TWM375264U - Globe with day and night - Google Patents

Abstract

A globe with day and night includes a sphere, a rotation axle, a light-shielding element and two light-emitting elements. The sphere is light-transmissible. The rotation axle is disposed through the sphere. The light-shielding element is disposed in the sphere and fixed to the rotation axle. The light-shielding element passes through the center of sphere and separates the sphere into a first part and a second part. An angle is formed between the light-shielding element and the rotation axle. The light-emitting elements are disposed respectively on two sides of the light-shielding element and located in the first part and the second part of the sphere.

Description

M375264 V. New description: [New technical field] This creation is about a globe, especially about a globe that is well-behaved. [Prior Art] In order to understand the location of countries around the world, in addition to the plane map, the globe is the most common prop. As shown in FIG. 1, the conventional globe J includes a sphere U having a sphere 15 having a sphere 15 disposed on a rotation axis 12 penetrating the sphere u, and the sphere u being rotatable about the axis 12 of the rotation axis 12 and the rotation axis 12 and half The circular bracket 13 is fixed, and the bracket 13 is disposed on a base 14. Therefore, the user can query the desired position on the map ι5 by rotating the sphere η. The Renyi 4 knows that the globe 1 is only a rotating sphere 11 pivoted on the base 14, so that the user cannot obtain, for example, the northern hemisphere summer (the summer return to the north pole in the summer solstice) or the winter (the winter solstice direct sunlight). Information such as the state of the sun's exposure. [New content] In view of the above issues, the purpose of this creation is to provide a day and night globe that simulates the northern and southern hemispheres in summer or winter. For the above purposes, a well-defined globe according to the present invention includes a sphere, a rotating shaft, a shading element, and two illuminating elements. The ball M375264 system is transparent. The rotating shaft is threaded through the sphere. The light shielding member is disposed in the spherical body and fixed to the rotating shaft, and divides the spherical body into a first portion and a second portion through a center point of the spherical body, and the light blocking member and the rotating shaft are at an angle. The light emitting elements are respectively disposed in the first portion and the second portion on both sides of the light shielding member. In an embodiment of the present invention, the sphere is rotated about the axis of rotation. In an embodiment of the present invention, the direction of extension of the axis of rotation coincides with the direction of inclination of the earth's rotation. In an embodiment of the present invention, the globe further includes a base, and the ball system is rotatably disposed on the base by the rotating shaft frame. In an embodiment of the present invention, the globe further includes two switching elements disposed on the base, and the switching elements are electrically connected to the light emitting elements. In an embodiment of the present invention, the ball is fixed, and the rotating shaft and the light shielding member are rotated relative to the spherical body. In an embodiment of the present invention, the rotating shaft and the shading member are fixed, and the ball rotates relative to the rotating shaft and the shading member. In an embodiment of the present invention, when the angle is 23.5 degrees, the light-emitting elements are selectively turned on to directly direct the Southern Regression or the Tropic of Cancer. In an embodiment of the present invention, when the angle is zero degrees, the light-emitting elements are selectively turned on to directly illuminate the equator. In an embodiment of the present creation, the axis of rotation passes through the center point of the sphere. In an embodiment of the present invention, the light-emitting elements are respectively disposed adjacent to a center point of the sphere. As mentioned above, the globe of the present invention has a shading element disposed in the 5 M375264 sphere and fixed to the rotating shaft, and divides the sphere into a first part and a second part through the center point of the sphere, and the sphere is The part and the second part respectively have light-emitting elements, so by combining the light-emitting element and the light-shielding element, the created globe can simulate the northern or southern hemisphere in summer or winter sunlight, such as the northern hemisphere summer (ie, the southern hemisphere winter) or the winter ( That is to say, in the summer of the southern hemisphere, the globe of this creation can display the day and night of the northern and southern hemispheres in the summer or winter in addition to the map information, and can further present the situation of the north and south poles forever or forever. . [Embodiment] Hereinafter, a globe that is well-defined according to a preferred embodiment of the present invention will be described with reference to the related drawings, in which the same elements will be described with the same element symbols. 2 and 3 are respectively a side view and a perspective view of a day and night globe 2 of a preferred embodiment of the present invention. Referring to Figures 2 and 3, the globe 2 of the present invention includes a sphere 21, a rotating shaft 22, a shading element 23, and two light-emitting elements 241 and 242. The ball 21 is, for example, a light-transmissive hollow casing, and the thickness of the casing is not limited herein. In addition, the material of the spherical body 21 is not limited herein, so that the light of the light-emitting elements 241 and 242 can be uniformly emitted. Further, in order to clearly show the internal structure of the sphere 21, the world map on the sphere 21 is omitted here, but in practice, the sphere 21 should be provided with a M375264 world map. The surface of the sphere 21 has three dashed lines from top to bottom, which respectively represent the Tropic of Cancer 3, the equator 4 and the Tropic of Cancer. The rotating shaft 22 is bored through the spherical body 21. The rotating shaft 22 can pass, for example, the center point 0 of the ball 21, and the ball 21 can be rotated about the axis of rotation 22 . The direction of extension of the rotating shaft 22 coincides with the direction of inclination of the axis of rotation of the earth. The light shielding member 23 is disposed in the spherical body 21 and fixed to the rotating shaft 22. Specifically, the ball 21 is rotatable relative to the rotating shaft 22 and the shading member 23 ® . For example, the rotating shaft 22 and the light shielding member 23 can be fixed to rotate the ball 21 with respect to the rotating shaft 22 and the light shielding member 23. Alternatively, the ball 21 can be fixed to rotate the rotating shaft 22 and the light shielding member 23 with respect to the ball 21. In addition, the light shielding member 23 divides the spherical body 21 into a first portion 211 and a second portion 212 by the center point 0 of the spherical body 21, and the light blocking member 23 and the rotating shaft 22 are at an angle Θ. The light shielding member 23 is, for example, a light shielding plate, a g or a reflecting plate or other member capable of shielding or reflecting light, and is not limited thereto. The light blocking member 23 and the rotating shaft 22 are fixed to the center point 0 of the spherical body 21, and the angle Θ between the light blocking member 23 and the rotating shaft 22 can be, for example, 23.5 degrees, in other words, the inclination angle of the earth's rotation axis. The light-emitting elements 241 and 242 are respectively disposed in the first portion 211 and the second portion 212 of the two sides 231 and 232 of the light-shielding element 23. The light-emitting elements 241 and 242 are respectively disposed adjacent to the center point 0 of the sphere 21, so that the light emitted by the light-emitting elements 241 and 242 can be uniformly incident on the sphere 2, in this embodiment, the light-emitting element 241 is adjacent to the light-emitting element 241. The center point 0 of the sphere 21 of one side of the shading element 23 is the M375264 231, and the light-emitting element 242 is adjacent to the center point of the sphere 21 adjacent to the other side 232 of the shading element 23 as an example, which is not limited. Sex. In addition, in this embodiment, the globe 2 may further include a base 25, a bracket 26, and two switching elements 271 and 272, which are not limited. The base 25 is coupled to the rotating shaft 22 by, for example, a semicircular bracket 26, so that the spherical body 21 can be rotated about the axis of rotation 22 with respect to the bracket 26 and the base 25. The switching elements 271 and 272 are disposed on the base 25, and the switching elements 271 and 272 are electrically connected to the light-emitting elements 241 and 242, respectively (not shown). For example, the switching element 271 can pass through the bracket 26 and the rotating shaft 22 by using a wire. And electrically connected to the light-emitting element 241 to control the opening and closing of the light-emitting element 241. Similarly, the switching element 272 can be electrically connected to the light-emitting element 242 by using a wire through the bracket 26 and the rotating shaft 22 to control the opening and closing of the light-emitting element 242. Therefore, the opening and closing of the light-emitting element 241 can be controlled by the switching element 271, and the switching element 272 can control the opening and closing of the light-emitting element 242. Of course, the correspondence between the switching elements 271 and 272 and the light-emitting elements 241 and 242 is not limited, and the switching element 271 controls the turning on and off of the light-emitting element 242, and the switching element 272 controls the turning-on and turning-off of the light-emitting element 241. The spherical body 21 is divided into left and right hemispheres (i.e., the first portion 211 and the second portion 212) by, for example, a circular plate-shaped light shielding member 23, and the light-emitting elements 241 and 242 are respectively disposed on the both sides 231 and 232 of the light-shielding member 23, so that The M375264 user can control the light-emitting elements 241 and 242 by using the switching elements 271 and 272 to simulate the sunshine conditions in the northern hemisphere summer (ie, the southern hemisphere winter) or the winter (ie the southern hemisphere summer), and the day and night state, and can further represent the south. The situation of the Arctic forever or forever. Among them, in the northern hemisphere summer solstice, the solar system directly hits the Tropic of Cancer 3; in the northern hemisphere winter solstice, the sun shines directly on the southern tropic line; while in the northern or southern hemisphere, the sun shines directly on the equator. The above description is based on the fact that the rotating shaft 22 does not move and the ball 21 rotates. The ball 21 can also be moved, and the rotating shaft 22 rotates relative to the ball 21. Since the shading element 23 and the rotating shaft 22 are fixed, the rotation of the rotating shaft 22 causes the shading element 23 to rotate, and the light emitting element 241 or 242 emits The light will make the simulated northern and southern hemispheres change day and night in summer or winter. Please refer to FIG. 4, which is a schematic diagram of the globe 2 of FIG. 2 simulating the northern hemisphere summer illumination. Therefore, when the inclination angle Θ of the rotating shaft 22 and the light shielding member 23 is 23.5 degrees, the light-emitting elements 241 and 242 can be selectively turned on to direct the sunlight to the north tropic line 3 or the south tropic curve 5. In the present embodiment, the light-emitting element 241 is turned on so that the illumination range of the light-emitting element 241 is the same as that of the northern hemisphere summer (i.e., the winter in the southern hemisphere), and the illumination range of the solar ray to the Tropic of Cancer 3 is the same. Thereby, when the user presses the switching element 271 to turn on the light-emitting element 241, the globe 2 can simulate the lighting situation in the northern hemisphere during summer and the day and night state. Furthermore, at this time, the north pole circle N is eternal (that is, there is no night), and the south pole circle S is permanent night (that is, there is no white scorpion). In addition, here again 9 M375264 shows that when the northern hemisphere summer solstice (ie the southern hemisphere winter solstice), the sun shines directly on the Tropic of Cancer. Please refer to FIG. 5. FIG. 5 is a schematic diagram of the globe 2 of FIG. 2 simulating the northern hemisphere winter illumination. Similarly, since the inclination angle Θ of the rotating shaft 22 and the light shielding member 23 is 23.5 degrees, in the present embodiment, the light-emitting element 242 is turned on, and the illumination range of the light-emitting element 242 and the northern hemisphere winter (i.e., the summer of the southern hemisphere) are sunlight. The illumination range of the subtropical line 5 is the same. Thereby, when the user presses the switching element 272 to turn on the light-emitting element 242, the globe 2 can simulate the sunshine situation and the day and night state in the northern hemisphere winter. Furthermore, at this time, the south pole circle S is eternal (that is, there is no night), and the north rim N is always night (that is, there is no day). In addition, it is to be noted here that when the northern hemisphere winter solstice (the summer solstice in the southern hemisphere), the sunlight is directly directed to the Tropic of Cancer. Referring to Figure 6, there is shown a schematic view of the sun of the globe 6 of another preferred embodiment. Therefore, when the inclination angle Θ of the rotating shaft 62 and the light shielding member 63 is 0 degree, the light-emitting elements 641 and 642 can also be selectively opened to direct sunlight to the equator 8. In the present embodiment, the light-emitting element 642 is turned on so that the illumination range of the light-emitting element 642 is the same as that of the northern hemisphere spring (i.e., the southern hemisphere fall) or the northern hemisphere fall (i.e., the southern hemisphere spring). Thereby, when the user presses the switching element 672 to turn on the light-emitting element 642, the globe 6 can simulate the lighting situation and the day and night state in the northern hemisphere spring (southern hemisphere fall) or northern hemisphere fall (southern hemisphere spring). In addition, here again, the northern hemisphere spring equinox (southern southern hemisphere) M375264

Or the southern hemisphere spring equinox (the northern hemisphere autumn equinox), the sun shines directly on the equator 8. It is worth mentioning that the globes 2 and 6 of the present invention may further include a dimming component and a driving component (none of which are shown). The dimming elements can be disposed on the bases 25 and 65, respectively, and electrically connected to the light-emitting elements 241 and 242 or the light-emitting elements 641 and 642, respectively, and the light-emitting elements can adjust the light-emitting elements 241 and 242 or the light-emitting elements 641 and 642, respectively. Intensity to simulate the Earth's exposure to different shades of sunlight. The drive assembly can be disposed on the bases 25, 65 and coupled to the rotating shafts 22, 62 or the balls 21, 61. The rotating shafts 22, 62 and the light-shielding members 23, 63 are rotated by the driving unit or the balls 21, 61 can be driven to rotate about the rotating wheels 22, 62 to automatically simulate the rotation of the earth. It should be noted that the design and setting of the dimming element and the driving component are not limited, and different design methods may be required according to different requirements.

In summary, the globe according to the present invention has a light-shielding element set in 3 and is fixed to the _-axis, and the first part and the second part of the ball are passed through the towel (4) of the sphere, and the first part of the sphere is spotted. s 2:: The light-emitting elements are respectively arranged on both sides of the light-shielding element, and the globe of the creation can be _=the southern hemisphere is in the summer or winter sunshine state, for example, the northern shirt due to the cooperation with/with the navigation member.

The hand (that is, the winter in the southern hemisphere) or the winter (that is, the summer of the show + main & 1 yak ball) E ..., the h shape, by which the creation of the globe in addition to having enough 顼 4 A 1 , , , Maps outside the news, more warehouses!, Wang Jianbei + ball and the southern hemisphere in the summer or winter 蚩 further show the status of the South and North Korea forever or forever. Resentment: More The above description is for illustrative purposes only and is not a limitation. Any changes or modifications to the spirit and scope of this creation are to be included in the scope of the appended patent application. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a conventional globe; FIG. 2 is a side view of the globe of the preferred embodiment; FIG. 3 is a perspective view of the globe of the preferred embodiment; FIG. The globe of the preferred embodiment of the present invention simulates a summer illumination of the northern hemisphere; FIG. 5 is a schematic diagram of the globe in the northern hemisphere winter simulated by the preferred embodiment of the present invention; and FIG. 6 is a perspective view of the globe of another preferred embodiment of the present invention. schematic diagram. [Main component symbol description] [Practical] 1 : Globe 11 : Sphere 12 : Rotary axis 13 : Bracket 14 : Base 15 : Map [This creation] 2 , 6 : Globe 12 M375264 21 , 61 : Sphere 211 , 611 : Part 212, 612: second portion 22, 62: rotating shaft 23, 63: shading element 231, 232: side 241, 242, 641, 642: light-emitting element 25, 65: base 26, 66: bracket 271, 272, 671 , 672 : Switching elements 3, 7 : Northern Tropics 4, 8 : Equatorial 5, 9 : Southern Regression N : Arctic Circle 0 : Center Point S : South Pole Circle : Angle 13

Claims (1)

M375264 VI. Patent application scope: 1. A globe with a clear day and night, comprising: a sphere, which is light-transmitting; a rotating shaft, which is disposed on the sphere; a shading element disposed in the sphere and fixed to the rotation a shaft, and dividing the sphere into a first portion and a second portion through a center point of the sphere, wherein the shading element and the rotating shaft are at an angle; and two light emitting elements are respectively disposed on both sides of the shading element The first portion and the second portion are within. 2. The globe of claim 1, wherein the sphere rotates about the axis of rotation. 3. The globe of claim 1, wherein the direction of extension of the axis of rotation coincides with an oblique direction of the axis of rotation of the earth. 4. The globe of claim 1, further comprising: a base, the ball system being rotatably mounted on the base by the rotating shaft. 5. The globe of claim 4, further comprising: two switching elements disposed on the base, the switching elements being electrically connected to the light emitting elements, respectively. 6. The globe of claim 4, further comprising: a dimming component disposed on the base, the dimming component being electrically connected to the light emitting components. 7. The globe of claim 1, wherein the ball solid 14 M375264 is stationary, and the rotating shaft and the shading element are rotated relative to the ball. 8. The globe of claim 1, wherein the rotating shaft is fixed to the shading element, and the ball rotates relative to the rotating shaft and the shading element. 9. The globe of claim 1, wherein the angle is 23.5 degrees, and the light-emitting elements are selectively turned on to direct the south regression line or the Tropic of Cancer. 10. The globe of claim 1, wherein the angle is zero and the light-emitting elements are selectively turned on to directly erect the equator. 11. The globe of claim 1, wherein the axis of rotation passes through the center point of the sphere. 12. The globe of claim 1, wherein the illuminating elements are respectively adjacent to the center point of the sphere. 15