for the shafts around which the ball is rotated, the upper shaft 6b at the upper pole and the hollow rod 2 at the lower pole a hollow shaft AA, an intermediate piece 39 and the hollow shaft 4, the hollow ball 5 is driven. The hollow shaft 44 carries at the upper end a worm wheel 42 j which via worm wheels 43 and 43a

A further worm wheel 45 drives and thus the lighting device 8 _S 9 ₅ which is firmly connected to the worm wheel 45 via a hollow shaft 46. The lighting device 8, 9 in this embodiment is no longer pivotable, but only rotatable about a vertical axis arranged ο

The. Ηοηΐλ / elle 44 is rotatably mounted on the lower part 6a of the shaft 6. "The lower shaft portion 6a is in the foot firmly bolted to a plate 50, connected at the opposite end fixed to a block 48 ₀ This block 48 carries the worm wheels 43 and 43a and is firmly connected to a shaft 49 _? which serves on the one hand as a bearing for the hollow shaft 46 and on the other hand via a connecting piece 47 - establishes a fixed connection to the upper shaft 6b = The connection between the shafts 49 and 6b is electrically non-conductive, so that the power supply for the light source 8 via the two Shaft parts 6a and 6b out v / ground.

As v in Embodiment 1 / ground the hollow ball and the illuminating device either by a clock or by a Kotor driven ₀ D _a for making the Z _c itscheibe again in the course of z \ / eiraal 24 hours, a full Unidrehung, Ein.mit the time slice 17 rigidly connected gear 38 transmits this Drehbev / ath in tjbersetzungs- ² ^ a ratio of 1: 2 in a fixed manner to the hollow shaft 44 associated gear 37 and thus causes via the intermediate piece 39 and the hollow shaft 4, rotation of the carbon ball 5 within 24 hours, '

The gears 42 ₅ 43 ₅ 43a and 45 are coordinated so that the lighting device 8, 9 a

full turn over the course of 366 full turns the hollow sphere 5 executes »

The 3 _a tumsanzc-ige in globe base is carried out in the same way as in embodiment 1 and is therefore not described again "The illumination of the G-lotus area is the same" as in embodiment I ₅ so that it is also possible in this embodiment5 to "illuminate the globe in such a way that in each case half is illuminated which actually corresponds to the half of the sun illuminated by the sun at the time given in the base of the globe and on the date given in the base of the globe

The -Fig _o 8 shows a side view, or Wc. Front view of the Patumweiterschaltung, wherein the housing intermediate plates are intended cut so that the axes of the wheels 29 ₅ 30 and 31 exposed The drawing shows in addition to the other figures, the spring 31e, a small pin between the R _a dteilen 31 and 31b, which the one connecting the end of the spring with the ^ _a gesrad and with - connected your body mount, the already said the other end of the spring retainer As should said spring respectively in the course of a Konats are wound by the handoff of the day wheel 31, and when IJnschalten on the the day wheel to the starting position for the new month

² ^ turn back ο Part 31b of the day thread has been changed in such a way that no longer a continuous axis and a l \ Oc3; en are provided, but two discs that are centric to the axis of the wheel 31 and that are connected by an eccentric corrugated part are, where the crank

this circle R _a dteiles slightly greater than the tooth pitch of the toothed Radteiles 30a of IConatsanzeigerades

In the embodiment according to Jig »9," better guidance of the push rod 26 is achieved by the fact that the rod is held in place for most of the month - even between the "toothing of the part 30a and the guides indicated by dashed lines - the month wheel locked and only released shortly before the next honorsurn _o In the new Torrn, the push rod 26 simultaneously prevents the wheel 31 from turning back by more than one rotation, doll »it serves as a stop in the honorsura positiono

Claims (18)

HansW-r Arnold September 30, 1966 Business note. A 25 879 / 42n Seh-DB / Ma claims 1. Globe with a lighting device arranged in its interior, characterized in that the lighting device (8, 9) and / or a hollow sphere (5) reproducing the globe are in such a way antreilfoar, that the earth's movement around the sun is simulated and that Lighting device is designed so that the instantly sunlit half of the earth on the globe is illuminated. 2. Globe according to claim 1, characterized in that the lighting device (8,9) consists of a point-shaped light source (8), which is arranged in a focal point of a polished mirror ring (9c) is that a light spot is formed on the hollow sphere (5) by the reflected light rays. 3. Globe according to claim 2, characterized in that the lighting device (8,9) has _{a darkening ring (9b) at its S a} nd, while the polished mirror ring (9c) is designed as a fully reflective mirror « 4. Globe according to claim 2 or 3, characterized in that the lighting device (8,9) and the hollow sphere (5.) about a diameter axis of the hollow sphere relative to one another are rotatable and the lighting device can be pivoted in planes passing through the diameter axis is. 5 · Globus after. Claim 4, characterized in that that the diameter knife axis is formed from a two-part shaft (6), at the lower part of which is a pivot point the lighting device forming bearing (10) is attached, while a pivot point forming Bearing (11) of the lighting device is attached independently of the shaft. 6. Globe according to claim 5, characterized in that that this is the fulcrum of the lighting device (8,9) forming bearing (10) is mounted in the center of the hollow ball (5), while the forming the pivot point bearing (11) with a control rod (13) "connected and closed the poles of the hollow ball can be pivoted about the bearing (10) forming the pivot point. 7. Globe according to claim 2 or 3, characterized in that that the hollow ball (5) is rotatable about a diameter axis and the lighting device consisting of the light source (8) and the concave mirror (9) by one opposite der Durehmesseraeh.se around the inclination of the axis of rotation the earth's inclined axis to orbit is rotatable. 8. globe according to claim 7, characterized in that the hollow sphere within a day once around their Axis of rotation and the lighting device is rotated once about its axis of rotation within a year. 9. Globe according to one of claims 2 to 6, characterized in that a gear for driving the hollow ball (5) and lighting device (8,9) is provided, which can either be a clock or a motor having drivable time slice (17), which together with the globe diameter axis once every 2 times 24 hours rotates and meshes with an annual wheel (23), that the lighting device (8, 9) pivots fully once within a year. 10. G-lobus according to claim 9, characterized in that that the pivoting movement is controlled via a crank mechanism (33) which is driven by the annual wheel (23) is driven. 11. G-lobus according to claim 7 or 8, characterized in that that a gear for driving the hollow ball (5) and lighting device (8,9) is provided, the one has either a clock or a motor drivable time disc (17) which the hollow ball (5) over a hollow shaft (44) rotates once every 24 hours by 360 °, and that by a relative movement between the revolving Hollow shaft (44) and the fixed globe shaft (6a, 6b) via a worm gear (42, 43, 43a, 45) the lighting device (8,9) can be rotated 360 times within 366 days. 12. Globe according to claims 9 to 11 to achieve Much shorter, but constant cycle times, characterized by that the motor has a much higher drive speed has than the clock and optionally one of the two drives can be coupled to the time disc (17). 13. G-lobus according to one of claims 9 to 12, characterized characterized in that between the drive axes of the hollow ball and Bauehtungseinrichtung and the gear and / or clock and motor overrunning clutches are provided with a locking mechanism for one direction of rotation. 14. Globe according to claim 9 or 11, characterized in that "" a ± e time slice (17) in a 24 hour Circulation corresponding distance each has a crouch (17b) which comes into engagement with a lever (31a) to which a spring (3Ie) is attached, which is in engagement with a day wheel (31) and during a pivoting movement the day wheel continues to rotate by 1/32 of its circumference » 15. Globe according to claim 14, characterized in that the day wheel (31) is rotated against the force of a spring from the F _e connected to the lever and is pushed back into its starting position after having covered a rotation of almost 360 °. 16. Globe according to claim 15, characterized in that in a ring gear of the day wheel (31) an arm (b) a control body (24) engages in the manner of a pawl, which after covering the almost 360 ° amount Rotation by a swiveling movement triggers the forward turning of the ^ age wheel. 17. Globe according to claim 16, characterized in that the beginning of the turning back of the day wheel (31) via cams (17c) and recesses (23a) provided on the time disc (17) and an annual wheel (23) is controlled, via which the control body (24) can be pivoted about a vertical and horizontal axis. 18. Globe according to one of the preceding claims, characterized in that in the foot (1) window (51-53) to visualize the data on the time slice (17), day (31), month (30) and year wheel (23) contains.