TWM576662U - Aurora and light dance generation machine - Google Patents

Abstract

A manufacturing machine comprising: a plurality of light sources, which generate light beams of different colors of laser light after being energized; a plurality of lenses, wherein the partial overlap of the lenses is defined as an overlap region, and one of the mirror surfaces of each lens is not smooth . When the light beam is incident on the overlapping area of the lens, the unsmooth mirror refracts the light beam, and a developing unit receives the light beam to form an image suitable for viewing like aurora and/or light dance. Even if you don't go far, any user can experience the aurora and/or radiance of the light dance through the manufacturing machine, and feel the beautiful features of the earth's south and north.

Description

Aurora and light dance manufacturing machine

This creation involves aurora simulation techniques, especially a device that artificially produces analog images such as aurora and/or halo.

It is well known that luminescence at high latitudes is called aurora. Aurora is a large-scale discharge process that covers the Earth's surroundings. Simply put, the Earth's magnetic field usually forces some of the charged particles from the Sun to concentrate along the magnetic field lines to the north and south poles, and collide or excite the atoms and molecules in the atmosphere. During the release of energy, around the magnetic poles The light of a big circle. Therefore, the frequency of aurora appears in the south and north of the earth, which is higher than other regions of the earth.

However, the life of modern people is very busy, not to pursue knowledge, or to work. Even if you take a free time, you will abandon the South and North poles and change to a more recent area or country because of the long distance. In this way, it is a very regrettable thing to have a taste of the aurora and only watch TV or video.

Therefore, how to make people appreciate the aurora style without going far away has become an urgent problem to be solved in this creation.

In view of this, the present invention provides a manufacturing machine, one of the main purposes of which is to use an optical device to artificially produce illuminating phenomena such as aurora and/or light dance, and to experience the aurora analog image without knowing the distance, and to feel the earth personally. The beautiful appearance of the south and north poles.

Due to the above object, the manufacturing machine of the present invention comprises: a plurality of light sources, which generate light beams of different colors of laser light after being energized; and a plurality of lenses, the partial overlap of the lenses is defined as an overlapping area, each lens One of the two mirrors is not smooth.

When the light beam is incident on the overlapping area of the lens, the unsmooth mirror refracts the light beam, and a developing unit receives the light beam to form an image suitable for viewing like aurora and/or light dance.

In this way, the light source and the lens of the manufacturing machine created in this case constitute a light-emitting assembly, which can artificially produce auroral light and/or light dance, and simulate the aurora image of the south and north poles of the earth, and can be personally experienced even if it is not far away. Feel the beautiful aurora.

In order to make the above objects, features, and advantages of the present invention more comprehensible, one or more preferred embodiments are described in detail with the accompanying drawings.

10‧‧‧Lighting assembly

11‧‧‧Regulator

12‧‧‧Support

13‧‧‧Box

14‧‧‧ Controller

16‧‧‧Wire

18‧‧‧Power supply

20, 21‧‧ ‧ motor

22‧‧‧First light source

23, 28‧‧‧ axis

24‧‧‧second light source

26‧‧‧ Third light source

30‧‧‧First beam splitter

31, 36‧‧‧ transparent lenses

32, 37‧‧‧ refracting lenses

33‧‧‧ Beam

34‧‧‧Light control film

34A, 42‧‧‧ center hole

35‧‧‧Second beam splitter

38‧‧‧Translucent area

39‧‧‧ hole

40‧‧‧First lens

41‧‧‧Reflective zone

43‧‧‧second lens

44‧‧‧Overlapping area

45‧‧‧Mirror

46‧‧‧Light transmission area

48‧‧‧Opacity zone

50‧‧‧ wall

52‧‧‧Image

60‧‧‧ Shell

62‧‧‧Set

70‧‧‧ convex lens group

72‧‧‧ flat transparent board

74‧‧‧ arc transparent plate

76‧‧‧Transparent liquid

78‧‧‧Confined space

80‧‧‧ projection screen

82‧‧‧Plastic screen

84‧‧‧ screen

90‧‧ ‧ behind-the-scenes refractor

92‧‧‧Manufacture machine

94‧‧‧Developing unit

94A‧‧‧ Cover

94B‧‧‧ crystal

94C‧‧‧Support Department

94D‧‧‧through hole

Fig. 1 is a plan view showing the first embodiment of the creation manufacturing machine.

Figure 2 is a schematic diagram of the image.

Fig. 3 is a plan view showing a second embodiment of the creation manufacturing machine with respect to the light-emitting assembly.

Figure 4 is a top plan view of the lens not smooth mirror.

Figure 5 is a cross-sectional view of a portion of the lens.

Figure 6 is a bottom view of the light control sheet.

Fig. 7 is a view showing the state of use of the manufacturing machine of Fig. 3.

Fig. 8 is a schematic view showing a third embodiment of the creation manufacturing machine.

Fig. 9 is a schematic view showing a fourth embodiment of the creation manufacturing machine.

Fig. 10 is a schematic structural view of Fig. 9.

Figures 11 and 12 are cross-sectional views of the projection screen and the convex lens group of Fig. 10, respectively.

Figure 13 is a schematic view showing a fifth embodiment of the creation manufacturing machine.

Fig. 14 is a schematic view showing a sixth embodiment of the creation manufacturing machine.

The first and second figures show a first embodiment of a manufacturing machine 92 in which a lighting assembly 10 is disposed. Upon energization, the illumination assembly 10 emits one or more beams 33 to a developing unit 94. The image forming unit 94 receives an image 52 at the light beam 33. The image 52 can be an aurora and/or a regularly-moving galloping light for viewing a scene that is rarely seen.

In the figure, the illumination assembly 10 includes a first light source 22, a second light source 24 and a third light source 26, and the first, second and third light sources 22, 24, 26 and a control are controlled by three wires 16. The 14 are connected together. The controller 14 is electrically connected to a power source 18 and a regulator 11 connected to external power (such as a generator or a commercial power) and supplied to the manufacturing machine 92. The power source 18 can be a plug that incorporates a generator or mains outlet (typically an alternating current). Of course, it is within the permissible range of this creation to use a DC power supply with a battery as the power source 18.

In this embodiment, the first, second, and third light sources 22, 24, 26 may be laser light generators. After energization, each of the laser light generators produces a beam 33, each beam 33 being of a different color, such as red, green, and blue. In other words, the light beams 33 generated by the first, second, and third light sources 22, 24, 26 are laser light of different colors.

In the figure, the regulator 11 is provided on the controller 14 for adjusting the brightness of the light beam 33. In some embodiments, the adjuster 11 is separate from the controller 14, and the two are connected together by other wires 16 to achieve brightness adjustment.

In addition, the light assembly 10 further includes a first lens 40 and a second lens 43 between the light source and the developing unit 94. The first and second lenses 40, 43 each have two mirror faces 45, and at least one mirror face 45 of each lens 40 or 43 is not smooth. Moreover, the first and second lenses 40, 43 are partially overlapped to define an overlap region 44 that is in front of the light source.

In use, it is assumed that the first and second lenses 40, 43 are not rotated. When the light beam 33 Upon entering the overlap region 44, the light beam 33 is caused to refract by the non-smooth mirror surface 45 of the second lens 43, and is again refracted to the developing unit 94 by the mirror 45 which is not smoothed by the first lens 40.

If the first lens 40 is rotated; the second lens 43 is fixed. When the light beam 33 is incident on the overlap region 44, the light beam 33 is incident on the mirror 45 which is not smoothed by the second lens 43 to cause a refraction phenomenon, and the orientation of the unsmooth mirror surface 45 is changed in response to the rotation of the first lens 40, and the associated refractive index changes, so that the light beam 33 is changed. Incident to the developing unit 94 reveals an image 52 that is continuous like a light dance.

Of course, the first and second lenses 40, 43 are all rotated, and the developing unit 94 receives the change of the image 52 appearing at the light beam 33, which is more elusive.

In some embodiments, the illumination assembly 10 has only a single lens and is within the permissible range of this creation. It is assumed that the single lens is fixed, the light beam 33 is incident on the mirror surface 45 which is not smooth, and is refracted to the developing unit 94, and the still image 52 is also displayed for viewing as aurora. If the single lens is rotated, the light beam 33 is incident on the mirror 45 which is not smooth by the lens. Depending on the refractive index, the image 55 of the variability is generated at the receiving beam 93 of the developing unit 94, like a continuous picture of irregular dancing. .

Specifically, the developing unit 94 may be a flat surface of an object such as a screen, a wall, or the like. Moreover, the developing unit 94 may also be a water-fog-like refraction area, and the aerosol area is irregular, and a fog machine is usually used (see Patent No. M297271 or M419068). To make. When the light beam 33 of the light-emitting assembly 10 is incident on the water mist region, the water mist region can also generate an image that is as brilliant as an aurora. Of course, the imaging unit 94 has other items to be replaced, which will be detailed one by one in the following description.

3 to 6 show a second embodiment of the manufacturing machine, the structure of which is substantially the same as that of the first embodiment, the difference is that the light assembly 10 adds a support member 12, a set of motors, a piece of light control sheet 34 and two Splitting component.

In this embodiment, the support member 12 is a flat plate for supporting the first light source 22, The sum of the weights of the two light sources 24, the third light source 26, the first lens 40 and the second lens 43. In some embodiments, the support member 12 can be a platform, a movable mechanism, or other related item sufficient to support the various components.

These beam splitting assemblies stand on the support member 12 and are fixed and are divided into a first beam splitting assembly 30 and a second beam splitting assembly 35 by angle or orientation.

In the figure, the first beam splitting assembly 30 is between the second beam splitting assembly 35 and the overlap region 44, and is composed of a transparent lens 31 and a refractive lens 32. The transparent lens 31 is between the third light source 26 and the refractive lens 32, and the refractive lens 32 is preferably substantially parallel to the transparent lens 31. When the third light source 26 emits a light beam 33 toward the first beam splitting assembly 30, the light beam 33 is refracted by the transparent lens 31 to the overlap region 44; alternatively, the light beam 33 is refracted by the transparent lens 31 to the refractive lens 32 and refracted to the overlap region 44. In some embodiments, the first beam splitting assembly 30 has only the refractive lens 32 and no transparent lens, which is within the scope of the present invention.

Similarly, the second beam splitting assembly 35 also has a transparent lens 36 and a refractive lens 37, and the refractive lens 37 is preferably substantially parallel to the transparent lens 36. However, the transparent lens 36 is between the first light source 22 and the refractive lens 37. When the first light source 22 emits a light beam 33 toward the second beam splitting assembly 35, the light beam 33 is refracted by the transparent lens 36 to the overlap region 44 or refracted through the transparent lens 36 to the refractive lens 37 and refracted to the overlap region 44. In some embodiments, the second beam splitting assembly 35 has no transparent lenses, only the refractive lenses 37, and is within the permissible range of the present invention.

According to the above description, it is known that the third light source 26 is at the upper left of the second light source 24, and the first light source 22 is at the upper right of the second light source 24 (see FIG. 3), so that the two transparent lenses 31, 36 are located at the second light source. 24 is between the overlap region 44. When the second source 24 emits a beam 33 towards the overlap region 44, the beam 33 is refracted by the two transparent lenses 31, 36 to the overlap region 44.

These motors 20, 21 are electrically connected to the controller 14. The motor 21 has a shaft 23 that is coupled to the center hole 34A of the light control sheet 34 and the center hole 42 of the second lens 43. Operation controller 14 The adjustment shaft 23 drives the rotational speeds of the light control sheet 34 and the second lens 43, and even determines that the shaft 23 is fixed. The motor 20 also has a shaft 28 that engages the central bore 42 of the first lens 40 to enable rotation of the first lens 40 or to immobilize the first lens 40 in response to operation of the controller 14.

In the figure, the light control sheet 34 is bonded (e.g., adhered) to the back of the second lens 43, so that the light control sheet 34 is rotated or fixed in the same direction as the second lens 43. The light control sheet 34 has a plurality of holes 39 (see FIG. 6) and an opaque region 48. The holes 39 are transparent to the opaque region 48, and each of the holes 39 is irregular. The opaque region 48 is a portion of the light control sheet 34 excluding the center hole 34A and the hole 39. When the light beam 33 is incident on the light control sheet 34, the opaque region 48 of the light control sheet 34 shields or refracts the light beam 33, and only the light beam 33 passes through the hole 39 of the light control sheet 34 before the second lens 43 is incident. A portion of the overlap region 44, and refracted by the non-smooth mirror 45, passes through the first lens 40 at a portion of the overlap region 44.

In the present embodiment, the non-smooth mirror surface 45 is different from the first embodiment in that the frosted glass serves as a non-smooth mirror surface, but is disposed in a plurality of glass two-smooth mirror surfaces 45 which are irregularly arranged and can be stacked on each other. The translucent region 38, the refractive region 41, the light transmissive region 46 and the opaque region 48.

The refractive area 41 referred to herein means that some transparent liquid (e.g., transparent glue) is applied to the smooth surface 45 of the two lenses 40, 43 to form an uneven surface. The opaque region 48 referred to herein means that some opaque material (such as opaque tape or pigment) adheres or covers the mirror surface 45 of the two lenses 40, 43 to produce a light blocking effect. The translucent zone 48 referred to herein means that some translucent material (e.g., translucent glue or pigment) is applied to the mirror surface 45 of the two lenses 40, 43 to form an uneven surface.

When the light beam 33 is incident on the overlapping region 44 of the first and second lenses 40, 43, the light beam 33 is blocked or refracted by the opaque region 48, but can penetrate through the translucent region 38, the refractive region 41, and the light transmitting region 46. Optical effects such as refraction, diffusion, dispersion, or color mixing.

As shown in Fig. 7, the developing unit 94 is a wall surface 50. The wall 50 (or imaging) Unit 94) is not inside the manufacturing machine 92, but is in front of the manufacturing machine 92. When the beam 33 is projected onto the wall 50, the wall 50 receives the beam 33 and produces an auroral and/or light-like image 52.

Fig. 8 is a third embodiment of the authoring machine 92, which is substantially identical in construction to the second embodiment, except that the machine 92 has a housing 60 that allows the lighting assembly 10 to be disposed inside the housing 60. Therefore, the manufacturing machine 92 protects the light-emitting assembly 10 from external force damage, affecting the emission of the light beam, and facilitating the relocation and transportation.

Secondly, the developing unit is a projection screen 80 disposed in the manufacturing machine 92, and the side receiving the light beam can display a beautiful color galloping image.

Furthermore, the manufacturing machine 92 has a convex lens group 70 that is embedded in the outer casing 60 opposite the projection screen 80. Any user can enlarge the convex lens group 70, and the left and right eyes can generate a difference in viewing angle through the lens, and the stereoscopic light dance image of the projection screen 80 can be viewed.

Figures 9-12 are a fourth embodiment of the manufacturing machine 92, which is substantially identical in construction to the third embodiment, with the difference that, first, the development unit has a rear refractor 90. The behind-the-scement refractor 90 is disposed inside the manufacturing machine 92 and behind the projection screen 80.

Next, the light-emitting assembly 10 is disposed inside a casing 13, which can protect the light-emitting assembly 10 from external force damage, and the light-emitting assembly 10 is conveniently mounted in the manufacturing machine 92. When the casing 13 is tilted, the light beam 33 of the light-emitting assembly 10 enters the behind-the-sector refractor 90 and is refracted to the projection screen 80, which also displays auroral and/or light-like images on the surface of the projection screen 80. In this way, any user can view the vivid stereo aurora image through the convex lens group 70.

Moreover, the interior 92 of the manufacturing machine 92 is disposed at a position between and below the projection screen 80 and the convex lens group 70. In addition to shielding the casing 13, the user can be prevented from perceiving the total illumination. Into the existence of 10. The set 62 presents the geographical environment of the South Pole or the North Pole, which sets off the Aurora image, allowing the user to enjoy the aurora and/or light dance in person.

In addition, the convex lens group 70 may be a solid glass or a convex lens. In some real For example, the convex lens group 70 may be of a combined configuration. As shown in Fig. 12, the convex lens group 70 is composed of a flat transparent plate 72 combined with a circular arc transparent plate 74, which together define a sealed space 78. Some of the transparent liquid 76 is filled in the sealed space 78 of the convex lens group 70, and the curvature which is substantially the same as that of the solid convex lens can be obtained, which not only reduces the manufacturing cost but also enhances the competitiveness of the market.

In addition, the projection screen 80 can also discard the monolithic translucent plastic curtain and adopt a combined construction. As shown in FIG. 11, the projection screen 80 is composed of a translucent plastic screen 82 which is parallel to a light transmissive screen 84. The light beam 33 (see Fig. 10) is incident on the plastic screen 82 and is refracted to the diffused effect of the screen 84, allowing the user to view the immersive auroral image from the lenticular lens group 70.

In some embodiments, the projection screen 80 is not inside the manufacturing machine 92, but rather outside of the manufacturing machine 92, an image of the aurora and/or light dance can also be formed at the receiving beam 33.

Figure 13 is a fifth embodiment of the manufacturing machine 92, which is substantially identical in construction to the fourth embodiment, with the difference that, first, the developing unit 94 is a cover 94A, and the cover 94A is transparent (or Translucent), which is fixed to the outside of the casing 60, replaces the projection screen of the fourth embodiment, allowing the user to see a crystal-like brilliance change.

Next, a transparent support portion 94C is embedded in the wall surface of the outer casing 60, and the support portion 94C is positioned above the curtain refractor 90 to be covered or covered by the cover 94A.

Further, more than one crystal 94B is adhered to the surface of the support portion 94C just in the refractive range of the refractor 90 behind the curtain. When the light-emitting assembly in the casing 13 emits the light beam 33, the light beam 33 is refracted to the support portion 94C through the behind-the-sector refractor 90, and diffused through the crystal 94B to the cover 94A, which contributes to the appreciation of crystal clear crystal light.

Fig. 14 is a sixth embodiment of the manufacturing machine 92, which is substantially identical in construction to the fifth embodiment, except that the crystal and the support portion are discarded so that the outer casing 60 has a through hole 94D. When the light beam 33 enters the cover 94A through the through hole 94D, the cover 94A is a translucent screen, and receives the light beam 33. It can also present a beautiful light dance image.

Claims (11)

An auroral and light dance manufacturing machine comprising: a plurality of light sources, which, when energized, generate light beams of different color laser light (33); and a plurality of lenses, the partial overlap of the lenses being defined as an overlap region (44), One of the two mirror faces (45) of each lens is not smooth; when the beam (33) is incident on the overlap region (44) of the lens, the unsmooth mirror (45) refracts the beam (33), a developing unit (94) The receiving beam (33) forms an image (52) that is suitable for viewing like aurora and/or light dance. The aurora and light dance manufacturing machine according to claim 1, further comprising: a support member (12) for allowing the light source and the lens to be disposed on the support member (12); and a plurality of motors (20, 21), The motors (20, 21) are disposed on the support members (12), and each of the motors (20, 21) is coupled to a corresponding lens to determine whether the lens is rotated or fixed. The aurora and light dance manufacturing machine according to claim 2, further comprising: at least one light control sheet (34) coupled to the back of the lens, which is operated in synchronization with the lens, the light control sheet (34) having a plurality of holes ( 39) and an opaque region (48), the opaque region (48) is a portion of the light control sheet (34) except for the holes (39). The aurora and light dance manufacturing machine according to claim 1, wherein the non-smooth mirror surface (45) refers to: a plurality of irregularly and vertically stacked translucent regions (38) and a refractive region (41). The light transmissive region (46) and the opaque region (48) are disposed on the mirror surface (45), and the optical beam (33) incident on the lens overlap region (44) is interrupted, penetrated, refracted, and diffused. One of the roles. The aurora and light dance manufacturing machine according to any one of claims 1 to 4, further comprising at least one beam splitting assembly comprising: a refractive lens (32 or 37) for transmitting the light beam (33) Refraction to the overlap region of the lens (44). The aurora and light dance manufacturing machine according to claim 5, wherein the developing unit (94) is inside the manufacturing machine (92) or outside, and may be a water mist-like refractive area or a wall surface (50). One of the objects that can form an image (52) at the projection screen (80), the cover (94A), and other receiving beams (33). The aurora and light dance manufacturing machine according to claim 6, wherein the projection screen (80) is disposed inside the manufacturing machine (92), and is matched with a convex lens group (70) and a rear curtain refractor (90). The behind-the-scement refractor (90) is behind the projection screen (80) to refract the beam (33) to the projection screen (80) to form an image (52). The convex lens group (70) is opposite the projection screen (80). For viewing of images (52). The aurora and light dance manufacturing machine according to claim 7, wherein the convex lens group (70) has a flat transparent plate (72), and the flat transparent plate (72) is combined with a circular arc transparent plate (74). Enclose a confined space (78) and fill some transparent liquid (76) in the confined space (78). The aurora and light dance manufacturing machine according to claim 7, wherein the projection screen (80) is composed of a parallel semi-transparent plastic screen (82) and a screen (84); in the light beam (33) Upon entering the behind-the-scement refractor (90), the plastic screen (82) diffuses the beam (33), causing the light to be projected onto the screen (84) to produce a chirped auroral image (52). The aurora and light dance manufacturing machine according to claim 6, further comprising: a casing (60) for protecting the light source and the lens, wherein the casing (94A) is firmly external to the casing (60), the casing ( 60) A through hole (94D) is provided to allow the light beam (33) to enter the cover (94A) through the through hole (94D) to form an image (52). The aurora and light dance manufacturing machine according to claim 10, further comprising: a transparent support portion (94C) embedded in the through hole (94D) of the outer casing (60); at least one adhered to the support portion ( The crystal of 94C) (94B) refracts the beam (33) to the cover (94A).