WO2017061823A2 - Light directing function display device achieved by techniques for implementing manipulation of light directing function, manipulation of display device therefor, and display device therefor - Google Patents

Abstract

The present invention relates to a light directing function display device achieved by techniques for implementing the manipulation of a light directing function, the manipulation of a display device therefor, and a display device therefor. The light directing function is displayed by the light directing function display device and achieved in principle such that: light energy radiated by a light source influences, as light energy, two or more light receiving bodies comprising a material constituting the light directing function display device; and the light receiving bodies, which have received the light energy, generate the electromagnetic wave of emitted light by optical spontaneous emission or thermal radiation emission, thereby allowing for the electromagnetic wave of the emitted light of the two or more light receiving bodies and guiding the light directing function.

Description

A light directing function display device comprising the operation of the light directing function, the operation of the display device, and the implementation technology of the display device.

The present invention relates to a light directing function display device comprising the operation of the light directing function, the operation of the display device, and an implementation technique such as the display device.

Since the 20th century, the use of electricity has been active, and many products using light sources have been released not only for industrial use but also for daily life.

Here, the light source is a light bulb, a fluorescent lamp, an incandescent lamp, and the like, and in recent years, light emitting devices such as LEDs and light emitting panels such as LCDs have been widely used.

In everyday life, for example, a light source may be mounted on the side or rear of a signage to make the signage more prominent, mounted on a ceiling or stand in the room to illuminate the room, or mounted on the front or back of a vehicle to display a signal. It functions to light the road when it is dark.

In addition, the light source may be used to exhibit a visually attractive decoration effect.

In addition, the optical display device for amplifying the visual effect according to the prior art, a plurality of holes are arranged in a toroidal shape in a square plate, and a decorative tool engraved with an advertising phrase or a character is attached to the center thereof.

Such a conventional light directing device, when light is irradiated from the rear of the plate, the light leaks through the hole and exhibits a toroidal halo effect, thereby improving the aesthetic value of the ornament and focusing attention.

Such a light directing device may be used as a decorative picture frame or a signboard.

However, the light directing technology according to the prior art has a limitation in the shape that can be expressed because it is expressed in one dimension, and once produced, there is a problem that the shape cannot be changed and cannot be variously implemented.

An aspect of the present invention is to solve the problems described above,

Diversified light sources for light energy, including ultraviolet light and infrared light in visible light of natural light, and ultraviolet light and infrared light in visible light such as artificial light bulbs and lamps. A single light energy consisting of fine photons of ultraviolet rays and infrared rays which are invisible rays to visible rays such as ultraviolet rays and infrared rays which are invisible rays and visible rays such as artificial light bulbs and lamps are visible rays of natural light reflected by natural light. Included in the category.

In addition, by forming various coupling portions such as a light receiving body of a light directing function display device composed of two or more light receiving bodies having a minimum length of one side of a nanometer (nm) or more, the light directing function display device can be freely used by two or more light receiving bodies. In order to be able to construct, to achieve the function of a precise and multidimensional light receiver,

Two or more light receivers constituting the light directing function display device correspond to the light receivers of the molded light receiver, the molding frame and the specific functional liquid substance, the coupling part and the molding groove, the molding hole, the pattern part, Auxiliary light, the material characteristics of points, lines, planes, and complex three-dimensional light-receiving members, or the color, scale, volume and shape, the positional change, etc. are manipulated, or the manipulated features are combined, mixed, or distributed with each other. It consists of a light receiving body of the light directing function display apparatus which consists of an operation technique, such as the following.

Further, in order to achieve the light directing function displayed on the light directing function display device, the light energy irradiated from the light source is converted and made of the electromagnetic waves of the emitted light such as two or more light receiving bodies constituting the light directing function display device. It is characterized in that the display light (visible light) or non-display light (ultraviolet light, infrared light) of one unit emission light collides with each other, or is multi-associated or spectroscopically to produce a light directing function.

Display energy of one or more unit emission light of the light directing function, which is composed of a combination of electromagnetic waves of emitted light such as two or more light receiving bodies which are converted and constituted a light directing function display device by converting light energy or the like from multiple light sources A combination of two or more light receivers constituting a light directing function display device in which a combination of a light beam) or a non-display light (ultraviolet ray, infrared ray), etc., continuously collides with each other, or is multi-coupled or spectroscopic, to form a light directing function. It remains in or out of the interior or exterior, and forms its shape with electromagnetic waves, etc. of emitted light, such as a light-receiving body, which make up the function of light until the destructive interference phenomenon or kinetic energy is lost to its function.

The technology to freely manipulate the light directing function display device has been improved, and the technical preemption function that can freely express or configure the light directing function display device has been granted.

In order to achieve the above object, the light directing function display device of the present invention includes ultraviolet light, visible light, infrared light, etc., irradiated from sunlight, ultraviolet light, visible light, incandescent lamps, fluorescent lamps, LED lamps, etc. , Infrared rays, and the like, colored light sources of electric and electronic display devices, and ultraviolet light, visible light, infrared light, etc., which are reflected and irradiated to objects, ultraviolet light such as light bulbs, incandescent lamps, fluorescent lights, LED lamps, Including infrared rays etc., it consists of a receiving light source.

Further, the light receiving body of the light directing function display device composed of two or more light receiving bodies is a modeling light receiver, a colorless transparent material light receiving body, a modeling light receiving body, a colorable transparent material light receiving body, a modeling light receiving body, Color-received translucent material receiver, molding light-receiving color translucent material-receiver material, molding light-receiver, colorless opaque material-receiving material, molding light-receiver, color opaque The light receiving body of the light directing function display device comprising at least one of a light receiving material and the like, and a light receiving function display device composed of two or more light receiving bodies is a light receiving body of a polyhedron, a mixed light receiving body of a polyhedron and a curved body, a light receiving body of a curved body, A mixed light receiver of a spherical body and a spherical body, a light receiver of a spherical body, a mixed light body of a spherical body and a polyhedron, a polyhedron and a curved body, or a mixed light body of a spherical body Or it may be made later.

In addition, the light receiver of the light directing function display device composed of two or more light receivers is composed of any one or more of a soft light receiver, a semi-soft light receiver, a radius light receiver, and a hard light receiver. A coupling portion is formed in the configured light directing display device, and the coupling portion may be formed of groove coupling, adhesive bonding using adhesive, hot pressing bonding, bolt coupling, clasp coupling, pin coupling, and woven coupling.

In addition, if the shape of the coupling portion, a curved surface, a spherical surface and a multi-sided, spherical surface, the curved surface is composed of a shape, the light receiving body of the light display function display device composed of two or more light receiving body is a light-receiving body by curing the liquid material in the mold As forming

Among the liquid materials, there are transparent liquid materials without color, transparent liquid materials with color, translucent liquid materials without color, translucent liquid materials with color, opaque liquid materials without color, and opaque liquid materials with color. It consists of a specific functional liquid substance consisting of any one or more liquid substances.

In addition, the specific functional liquid material is cured by the molding frame, forming a molding light receiving body, and the shape of the molding frame and the molding light receiving body is composed of various patterns of a shape in which polyhedron, curved body, spherical body or polyhedron, curved body and spherical body are mixed with each other. .

In addition, the mold and the light receiving body are composed of two or more light receiving bodies, the light receiving body of the light directing function display device, etc., and the minimum length of one side of the light receiving body constituting the light directing function display device is nanometers ( nm) or more.

In addition, molding grooves, molding holes, etc., operated on the light receiving body of the light directing function display device composed of two or more light receiving bodies are formed to be deeply dug from the surface of the light receiving body. A planar shaped groove having an area and a hole formed through the light receiving body form a hole or the like, or a linear shape having a long area, and a planar shaped hole having a constant area.

In addition, the molding groove and the molding hole pass through two or more light receiving bodies constituting the light directing function display device, and are composed of the molding groove and the molding hole, and the shape of the molding groove and the molding hole is multifaceted, curved, spherical or manifold, curved, spherical. The shapes may be represented by shapes of various patterns mixed with each other.

In addition, the light receiving body of the light directing function display device composed of two or more light receiving bodies is a molding light receiver which forms an inner space in the light receiving body, a molding light receiving body which forms an internal vacuum space in the light receiving body, Molded receiver that injects specific functional liquid material into molded inner space of receiver, Molded receiver that injects specific functional liquid material into molded inner space of receiver and filled one or more receivers, Molded receiver It forms a molding receiver with one or more receivers filled in its internal vacuum space.

In addition, the shape of the shaped light receiving body is characterized by consisting of various patterns in which polyhedron, curved body, spherical body and polyhedron, curved body, spherical body, and the like are mixed with each other, and the light receiving body has a light directing function composed of two or more light receiving bodies. Characterized in that the light receiving body of the display device.

In addition, the modeling receiver may be a modeling receiver that combines two or more receivers having different materials and colors that constitute the light directing function display device.

In addition, the light receiving body of the light directing function display device composed of two or more light receiving body is to form a molding light receiver by cutting and processing the molding light receiver, the specific functional liquid material cured in the molding frame,

The specific functional liquid substance injected into the operation mold, which repeats the stop, movement and rotation in various patterns, is cured sequentially over time in a repetitive dynamic state, and the molding is cut and processed to display a regular or irregular wave shape. A specific functional liquid material is injected into an action mold that forms a light receiving body, and stops, moves, and rotates in various patterns, and one or more light receiving bodies are filled in. Regularly or irregularly waved and one or more light receivers filled in order to stop, move, and rotate in various patterns to display the operation shape of regular or irregular light receivers. Forming a molding receiver, and cutting and processing a receiver formed with a pattern part to form a molding receiver. .

In addition, a molding receiver can be formed by cutting and processing a molding groove formed in a receiver, etc. constituting the light directing function display device, a receiver which is cured by filling a specific functional liquid material in the molding hole, and the shape of the molding receiver. The polyhedron, curved body, spherical body and polyhedron, curved body, spherical body, etc. may be formed in a variety of patterns mixed with each other, and the molded photoreceptor may be a photoreceptor of a light directing function display device composed of two or more photoreceptors.

In addition, a pattern is formed in the light receiver of the light directing function display device composed of two or more light receivers, and the shape of the pattern may be embossed, engraved, uneven, groove, hole, or protrusion.

In addition, an embossed pattern, an intaglio pattern, an uneven pattern, a groove pattern, a hole pattern, and the like formed through two or more light receiving bodies constituting the light directing function display device may be obtained.

And the shape of the pattern portion, such as the pattern may be formed in the shape of various patterns mixed with a surface, a surface, a surface and a surface, a surface, a surface, a sphere.

In addition, an auxiliary light can be provided in a light receiving body of a light directing function display device composed of two or more light receiving bodies, and an auxiliary light is embedded in a part of the light receiving body or in the light receiving body, or two or more unsealed light receiving bodies. Non-embedded auxiliary light installed between the, may be made of a space-embedded auxiliary light installed in the molded interior space, such as a light receiving body.

In addition, the auxiliary light may be made of incandescent lamps, fluorescent lamps, LED lamps or colored incandescent lamps, fluorescent lamps, LED lamps and the like coated with a light bulb or lamp.

In addition, a light directing function display device composed of two or more light receivers includes a three-dimensional light receiver having a point shape at a viewing angle of 360 degrees up, down, left, and right, a three-dimensional light receiver having a linear shape, and a surface shape. It consists of a planar three-dimensional light-receiving member consisting of a planar three-dimensional light-receiving member consisting of a three-dimensional, three-dimensional light-receiving member consisting of a compound, and a three-dimensional light-receiving member.

The shape of the light directing function display device is characterized by consisting of various patterns in which polyhedron, curved body, spherical body and polyhedron, curved body, spherical body, etc. are mixed with each other, and the points, lines, and planes of the light directing function display device. A pattern groove, such as a molding groove, a molding hole, and a coupling portion are formed in a multi-stereo light receiving body.

Two or more light receivers constituting the light directing function display device convert the light energy irradiated from the light source to form electromagnetic waves of the emitted light such as the light receiver, and thus the refractive modulated transmission beam, the refractive modulated transmission beam, Color-sensitized transmitted light of a light-receiver, refractive-type modulation-transmitted light of colored light, color-transmitted modulated light of colored light Modulated reflections, refraction-modulated reflections and color-sensing reflections of light-receivers, refraction-modulated reflections of colored light, refraction-modulated reflections of colored light and color-displayed reflections of colored light, refraction-modulated reflections of ultraviolet light, Infrared refraction modulated reflection infrared light.

In addition, when the light receiving body of the light directing function display device composed of two or more light receiving bodies is in a dynamic state in which it stops, moves, and rotates by external physical force, the light energy irradiated from the light source is converted to the light receiving body. Forming electromagnetic waves of the emitted light such as split rays of refraction modulated transmission beams, refraction modulated transmission beams, and color display transmission rays of light-receiving members; split rays of colored light modulation beams and colored rays of refraction Separated rays of modulated transmitted light and color-sensitized transmitted light of received light, Separated rays of refracted modulated reflection light, Separated rays of refracted modulated reflection light and Color-coded reflected light of photoreceptor, Separated rays of refractive-type modulated reflected light of colored light, Colored It forms a refractive modulated reflected ray of light and a separated ray of a color display reflecting ray of the light receiver 2.

In addition, the light energy irradiated from the light source is converted to form electromagnetic waves of the emitted light such as the light receiving body, transmitted through the light receiving body of the light directing function display device, and contacted with a narrow gap or corner of two or more light receiving bodies. Diffracted light of transmitted light generated when the electromagnetic wavefront of the emitted light such as light is distorted, or the distorted electromagnetic wave surface and the like interfere with each other, and

Occurs when the electromagnetic wavefronts of the emitted light such as the light receivers are distorted or the distorted electromagnetic wavefronts interfere with each other by reflecting two or more light receivers of the light directing function display device and contacting a narrow gap or a corner of the two or more light receivers. To form diffracted light of reflected light.

The light energy irradiated from the light source is converted to form electromagnetic waves of the emitted light such as the light receiving body, and the transmitted light passing through the two or more light receiving bodies of the light directing function display device is dispersed for each wavelength band to form multicolor diffused light or transmitted. The light beam repeats total reflection for each wavelength band to form multicolor diffused light.

Characterized in that the reflected light reflecting two or more light receivers of the light directing function display device is dispersed by wavelength band to form multi-color dispersed light, or the reflected light repeats total reflection by wavelength band to form multi-color distributed light. The light energy irradiated at is converted to form electromagnetic waves of emitted light such as a light receiving body, and any of the types of transmitted light passing through at least two light receiving bodies of the light directing function display device and the types of reflected light reflecting at least two light receiving bodies. And cross-beams, which are collided or cross-intersected with one or more transmitted or reflected beams, or the like, to be mixed and displayed. The light energy irradiated from the light source is converted to form a light directing function display device. By the light directing function display device which consists of electromagnetic waves of emitted light, such as two or more light receiving bodies Formed display light (visible light) or non-display light (ultraviolet light, infrared light), etc., formed by technical operation of two or more light receivers constituting the light directing function display device and formed on two or more light receivers By technical operation of the coupling part with the pattern part of the groove molding hole pattern,

By varying the refractive index, or by modulating reflection and transmissive, the light is irradiated from the light source by converting light energy irradiated from the light source. 1) Display light (visible light) or non-display light (ultraviolet rays, infrared rays) of one unit emission light having a light directing function, consisting of electromagnetic waves of emission light such as two or more light receiving bodies constituting each other, collide with each other or multiple association Or spectroscopically, to achieve a light directing function,

The light energy irradiated from the light source is converted, and is generated by the light directing function display device, which is composed of electromagnetic waves of emission light such as two or more light receiving members constituting the light directing function display device, Display light (visible light) or non-display light (ultraviolet light, infrared light) and light energy irradiated from multiple light sources are converted into a combination of electromagnetic waves of emitted light such as two or more light receivers constituting the light directing function display device. Combinations of display light (visible light) or non-display light (ultraviolet light, infrared light), etc., of one unit emission light having a light directing function are continuously collided with each other, or multiplexed or spectroscopically, to achieve a light directing function. ,

Such as a light receiving body, which stays in or displayed inside or outside of two or more light receiving bodies constituting the light directing function display device, or until a destructive interference phenomenon or kinetic energy is extinguished to its fullest extent. It forms the shape by electromagnetic waves, etc. of emitted light.

In addition, the light directing display device comprising two or more light receiving bodies includes a light receiving body, a molding frame and a specific functional liquid material, a coupling part and a molding groove, a molding hole, a glyph part, an auxiliary light, and a dot, line, and face. Manipulation techniques such as manipulating the characteristics of materials such as a light receiving body of a complex three-dimensional shape, color, scale, volume and shape, position variation, etc., or combining or mixing and distributing the manipulated features, etc. Thereby, the light directing function display device is not limited to a certain shape, and is free of polyhedrons, polyhedrons and curved bodies, spherical bodies, spherical and spherical bodies, spherical bodies, spherical bodies and polyhedrons, polyhedrons and spherical bodies, and spherical bodies. Characterized in that can be made in shapes and shapes.

 And a light directing function display device composed of two or more light receivers, which includes a light receiver, a mold, and a specific functional liquid substance, a coupling part, a molding groove, a molding hole, and a glyph part corresponding to a molding light receiver and a molding light receiving body. Combining the characteristics of materials such as auxiliary light, dot, line, plane, and light-receiving body in the shape of complex, or color, scale, volume and shape, positional variation, etc. Or a light directing function display device made by an operation technique such as mixing, distributing or distributing, is first designed and operated, and subsequently displayed in association with the light directing function display device, and the light energy irradiated from the light source is Display of one unit emission light of the light directing function generated by the light directing function display device which is converted and constituted by electromagnetic waves of emission light such as two or more light receiving bodies constituting the light directing function display device. Light rays (visible rays) or non-display rays (ultraviolet rays, infrared rays) and light energy irradiated from a plurality of light sources are converted and combined with electromagnetic waves of emitted light such as two or more light receivers constituting the light directing function display device. A combination of one unit output light of the light directing function, the display light (visible light) or the non-display light (ultraviolet light, infrared light), etc., generated by the light directing function display device, continuously collides with each other, or Electromagnetic waves of the emitted light such as two or more light receivers that form the light directing function display by converting the light manipulation irradiated from the light source and the line manipulation technique of the light directing function display device, which are multiplexed or spectroscopically, to produce a light directing function The display light (visible light) or non-display light (ultraviolet light, infrared light) of the unit emission light of the light directing function consisting of the light and the light energy irradiated from the multiple light sources 2500 are converted, Constituting the directing function display device which is a combination of an electromagnetic wave of the emitted light, etc. can be two or more housing,

A unit light having a light directing function, a combination of the above-described display light (visible light) or non-display light (ultraviolet light, infrared light), etc., which continuously collides with each other, or multiplexes or spectroscopy to form a light directing function. Designing and manipulating the directing function, the light receiving body, the molding frame and the specific functional liquid material, the joining part and the molding groove, the molding hole, the pattern part, the auxiliary light, Manipulating material properties, such as point, line, surface, and complex three-dimensional light-receiving members, color, scale, volume and shape, and positional variations, or combining or mixing and distributing the manipulated features, etc. The light directing function display device is varied by a post-operation technique of the light directing function display device, which is first designed and operated on the light directing function display device, which is made by an operation technique. It can be manipulated.

In addition, the light directing function display device composed of two or more light receivers can manipulate the color, shape and shape of light with at least two light receivers 2.

In addition, at least two light receivers constituting the light directing function display device are made of any one of the light receivers, and are made of a molded light receiver which is cured and formed by manipulation of a specific functional liquid material by a mold. Forming grooves, sculptural holes, glyphs, which are displayed on at least two light receiving bodies constituting the light directing function display device; , A multi-sided surface, a spherical surface or a multi-sided surface, a spherical surface, a curved surface, etc. are displayed in the shape of a variety of patterns mixed with each other, and the auxiliary light installed in at least two light receiving members forming a light directing function display device Characterized in that the color of the light energy irradiated from the light source, and the electrons of the emitted light emitted from one of the two light receivers When the color of the wave and the electromagnetic wave of the emitted light of the color of the emitted light emitted from another number of light receivers collide with each other, a color matching phenomenon, which is a combination of light, is achieved and the color of the light is different. The color rendering function of the third light formed by the electromagnetic wave of the emission light of the three dimming light, and when the light energy irradiated from the light source enters at least two light receiving members constituting the light directing function display device, the light directing function At least two photoreceptors constituting the display device react to form electromagnetic waves of emission light having the colors of the two photoreceptors, thereby displaying all colors of light having different wavelengths in the visible light source, and producing light. Auxiliary light, which is installed in at least two light-receiving members forming a function display device, forms an electromagnetic wave of emitted light, and light energy irradiated from the light source is converted to provide a light display function display device. The display light (visible light) or non-display light (ultraviolet light, infrared light) of one unit emission light of the light directing function generated by the light directing function display device, which is composed of electromagnetic waves of emitted light such as two light receiving bodies. And generated by the light directing function display device, wherein light energy or the like irradiated from a plurality of light sources is converted, and is composed of a combination of electromagnetic waves of emitted light such as two numbers of light receivers constituting the light directing function display device. Combination of one unit light of the light directing function, the above-described display light (visible light) or non-display light (ultraviolet light, infrared light), etc., continuously collides with each other, or multiplexes or spectroscopy to achieve the light directing function At least two, comprising the coupling portion, forming a light directing function display device to form at least two light receiving body, thereby constituting the light directing function display device The inside of at least two light receivers, such as the number of light receivers, staying inside or displayed, or canceling out interference or kinetic energy to its full capacity Or it is characterized by being able to operate what is displayed or displayed in the exterior.

A light directing function display device composed of two or more light-receiving members reacts to ultraviolet rays and infrared rays, converts incident light rays of ultraviolet light emitted from the light source, and is characterized by higher refractive-modulation-transmitted light rays, thereby making it invisible to the eyes. It is characterized in that it stays inside or outside of the light receiving body of the light directing function display device with the refraction-modulated transmitted light of.

In addition, the light irradiated from the light source is formed by forming a modeling hole or a hole pattern corresponding to the ultraviolet wavelength band, which is invisible due to the characteristics of the ultraviolet light, and is formed in the light receiving body of the light display function display device. When the electromagnetic waves and the like of the emission light such as the light receiving body having the color of the visible ray converted into the electromagnetic waves of the emission light such as the light receiving body collide with each other, or are multi-coupled or mixed, the light energy emitted from the light source is emitted from the light receiving body. The electromagnetic wave of the emitted light, such as the light receiving body having the color of the visible ray band converted into the electromagnetic wave of the light, is not visible to the inside or outside of the two or more light receiving bodies 2 constituting the light directing function display device. Characterized in that the spatial division of light while achieving the effect of the spectroscopically distinguished,

Characterized in that it forms a refractive-modulated transmission beam of ultraviolet light which is a unit output light of multiple ultraviolet rays.

The incident light rays of the ultraviolet rays irradiated from the light source are converted to form upper refraction modulated reflection beams, which are invisible to the refraction modulated reflection rays of ultraviolet rays, inside or outside the light receiving body of the display device. It is characterized by staying.

In addition, it is invisible due to the characteristics of ultraviolet rays, and by forming molding grooves or groove patterns corresponding to the ultraviolet wavelength band in the light receiving body of the light display function display device, and reflecting only the invisible multiple ultraviolet rays, When the light energy irradiated from the light waves emitted by the light beams such as the light beams converted into the electromagnetic waves of the light beams, such as the light beams, collide, multi-couple, or mix with each other, Refraction modulation of ultraviolet light, which is a unit emission light of multiple ultraviolet rays, characterized in that the spatial division of light is achieved while forming an effect of spectroscopy distinguished from multiple ultraviolet rays invisible to the upper eye from inside or outside two or more light receiving bodies. It forms reflected light.

In addition, the infrared light irradiated from the light source is invisible due to the characteristics of the infrared light, and the infrared light irradiated from the light source is irradiated from the light source to two or more light receivers constituting the light directing function display device. When the heated air of the front rises due to characteristics such as heat radiation emission such as infrared rays, which are invisible while multiplying each other or electromagnetic waves of the emitted light of the light-receiving body formed by converting light energy, The electromagnetic wave of the light emitted from the light receiver inside or outside is optically distorted by the distorted refraction phenomenon in the air surface to achieve a specific phenomenon, such as haze, to achieve a light directing function.

A light directing function display device composed of two or more light receivers comprises a light directing function display device consisting of two or more light receivers composed of ultra-small nanoparticles. Or two or more light receivers composed of micro-nanoparticles, forming grooves, molding holes and patterns, and two or more light receivers composed of micro-nanoparticles are formed by the mold of micro-nanoparticles. Two or more photoreceptors comprising a modeling receiver of micro-nanoparticles formed by curing, and the modeling receiver is formed of micronanoparticles, and forming a light directing function display device in the form of dots, lines, planes, and composites. It is characterized by consisting of these ultra-small nanoparticles.

In addition, the light directing function display device composed of two or more light receivers is characterized in that electrical, electronic and mechanical devices can be attached to two or more light receivers constituting the light directing function display device. When electrical, electronic and mechanical devices, etc. attached to two or more light receiving bodies constituting the same move or rotate in the front, rear, up, down, left and right directions, or make dynamic fluctuations of stopping, moving and rotating, The two or more light receivers constituting the light directing function display device also make dynamic fluctuations, or the electromagnetic waves of the emitted light such as the light emitters which make the dynamic fluctuations interfere with each other to form regular or irregular dynamic fluctuations.

In addition, by the electric, electronic and mechanical devices attached to two or more light receivers constituting the light directing function display device, the light energy irradiated from the light source, which is made of electromagnetic waves of the emitted light such as the light receiver, which is dynamically changed, is converted. Display light (visible light) or non-display light of one unit emission light of the light directing function, which is generated by the light directing function display device, which is composed of electromagnetic waves of emitted light such as two or more light receiving members constituting the light directing function display device The light source is caused by electric, electronic and mechanical devices, etc. (ultraviolet rays, infrared rays) collide with each other, or multiple associations or spectroscopy to achieve a light directing function in dynamic fluctuations and attached to two or more light receivers constituting the light directing function display device. The electromagnetic waves of the emitted light such as the light receiving body converted from the light energy irradiated from the light are continuously incident or multi-combined. It consists of electromagnetic waves of emitted light, such as a light receiving body, which are highly dynamic.

In addition, the light energy irradiated from the light source is converted to generate one of the light directing functions, which is generated by the electromagnetic wave of the light emitted by the light receiving body, which is composed of electromagnetic waves of the light emitted by the two or more light receiving members constituting the light directing function display device. It consists of electromagnetic waves of emitted light such as visible light (visible light) or non-display light (ultraviolet light, infrared light) of unit emission light and a light receiving body which makes dynamic fluctuations.

Further, the light directing function generated by the electromagnetic waves of the light emitted by the light source, such as the light energy emitted from the light source, is converted into a combination of the electromagnetic waves of the light emitted by the two or more light receivers constituting the light directing function display device. Combinations of one unit emission light, or more than one display light (visible light) or non-display light (ultraviolet light, infrared light) are continuously collided with each other, or multiplexed or spectroscopically to constitute a light directing function display device. It is a function of directing light on dynamic variability until it remains or is displayed, internally or externally, such as two or more light-receiving elements, or until the destructive interference phenomenon or kinetic energy is lost to its function.

When various technical manipulation techniques of the above-described light directing function display device are utilized, it is a solution to the problem that the light directing method and the like of the light directing function display device of the present invention achieve multi-dimensional or high-dimensional creativity. .

According to the above description, the light directing function display device according to an embodiment of the present invention requires artificial driving energy when the light directing function display device utilizes light energy of ultraviolet light, visible light, infrared light, or the like as a light source. Do not In addition, there is an effect of the invention that the light directing function display device can exhibit the effect of sufficient light directing function by the light energy using the ultraviolet light, visible light, infrared light, etc. of the sunlight as a light source indoors and outdoors.

In addition, the complex stereoscopic shape of light that can be represented by a light directing function display device composed of two or more light receivers is technically manipulated in various and multidimensional manners. There is an inventive effect that can express a multi-dimensional shape in multiple dimensions.

In addition, the electromagnetic wave of the emitted light of the light-receiver converted by the light energy irradiated from another light source, which is directly transmitted to the complex solid shape of the upper light or displayed alternately, is canceled by forming a band-shaped beam while repeating electromagnetic radiation. Until the interference phenomenon or the kinetic energy disappears, the linear light beam is displayed by the display rays such as electromagnetic waves of the emitted light of the light receiver while repeating the refraction, transmission, and reflection between the two or more light receivers constituting the light directing function display device. While expressing, the upper and the complex three-dimensional shape of the light and the electromagnetic wave of the emitted light of the linear light-receiving object interlock with each other, so that the cloud shape of the natural phenomenon and the shape of the complex linear light displayed between the cloud and the cloud The invention has the inventive effect of expressing the combined shape of high-dimensional complex combination of light and linear spectroscopy in various colors.

In addition, a light directing function display device composed of two or more light receiving members forms ultraviolet rays and forms a modeling hole or a hole pattern corresponding to the ultraviolet wavelength band in the light receiving body of the light directing function display device, thereby providing multiple invisible ultraviolet light. By transmitting only the light, when the light energy irradiated from the light source is converted into the electromagnetic wave of the emission light such as the light receiver, the electromagnetic wave of the emission light such as the light receiver having the color of the visible light beam collides with each other, or multiplexes or mixes with each other. In the inside or outside of two or more light receivers constituting the display device, there is an inventive effect that can express the spatial division of light, etc. while achieving the effect of spectral display distinguished from multiple ultraviolet rays or the like that are not visible to the upper eye. .

In addition, a light directing function display device composed of two or more light receiving bodies forms a slit or groove pattern corresponding to an ultraviolet wavelength band in the light receiving body of the light directing function display device by using ultraviolet rays, thereby forming a plurality of invisible multiplexes. By reflecting only the ultraviolet rays, the light energy emitted from the light source is converted into the electromagnetic waves of the emitted light such as the light receiving body. Inventive effect capable of expressing spatial division of light, etc., while forming the effect of spectral display distinguished from multiple ultraviolet rays which are not visible to the upper reflection from the inside or outside of two or more light receiving bodies constituting the function display device There is.

In addition, the light directing function display device composed of two or more light receivers uses infrared light, and the infrared light or the like irradiated from the light source is applied to the two or more light receivers constituting the light directing function display device. When heated air in contact with the inside and outside of the light receiver rises due to characteristics such as heat radiation emission, such as invisible infrared rays, by colliding, multiplexing, or mixing with electromagnetic waves and the like of the emitted light of the converted light receiver In the interior or exterior of the light directing function display device 1, the electromagnetic waves of the emitted light of the light receiving body 2 are optically distorted in the air surface in contact with each other, thereby forming a specific phenomenon such as haze, thereby achieving a light directing function. There is an effect of the invention that can express things.

In addition, according to the present invention, as an optical display function display device of the nanoparticles, it has the effect of forming an optical illusion such as light generated in a transparent space.

In addition, according to the present invention, while the above-described effects of the invention are implemented, it is possible to display dynamic phenomena of light having various colors such as dynamic movement of water of natural phenomena, or falling waterfall of natural phenomena. It is possible to display dynamic phenomena of light with various colors that make up the dynamic movement of the phenomenon.

In addition, the light directing function display device composed of two or more light receivers includes electric, electronic, and mechanical devices attached to two or more light receivers constituting the light directing function display device in front, rear, up, down, left, and right directions. One unit light and one unit light of the light directing function by the effect of the split light generated by the light directing function display device when moving or rotating, or when performing dynamic fluctuations of stopping, moving and rotating. When operating a light directing function display device comprising a light or more, characterized in that the display light (visible light) is separated, while the above-described invention effect is implemented, the light and the light is separated in a certain space, There is an inventive effect that can indicate what constitutes a feature of spatial division of light.

In addition, the received light source is irradiated with light energy at various viewing angles, and the light receiving body constituting the light directing function display device has various colors, various textures and various shapes, and a molding groove operated on the light receiving body. , The shape of the molding hole, the shape of the pattern, etc., characterized in that can be made in a variety of, and when the light directing function display device of the present invention made of a variety of roles of the auxiliary light installed in the light receiver, etc. in various patterns, the light is produced In the interior or exterior of the functional display, the light can collide with each other, be combined, or be spectroscopic to freely create a multidimensional or high-dimensional light shape, such as watching fireworks.

1 is a schematic perspective view and a cross-sectional view of a light directing function display device according to an embodiment of the present invention.

FIG. 2 is a schematic exploded perspective view of the light directing function display device shown in FIG. 1.

3 is a schematic cross-sectional view and an exploded perspective view of the light directing function display device shown in FIG.

4 is a schematic cross-sectional view and an exploded cross-sectional view of the light directing function display device shown in FIG.

5 is a schematic cross-sectional view and an exploded perspective view of the light directing function display device shown in FIG.

Figure 6 is a schematic view showing a heat compression bonding process for implementing a light directing function display device according to the present invention.

7 to 16 are schematic use state diagrams of a molded light receiver for implementing a light directing function display device according to the present invention.

17 to 20 are schematic configuration diagrams of a point, a line, a surface, and a complex stereoscopic shape for implementing a light directing function display device according to the present invention.

21 and 22 are schematic use state diagrams of shapes and shapes of display light (visible light), non-display light (ultraviolet light, infrared light), etc., of the unit light output light of the light directing function display device according to the present invention; .

Fig. 23 is a schematic diagram showing the state of use of the auxiliary light installed in the light directing display device according to the present invention and the shape and shape of the auxiliary light including visible light (visible light) and non-display light (ultraviolet light, infrared light). .

24 is a schematic view showing an embodiment in which the light directing function display device according to the present invention is implemented as a component material of a lighting device.

FIG. 25 is a schematic diagram illustrating an embodiment in which a light directing function display device according to the present invention is implemented as an optical display device; FIG.

Figure 26 is a schematic diagram showing an embodiment in which the light directing function display device according to the present invention is implemented as a synthetic yarn of textiles.

27 to 29 are schematic diagrams showing an example in which the light directing function display device according to the present invention is used as a component material of an image display.

Advantages and features of the present invention, and methods for achieving them will be apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure may be made thorough and complete, and to fully convey the spirit of the present invention to those skilled in the art. In the drawings, the thicknesses of layers and regions are exaggerated for clarity.

Terms such as first and second may be used to describe various components, but the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly the second component may be referred to as the first component.

The terms top, bottom, top, bottom, or top, bottom, etc. are used to distinguish relative positions in the component. For example, in the case of naming the upper part on the drawing as the upper part and the lower part on the drawing for convenience, the upper part may be called the lower part and the lower part may be named the upper part without departing from the scope of the present invention. .

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not. In addition, in order to achieve the light directing function display device 1 of the present invention, procedural technical methods or terms and the like, which are named and named, should be interpreted as technical methods or terms in which the right is invalid or widely known, and the technical It should be interpreted that the method or terminology does not infringe other rights.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

The light directing function display device 1 composed of two or more light-receiving members 2 includes ultraviolet rays, visible rays, infrared rays, and the like of the sunlight to be irradiated, and is a light bulb, an incandescent lamp, a fluorescent lamp, an LED lamp, or the like that is irradiated. UV light, visible light, infrared light, and colored light applied to light bulbs, incandescent lamps, fluorescent lamps, LED lamps, and the like, and the colored light of an electric and electronic display device to be irradiated; Ultraviolet light, visible light, infrared light, and the like, which are irradiated and irradiated, and includes ultraviolet light, visible light, infrared light, etc. The kind of electromagnetic wave (light energy) of the direct and indirect light including the colored light of the electric and electronic display device which is reflected and irradiated to it is referred to as a receiving light source (abbreviated as light source 2500).

In addition, in the case of a light directing apparatus using visible light as an accommodation light source (light source 2500), in order to expand the function of a more accurate accommodation light source (light source 2500), ultraviolet rays and infrared rays are accommodated in the accommodation light source (light source ( 2500).

Light energy irradiated to the light source 2500 and incident on the light receiving body 2 of the light directing function display device 1 causes the light receiving body 2 of the light directing function display device 1 made of a material to react. The material constituting the light-receiving body 2 of the light directing function display device 1 is influenced as light energy, and the light energy (ultraviolet light, visible light, Infrared rays), thereby absorbing (natural law); In the case of a material that receives (light) energy from the outside (the electrons around the nucleus in the atoms that make up the material move to an energy level where they can have more energy, forming an excited state).

In addition, since the electrons in the excited state are unstable, they have a characteristic of returning to a stable ground state while releasing energy again. At this time, the energy equal to the difference between the energy in the excited state and the energy in the excited ground state is spontaneous emission in the form of electromagnetic waves, corresponding to the energy difference. The principle that light is generated in the wavelength band, and all objects have heat, and thus, thermal radiation emission, and then emits electromagnetic waves composed of light according to the temperature), optical characteristics By the light energy composed of the electric field and the magnetic field of the irradiated optical image of the light source 2500, the two or more light receivers 2 of the light directing function display device 1 made of the material are used to emit light of the light receiver 2. Interaction of optical objects with light, emitting light by electromagnetic waves, and forming various types of light, such as refraction, scattering, transmission, reflection, etc., generated when the light is in contact with the light receiving body 2, etc. By it made as light directing features.

The light directing function is characterized in that the light directing function is performed by operation of two or more light receiving bodies 2 constituting the light directing function display device 1, and the light energy irradiated from the light source 2500 is converted. While the electromagnetic waves and the like of the emitted light of the multiple light receivers 2 constituting the light directing function display device 1 interfere with each other, the color and shape of the light are embodied to be multi-dimensional or non-dimensional multicolored, various multiple The artificial harmony and non-harmonic characteristics of the light, which are displayed in a regular shape or irregular patterns as a shape of light or as a change in light properties, are fused to each other, resulting in a high degree of creative creativity in technology. It is characterized in that the operational technical features of the light generated or extinguished are combined to form the shape.

In addition, the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2 is a modeling light receiver 660, which is a light receiving body 201 and a modeling body of transparent material without color. 660, a transparent light-receiving material 202, a modeling light receiving body 660, a colorless translucent light-receiving material 203, a modeling light receiving body 660, a color translucent translucent As a light-receiving member 204 of one material, a modeling light receiving body 660, as a light-receiving material 205, a modeling light receiving body 660 of a colorless opaque material, a light-receiving body 206 of a opaque material with a color The light receiving body 2 of the light directing function display device 1, which is composed of at least one of the above, and is composed of two or more light receiving bodies 2, is composed of a modeling light receiving body 660.

Further, a polyhedral light receiver 211, a polyhedron and a curved light receiver 212, a curved light receiver 213, a curved and spherical mixed light receiver 214, a spherical light receiver 215, a spherical body and A light directing function display device (1) comprising any one or more of a mixed polyhedron 216 of a polyhedron, a polyhedron and a curved body, and a mixed photon of a spherical body (217). ), The light receiver 2 consists of a modeling light receiver 660, the soft light receiver 221, the semi-soft light receiver 222, the light receiver 223, the hard light receiver 224. It consists of any one or more of the.

In order to achieve the light directing function display device 1, the configuration of two or more light receivers 2 is essential.

In addition, in order to achieve the configuration requirements of the light receiver 2, (201), (202), (203), (204), (205), (206), (211), (212), (213). Distinguish the characteristics, shape, shape, and material of the light receiver 2 such as 214, 215, 216, 217, 221, 222, 223, and 224 1 to 5 and 18 to 20 to display.

In FIG. 5, the schematic of the shape and shape of the light receiving body 2 is separately divided into (211), (212), (213), (214), (215), (216) and (217). It is specified as a notation.

In Fig. 18, examples of material classification of the light receiving body 2 are shown as reference numerals 221 and 222, 223 and 224 in Fig. 20, respectively.

Modeling light receiving body 660 constituting the light directing function display device 1, and 201, 202, 203, 204, 205, 206, 211, 212 The light receiving member 2 such as 213, 214, 215, 216, 217, 221, 222, 223, and 224 embodies a light directing function. As shown in FIG. 1 to FIG. 29, 2 or 2, 660, which are represented by the light-receiving member 2 according to the optional requirements for the following, are designated.

In principle, the light receiving body 2 constituting the light directing function display device 1 includes the modeling light receiver 660 and the modeling light receiver 6 described above.

As described above,

(201), (202), (203), (204), (205), (206), (211), (212), (213), (214), (215), (216), (217 ), (221), (222), (223), (224) configuration requirements of the light receiver 2,

In technical function,

Corresponds to the selective technique of the molding receiver 660 constituting the light directing function display device 1.

As described above,

(201), (202), (203), (204), (205), (206), (211), (212), (213), (214), (215), (216), (217 In the case of subdividing the requirements of the light receiver 2 such as 221, 222, 223, and 224, the modeling light receiver 660 of the light directing function display apparatus 1 Selective criteria can be variously met.

In the light directing function display device 1 composed of two or more light receiving bodies 2, a coupling part 3 is formed, and in the case of the groove coupling 301, the coupling part 3 is of the type shown in FIGS. Two or more light receivers 2 are etched on the light receiver 2 and formed in a groove shape that forms a shape that is deeper than the surface of the light receiver 2 or deeply recessed deeply. If the shape of the groove is formed in the engaging portion 3, and the shape of the groove is formed in the engaging portion 3, the surface, spherical or multi-faceted, spherical, the shape of the curved surface mixed with each other It is characterized by being displayed in the shape of a pattern.

In the case of the adhesive bond 302, the indication of the shape is shown in Figs. 1 to 5, and the light directing function display is performed by using an adhesive on two or more light receiving members 2, etc. of the light directing function display device 1 and the like. In forming an adhesive bond 302, characterized in that to combine two or more light receivers 2, etc. of the device (1),

The adhesive is composed of an adhesive material, and the light-receiving member 2 of the light directing function display device 1 can be manipulated with a liquid material or the like to form an adhesive to be composed of an adhesive.

In addition, in the case of the heat-compression bonding 303, the shape of the shape is shown in FIGS. 1, 4, 17, 18, 19, 20, 24, 25, etc.

 Fig. 6 shows the detailed view.

 303a and 306b of FIG. 6 are tools for forming the hot press bonding 303.

Heat-compression bonding 303 is characterized in that the pressure-sensitive adhesive surface generated by heating two or more light receivers 2 to each other to form a thermal compression bonding (303) to form a bonding portion 3, heating It is characterized in that the pressing surface is converted into a sticky soft form.

In the case of the bolt coupling 304, the representation of the shape is shown in Figs. 1 to 5, and a screw groove is formed in two or more light receiving members 2 of the light directing function display device 1, or two or more of them. It is characterized in that the bolt coupling 304 forming the coupling portion 3 is formed by rotating and joining the deeply recessed structural solid bodies having another female thread groove formed in the screw groove of the light receiver 2 to each other.

In the case of the clasp coupling 305, the display of the shape is shown in Figs. 1 to 5, the hook and the hook structure for coupling or connecting the two or more light receivers 2 of the light directing function display device (1) It characterized in that the hook and the locking structure to form a latch coupling 305 in the shape of engaging the two or more light receivers 2 of the light directing function display device (1).

In the case of the pin coupling 306, the marking of the shape is shown in Figs. 1 to 5, and the pin hole is formed in the thin long elongated pin and the two or more light-receiving members 2 to penetrate the pins. The light receiver 2 is characterized in that it forms a pin coupling 306 of the shape coupled to each other.

In the case of the woven coupling 307, the display of the shape is shown in Figs. 1, 3, 4, and 5, and two or more light receivers 2 of the light directing function display device 1 are woven together. Characterized by forming a woven coupling 307 to combine in shape.

In order to achieve the light directing function display device 1, the two or more light receiving bodies 2 are connected to (301), (302), (303), (304), (305), (306), (307), etc. It is necessary to form the coupling part 3 of.

Also, if the coupling structure such as (301), (302), (303), (304), (305), (306) or (307) forming the coupling portion (3) does not depend on a certain shape, the curved surface , Spherical or multi-faceted, characterized in that the spherical surface, the curved surface is displayed in the shape of various patterns mixed with each other.

In addition, a coupling structure, such as 301, 302, 303, 304, 305, 306, 307, which forms the coupling portion 3, is a light directing function display device 1. Characterized in that it can be made of the light receiver (2).

 In order to form the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2, a technique for forming a light receiving body 2 having a volume is required, and its technical creativity is further described. Also needs.

 The specific functional liquid material 650 is a compounding material for forming the shaped light receiving body 660 constituting the light receiving body 2 of the light directing function display device 1 and melting a substance or an artificial material in nature or the like. It is made by converting to a liquid material, colorless transparent liquid material (651), colorless transparent liquid material (652), colorless translucent liquid material (653), color translucent liquid material 654, the opaque liquid substance 655 without color, the opaque liquid substance 656 with color, etc., are made of any one or more liquid substances.

The specific functional liquid substance 650 is a specific substance which is a natural substance or an artificial substance in order to form the liquid substance of the above 651, 652, 653, 654, 655, and 656. It is characterized in that the specific functional liquid material 650 can be thickened by adding nanoparticles or pigment powder.

In addition, the specific functional liquid material 650 to achieve a variety of colors and textures,

Characterized in that it can be mixed repeatedly by recombination with a liquid material such as 651, 652, 653, 654, 655, 656.

The modeling receiver 660 is a technical operation in the process of injecting and then curing the specific functional liquid material 650 into the mold 400, characterized in that to form the molding receiver 660, (651 ), (652), (653), (654), (655), 656 made of any one or more of the liquid material, and (211), (212), (213), Among the volume shapes such as (214), (215), (216), (217), any one or more volume shapes, and among the materials such as (221), (222), (223), (224), It is made of any one or more materials.

 12 to 14, 16, and 29 show the shape of the shape and an example of a similar process and the like.

The light receiving body 2 of the light directing function display device 1 is composed of a modeling light receiver 6, a modeling light receiver 660, and the like.

(201), (202), (203), (204), (205), (206), (211), (by molding mold (400) or by blending techniques of specific functional liquid materials (650). 212), 213, 214, 215, 216, 217, 221, 222, 223, 224, and the like. have.

According to the manufacturing method of the molding light receiving body 660 made in the process of curing the specific functional liquid material 650 filled in the molding frame 400 by the molding frame 400,

(201), (202), (203), (204), (205), (206), (211), and (2), which are the selection criteria of the light receiver (2) constituting the light directing function display device (1). The light receiver 2 corresponding to 212, 213, 214, 215, 216, 217, 221, 222, 223, and 224 may be implemented. .

When the specific functional liquid material 650 filled in the molding frame 400 by the molding frame 400 corresponds to the liquid substance of 651, it is cured and consists of the molding light receiver 660. 201,

When the specific functional liquid material 650 filled in the molding frame 400 by the molding frame 400 corresponds to the liquid substance of 652, it is cured and consists of the molding light receiver 660. 202 can be achieved,

When the specific functional liquid material 650 filled in the molding frame 400 by the molding frame 400 corresponds to the liquid substance of 653, it is cured and consists of the molding light receiver 660. 203 can be achieved,

When the specific functional liquid material 650 filled in the molding frame 400 by the molding frame 400 corresponds to the liquid substance of 654, it is cured and made of the molding light receiver 660. 204 can be achieved,

When the specific functional liquid material 650 filled in the mold 400 by the mold 400 corresponds to the liquid substance of 655, it is cured and consists of the molding light receiver 660. 205 can be achieved,

When the specific functional liquid material 650 filled in the molding frame 400 by the molding frame 400 corresponds to the liquid substance of 656, it is cured and consists of the molding light receiving body 660, 206).

When the molding frame 400 is in the shape of a polyhedron, the light receiving body 211, which is composed of the molding light receiving body 660, may be formed, and when the molding frame 400 is in the shape of a mixture of a polyhedron and a curved body, A light receiver- 212, consisting of a molded light receiver 660,

When the molding frame 400 forms the shape of a curved body having a curved surface with a curved surface, the light receiving body 213, which is formed of the molding light receiving body 660, may be formed.

When the molding frame 400 forms the shape of a mixture of a curved body and a spherical body, it may form a light receiving body 214, which is composed of the molding light receiving body 660, and the molding frame 400 is formed of a spherical body having a circular spherical shape. In the case of a shape, a light-receiver 215, which is composed of a molding light receiver 660, may be formed, and when the mold 400 is in the shape of a mixture of spherical and polyhedrons, it is made of a molding light receiver 660. Can form a light-receiver-216,

When the molding frame 400 forms a mixture of a polyhedron, a curved body, and a spherical body, the light receiving body 217 may be formed of the molding light receiving body 660.

When the specific functional liquid material 650 filled in the mold 400 by the mold 400 is cured in a soft state in the process of restoring the curing method or the original properties, the molding light receiver 660 Consisting of, a light-receiving member-221,

The specific functional liquid material 650 filled into the mold 400 by the mold 400 is cured in a semi-soft state that is close to soft between soft and hard in the process of restoring the curing method or the original properties. May comprise a receiver- 222, consisting of a modeling receiver 660,

The specific functional liquid material 650 filled in the mold 400 by the mold 400 may be cured in a semi-hard state between soft and hard in the process of restoring the curing method or the original properties. In this case, the photoreceptor 223, which is composed of the molding receiver 660, may be formed, and the specific functional liquid material 650 filled in the molding mold 400 by the molding mold 400 may be hardened or inherently formed. In the process of restoring the properties of, when cured in a hard state, it can form a light-receiver-224, consisting of a molding light-receiver 660.

In addition, in order to form the light receiving body 2 constituting the light directing function display device 1,

Receptor 201, 202, 203, 204, 205, 206, 211, 212, 213, 214, 215, 216, 217, 221, 222, 223, 224, and the like are interoperable.

Receivers 201, 202, 203, 204, 205, 206, etc., Receivers 211, 212, 213, 214, 215 ), 216, 217, etc., any one or more of the characteristics, such as the receiver-(221), (222), 223, (224), etc. do.

Further, the light receivers 211, 212, 213, 214, 215, 216, 217, and the like, the light receivers 201, 202, 203, 204, 205, 206, any one or more of the characteristics, such as a light receiver-221, (222), (223), 224, 224 or any of the characteristics Should be nested.

Further, the light receivers-221, 222, 223, 224, and the like, the light receivers 201, 202, 203, 204, 205, 206, etc. Contains any one or more of the following characteristics, and includes any one or more of the following features: light- receiver 211, 212, 213, 214, 215, 216, 217, and the like. Should be nested.

In addition, in order to form the light receiving body 2 constituting the light directing function display device 1,

Receivers-201, 202, 203, 204, 205, 206, 211, 212, 213, 214, 215, 216 , 217, 221, 222, 223, and 224 should correspond to the plastic receiver 660.

In addition, in order to form the light receiving body 2 constituting the light directing function display device 1,

Specific function, in which the modeling light receiver 660 is composed of any one of liquid materials such as 651, 652, 653, 654, 655, and 656 It should be made of a liquid material (650).

In order to form the light receiving body 2 constituting the light directing function display device 1, the above-described properties and shapes of materials, shapes and colors, and all properties of materials must be combined or matched with each other.

In addition, the molding frame 400 may be made of the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2, and the molding frame 400 is not removed. The molding frame 400 and the specific functional liquid material 650 may be combined with each other to form the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2. In addition, the molding frame 400 is not sealed, as in the molding frame 400 of FIG. 29, and any one or more portions of the molding frame 400 may be opened like the molding frame 400 of FIG. 29. do.

The light directing function display device 1 composed of two or more light receivers 2 has a minimum length of one side of the light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2. (nm) or more.

The minimum length of one side of the light receiving body 2 of the light directing function display device 1 is nanometer so that the light directing function display device 1 composed of two or more light receiving bodies 2 can be made of ultra-small nanoparticles or the like. (nm) or more.

In addition, the functional characteristics of the light directing function display device 1, which is composed of ultra-small nanoparticles having a minimum length of one side of the light receiving body 2 of the light directing function display device 1 or more in nanometers (nm), To be broadly comprehensive,

For example, when a single light or a single photon composed of an electric field or a magnetic field irradiated from the light source 2500 is accommodated in the ultra-fine nanoparticle light directing function display device 1 for a certain period of time, Characterized by the functional characteristics capable of carrying light, single photons, etc., the functional characteristics,

In order to be displayed on the light directing function display device 1, it is characterized in that the light directing function display device 1 can be made of two or more light-receiving materials 2, etc. of a nano thin film multilayer.

In the light directing function display device 1 composed of two or more light receiving bodies 2, molding grooves 4, 44, molding holes 5, 55, and the like can be formed.

In the case of the molding groove 4 and the molding hole 5, an identification mark is schematically illustrated in FIGS. 1 to 5.

The molding groove 4 is characterized by being etched in the light receiving body 2 to form a shape that is deeper than the surface of the light receiving body 2 or is recessed deeply.

The molding hole 5 is etched in the light receiving body 2, and is represented by a hole or the like that penetrates the light receiving body 2 to form a shape, and the shape of the hole is linearly elongated to form a line shape. It is characterized in that the shape of the hole forms the shape of a wide hole forming a constant area.

The molding groove 4 and the molding hole 5 are formed by forming the shape and shape of the molding groove 4 and the molding hole 5 in detail on a part of the light receiving body 2 and displaying them on the light receiving body 2. It is characterized by a wider range than the pattern and a narrower range than the shape of the light receiver 2.

In addition, the shape of the molding groove 4 and the molding hole 5 is characterized in that the shape of the curved surface, the spherical surface or the multiple surface, the curved surface, the spherical surface is displayed in the shape of various patterns mixed with each other.

In the case of the molding groove 44 and the molding hole 55, an identification mark is schematically illustrated in FIGS. 1 to 5.

The molding groove 44 is characterized in that the molding groove 4 passes through two or more light receiving bodies 2 constituting the light directing function display device 1 to form the molding groove 44.

The molding hole 55 is characterized in that the molding hole 5 or the like passes through two or more light receiving bodies 2 constituting the light directing function display device 1 to form the molding hole 55. .

In the case of the molding groove 44 and the molding hole 55, there is a feature that can maximize the use effect when manufacturing the laminated light receiving body 2 of the multilayer thin film.

In addition, the molding groove 4, the molding hole 5, the molding groove 44, the molding hole 55, and the like are manipulated in various ways to display the functional characteristics on the light receiving body 2 for the purpose of light directing function. It can be characterized by.

In addition, if the shape of the forming grooves (4), (44), the forming holes (5), (55) is a curved surface, a spherical surface, or a multi-sided surface, the curved surface and the spherical surface are displayed in the shape of various patterns mixed with each other. It features.

Two or more light receivers, wherein the light directing function display device 1 composed of two or more light receivers 2 is displayed on the light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2. Modeling receiver 601 in which the light receiving body 2 of the light directing function display device 1 composed of (2) is formed to form an internal space in the light receiving body 2, and an internal vacuum space in the light receiving body 2; In the modeled light receiving body 602 and the modeling light receiving body 2 in which the functional specific liquid material 650 is injected into the molded internal space of the light receiving body 2, and in the molded internal space of the light receiving body 2. A molding receiver 604 in which a functional specific liquid material 650 is injected and one or more receivers 2 or the like is filled in, or one or more receivers 2 or the like in the molded internal vacuum space of the receiver 2. It is characterized by forming a kind of a molded receiving body 605 and so on.

In the case of the molded light receiver 601, its functional characteristics are shown in Fig. 7, and the inner space is formed in the light receiver 2 to form the molded light receiver 601.

In the inner space of the modeling light receiver 601, the light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the light receiver 2, so that the light directing function (1200), (1201), (1202), Refractory modulated transmitted rays 1300, 1301, 1302, 1303, etc., such as 1203, or the like.

When the molding receiver 601 repeats movement, rotation or stop, movement, rotation, etc. by external physical force, it is displayed separately from the molding receiver 601 (1400), (1401), (1402). ), (1403), (1500), (1501), (1502), (1503), and the like, the split light of the refractive modulation modulation beam and the refractive modulation modulation reflection beam is a display beam having a light directing function. It is characterized by forming the modeling light receiving body 601, characterized in that displayed on (601).

In addition, the shaped light receiving body 601 is characterized in that the polyhedron, curved body, spherical body, or a polyhedron, a curved body, a spherical body and the like are displayed in the shape of various patterns mixed with each other.

In addition, the modeling light receiving body 601 is characterized by forming a light receiving body 2 constituting the light directing function display device 1 composed of two or more light receiving bodies 2.

In addition, the modeling receiver 601 is characterized in that the modeling receiver 601 can be formed by sealingly bonding two or more receivers 2 constituting the light directing function display device 1 with each other.

In the case of the molded light receiver 602, its functional characteristics are shown on FIG. 8, and an internal vacuum space is formed in the light receiver 2 to form the molded light receiver 602. The light energy irradiated from the light source 2500 in the internal vacuum space is converted into the electromagnetic waves of the emitted light of the light receiver 2, such as (1200), (1201), (1202), (1203), etc. , Refracted modulated transmitted rays and refracted modulated reflected rays such as 1300, 1301, 1302, and 1303, or the like,

When the modeling light receiver 602 is repeatedly moved, rotated or stopped, moved, rotated, etc. by an external physical force, it is displayed separately from the modeled light receiver 602 (1400, 1401, 1402). ), (1403), (1500), (1501), (1502), (1503) and the like, and the split light of the refracted modulated transmitted light and the refracted modulated reflected light is a display light having a light directing function. It is characterized in that to form a molding light receiver (602).

Due to the nature of the internal vacuum space of the shaped light receiving body 602, the light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the light receiving body 2, so that the light directing function (1200), (1201), (1202) Refraction modulated transmission light and refraction modulated reflection light such as 1203, 1300, 1301, 1302, 1303, etc. due to the rapid luminous flux under vacuum Shapes of refractive modulated transmitted light and refractive modulated reflected light such as 1200, 1201, 1202, 1203, 1300, 1301, 1302, 1303, etc. Characterized in that is displayed,

(1400), (1401), (1402), (1403), (1500), (1501), (1502), (1503), and the like. Display light having a light directing function characterized by being displayed, characterized in that displayed on the modeling light receiving body 602, characterized in that to form a modeling light receiving body (602).

In addition, the shaped light receiving body 602 is characterized in that the polyhedron, curved body, spherical body, or a polyhedron, curved body, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the modeling light receiving body 602 is characterized by forming a light receiving body 2 constituting the light directing function display device 1 composed of two or more light receiving bodies 2.

In addition, the molding receiver 602 is characterized in that the molding receiver 602 can be formed by sealingly bonding two or more receivers 2 constituting the light directing function display device 1 to each other.

In the case of the molded light receiving body 603, its functional characteristics are shown on FIG. 9, and a closed inner space is formed in the light receiving body 2, and then a specific functional liquid material 650 is injected to make the molded water. It is characterized by forming the housing 603.

The specific functional liquid material 650 is injected into the interior space of the molding light receiver 603, and the color of the molding light receiver 603 is contrasted with the characteristic of the specific functional liquid material 650, or the specific color is different. Refraction modulated transmission light such as (1200), (1201), (1202), (1203), (1300), (1301), (1302), (1303), etc., in the functional liquid material (650). A display beam having a light directing function, which is characterized in that the refractive index of the refraction-modulated reflecting ray can be manipulated in various patterns, and is displayed on the modeling receiver 603 to form the modeling receiver 603. It features.

In addition, when the modeling light receiver 603 repeats movement, rotation or stop, movement, rotation, etc. by external physical force (1400, 1401), which is displayed separately from the modeling light receiver 603, Refraction-modulated transmitted light and refraction-modulated reflected light such as (1402), (1403), (1500), (1501), (1502), (1503) can be manipulated in a pattern having various refractive indices, etc. The display light beam having the light directing function, which is characterized in that it is displayed on the modeling light receiving body 603, characterized in that to form a modeling light receiving body 603.

In addition, the shaped light receiving body 603 is characterized in that the polyhedron, curved body, spherical body, or a polyhedron, curved body, spherical body and the like are displayed in the shape of various patterns mixed with each other.

In addition, the modeling light receiving body 603 is characterized by forming a light receiving body 2 constituting the light directing function display device 1 composed of two or more light receiving bodies 2.

In addition, the molding receiver 603 is characterized in that the molding receiver 603 can be formed by sealingly bonding two or more receivers 2 constituting the light directing function display device 1 with each other.

In the case of the molded light receiver 604, its functional characteristics are shown on FIG. 10, and an internal space is formed in the light receiver 2, and then a specific functional liquid material 650 and one or more light receivers 2 Injecting or filling the seal) to form a molding receiver 604 is characterized in that.

By injecting or filling the specific functional liquid material 650 and one or more light receivers 2 into the interior space of the molded light receiver 604, the specific functional liquid material 650 and When one or more light receivers 2 or the like repeats movement, rotation or stop, movement, rotation, etc. by the external physical force in the molding light receiver 604, the specific functional liquid material 650 and one or more light receivers (2) Dynamic movement and refraction modulated transmission such as (1200), (1201), (1202), (1203), (1300), (1301), (1302), (1303), etc. One or more light receivers 2, which display light rays and refractive-modulated reflecting rays, or dynamically move in a specific functional liquid material 650 injected in the interior space of the molded light receiver 604, are momentarily narrow. The light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the light receiving body 2, 1200, 1201, 1202, 1203, 1300, and 1301. , (130 2), diffraction light generated when the electromagnetic wave surfaces generated while contacting one or more light receivers 2 of the refractive-modulated transmitted light and the refractive-modulated reflected light such as (1303) are distorted or the distorted electromagnetic wave surfaces interfere with each other ( 1600), 1610, and so on,

When at least one light receiver 2 accommodated in the interior space of the shaped light receiver 604 has a shape of an optical prism and a triangular volume similar to that of a prism, the light energy irradiated from the light source 2500 is received by the light receiver 2. (E.g., an example of rainbow light), which is converted into electromagnetic waves of (1200) and (1300), and scattered light (examples of rainbow light) such as (1700) and (1710) of refractive-modulated reflected light (1200) and (1300). It is characterized by being displayed on the modeling light receiving body 604 by the display light of the light directing function, characterized in that to form a modeling light receiving body 604.

In addition, the light energy irradiated from the light source 2500 to the modeling light receiving body 604 is converted into electromagnetic waves of the emitted light of the light receiving body 2, and the refraction-modulated transmission beams of the light directing function (1200) and (1203) and When the refraction-modulated reflecting ray is displayed, or when the modeling light receiver 604 is repeatedly moved, rotated or stopped, moved or rotated by an external physical force, it is injected into the interior space of the molded light receiver 604. The specific functional liquid material 650 and the filled one or more light receivers 2, etc. (1400), which are displayed inside or outside the model light receiver 604 while colliding with each other in the interior space of the model light receiver 604 (( 1401, 1402, 1403, 1500, 1501, 1502, 1503, and the like, and the separated rays of the refracted modulated transmitted light and the refracted modulated reflected light are the display beams of the light directing function. It is characterized by being displayed on the modeling light receiver 604, It is characterized by forming the modeling light receiver 604.

In addition, the shaped light receiving body 604 is characterized in that the polyhedron, curved body, spherical body, or a polyhedron, a curved body, a spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the modeling light receiving body 604 is characterized by forming a light receiving body 2 constituting the light directing function display device 1 composed of two or more light receiving bodies 2.

In addition, the molding receiver 604 is characterized in that the molding receiver 604 can be formed by sealingly bonding two or more receivers 2 constituting the light directing function display apparatus 1 with each other.

In the case of the molded photoreceptor 605, its functional characteristics are shown on FIG. 11, and the inner space is formed in the photoreceptor 2, and then one or more photoreceptors 2, etc. are filled and closed. Forming an internal vacuum space is characterized by forming a molding light receiver (605).

By filling one or more light receivers 2 and the like into the internal vacuum space of the molding light receiver 605, one or more light receivers 2 and the like are made in the internal vacuum space of the molding light receiver 605. ) Repeats the movement, rotation or stop, movement, rotation, etc. by the external physical force, the dynamic movement of each other in the internal vacuum space of the molding receiver 605, (1200, 1201) Display refractive-modulated transmitted light and refractive-modulated reflected light, such as (1202), (1203), (1300), (1301), (1302), and (1303), or internal vacuum of the molded receiver 605. The light energy irradiated from the light source 2500 is converted into the electromagnetic wave of the light emitted from the light receiver 2 while one or more light receivers 2, which are dynamically moved above each other in space, form a narrow gap at a moment. Number of refracted modulated transmitted rays and refracted modulated reflected rays such as 1200, 1201, 1202, 1203, 1300, 1301, 1302, and 1303 The diffraction light 1600, 1610, etc. generated by contacting the sieve 2 and the like are distorted, or the distorted electromagnetic wave surfaces interfere with each other, and are instantaneously displayed by a fast luminous flux. When the one or more light receivers 2 and the like filled in the internal vacuum space of the 605 have a shape of an optical prism and a triangular volume similar to that of a prism, the light energy irradiated from the light source 2500 is received by the light receiver 2. Is converted into electromagnetic waves, and scattered light (examples of rainbow light) such as (1700) and (1710) of refracted modulated transmitted light such as (1200) and (1300) and refracted modulated reflected light are sequentially modeled. What is displayed instantaneously by the fast luminous flux in the internal vacuum space of the housing 605 is displayed on the molding receiver 605 with the display light of the light directing function, thereby forming the molding receiver 605 It is done.

In addition, when the molding receiver 605 repeats the movement, rotation or stop, movement, rotation, etc. by the external physical force, the one or more receivers 2 filled in the internal vacuum space of the molding receiver 605. Light energy emitted from the light source 2500 in contact with the one or more light receivers 2 filled in the internal vacuum space of the molding light receiver 605 is converted into electromagnetic waves of the emitted light of the light receivers 2, Separation beams of refractive modulated transmission beams and refractive modulation modulated reflection beams such as (1400), (1401), (1402), (1403), (1500), (1501), (1502), (1503), etc. Displayed in the internal vacuum space of the molding light receiver 605 through the one or more light receivers 2 filled in the internal vacuum space of the molding light receiver 605 or displayed outside of the molding light receiver 605 at a high speed. Is displayed on the modeling light receiving body 605 as a display light having a light directing function. Characterized in that forming.

In addition, the shaped light receiving body 605 is characterized in that the polyhedron, curved surface, spherical body, or a polyhedron, curved surface, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the modeling light receiver 605 is characterized by forming a light receiving body 2 constituting the light directing function display device 1 composed of two or more light receiving bodies 2.

In addition, the molding receiver 605 is characterized in that the molding receiver 605 may be formed by sealingly joining two or more receivers 2 constituting the light directing function display device 1 to each other.

(1200), (1201), (1202), (1203), (1300), (1301), (1302) to the above-described modeling receivers (601), (602), (603), (604), (605), etc. The mixed light beams 1800, in which the refractive-modulated transmission beams and the refractive-modulated reflection beams collide with each other or deflect each other, are displayed as display beams having a light directing function. , 602, 603, 604, and 605, the modeling receivers 601, 602, 603, 604, 605, etc. It is characterized in that it can be freely manipulated, including the features of the molding receivers 601, 602, 603, 604, 605, and the like described above.

As a modeling light receiving body 610, 611, 612, 613, 614, etc., which are made of the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2, and the like. In the case of the molded light receiver 610, its functional characteristics are shown on FIG. 12, and on FIG. 12, the cut (B) and the process flow chart (C) of the molded light receiver 610 are shown. It was.

In the case of the molding receiver 610, after the specific functional liquid material 650 is cured by injecting the specific functional liquid material 650 into the molding mold 400 by the molding mold 400, the molding mold 400 is used. It is characterized in that to form a processed light receiving body 610 by cutting the cutting (B), the molding light receiving body 610 of the polyhedron, curved, spherical or polyhedron, curved, spherical, etc. It is characterized by being displayed in the shape.

In addition, the molding frame 400 is characterized in that the polyhedron, curved surface, spherical body, or a polyhedron, curved surface, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the modeling light receiving body 610 is characterized in that the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2.

In the case of the molded light receiver 611, its functional characteristics are shown schematically on FIG. 13, and the cut (B) and process flow chart (C) of the molded light receiver 611 are shown on the same diagram. .

In the case of the molding receiver 611, a specific functional liquid material 650 is injected into the molding mold 400, and then the dynamic movement of moving the molding mold 400 or repeating the movement, rotation, and stopping is performed. By repeating sequentially, a specific functional liquid material 650 in the mold 400 forms a molding receiver 611 solidified in a regular or irregular shape repeatedly cured according to the dynamic momentum of the mold 400. ,

The shaped light receiving body 611 is characterized in that the polyhedron, curved body, spherical body, or polyhedron, curved body, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the molding frame 400 is characterized in that the polyhedron, curved surface, spherical body, or a polyhedron, curved surface, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

Further, it is characterized in that the modeling light receiving body 611 constitutes the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2.

In the case of the molded light receiver 612, its functional characteristics are shown on FIG.

 On FIG. 14, the cutting (B) and the process flowchart (C) of the molded light receiver 612 are shown and shown.

In the case of the molding receiver 612, a functional specific liquid material 650 and one or more receivers 2, etc. are injected into the molding mold 400, and then the molding mold 400 is moved or rotated. , The movement, rotation, and stop in order to repeat the dynamic movements in sequence to form a specific liquid material 650 and one or more receivers (2) in the mold 400 according to the dynamic amount of the mold 400 It characterized in that to form a molding receiver 612 solidified in a regular or irregular shape that is sequentially cured repeatedly.

In the case of the molding receiver 612, unlike the upper molding receiver 611, one or more receivers 2, etc., which are filled in the molding frame 400, are formed according to the dynamic momentum of the molding frame 400. Specific functional liquid material 650 in the) by the one or more light receivers (2), etc., filled in the mold 400, sequentially cured in a variety of patterns, solidified in a regular or irregular shape molding receivers 612 ), And

The shaped light receiving body 612 is characterized in that the polyhedron, curved surface, spherical body, or polyhedron, curved surface, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the molding frame 400 is characterized in that the polyhedron, curved surface, spherical body, or a polyhedron, curved surface, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the modeling light receiving body 612 is characterized in that the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2.

In the case of the molded light receiver 613, its functional characteristics are shown in Fig. 15,

 On FIG. 15, the cutting B and the process flowchart C of the modeling light receiver 613 are shown and shown.

In the case of the molded receiver 613, (701), (702), (703), (704), (705), (706), (711), (722), (733), (744), ( It is characterized by forming and processing the light receiving body 2 in which the pattern part 7, such as 755, is formed, and forming the shaped light receiving body 613.

In addition, the modeling light receiver 613 is provided with the light receiving body 2 to the light receiving body 2 by means of (701), (702), (703), (704), (705), (706), (711), 701, 702, 703, 704, 705, 706 by manipulating glyphs 7 such as 722, 733, 744, 755, etc. 711, 722, 733, 744, 755, etc., form the glyphs 7 and then the 701, 702, 703, 704, 705 ), (706), (711), (722), (733), (744), (755), etc. The light receiving body (2) formed with the pattern portion (7) is cut and processed to form a light receiving body (613) It characterized in that the forming, the molding receiver 613 is characterized in that the polyhedron, curved, spherical or polyhedral, curved, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the molding frame 400 is characterized in that the polyhedron, curved surface, spherical body, or a polyhedron, curved surface, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the modeling receiver 613 is characterized in that the receiver 2 of the light directing function display device 1 composed of two or more receivers 2.

In the case of the molded light receiver 614, its functional characteristics are shown on FIG.

 On FIG. 16, the cutting (B) and the process flowchart (C) of the molded light receiver 614 are shown and shown.

In the case of the shaped light receiver 614, the light receiver body is formed by curing a specific functional liquid material 650 into the molding grooves 4, 44, and the molding holes 5, 55 formed in the light receiver 2. (2) cutting and processing to form a molding light receiving member 614,

The shaped light receiving body 614 is characterized in that the polyhedron, curved surface, spherical body, or a polyhedron, curved surface, spherical body, etc. are displayed in the shape of various patterns mixed with each other.

In addition, the modeling receiver 614 is characterized in that the receiver 2 of the light directing function display device 1 composed of two or more receivers 2.

In the case of the upper molding receivers 610, 611, and 612, the molding frame 400 may be formed of the light receiving body 2 of the light directing function display device 1. 400 and the modeling light receiving bodies 610, 611, and 612 may be coupled to each other to form the light receiving body 2 of the light directing function display device 1.

A pattern portion 7 is formed on the light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2, and the shape of the pattern portion 7 is an embossed pattern 701. 1 to 5 schematically show the indication of identification,

It is etched on the light receiver 2 and is sculpted or etched in contrast with the recessed portion of the light receiver 2, characterized in that it is markedly sharper than the recessed portion of the light receiver 2.

In the case of the embossed pattern 711, the representation of the identification is shown in Figures 1 to 5,

The embossed pattern 701 is characterized by the embossed pattern 711 that the shape and shape of the embossed pattern 701 passes through two or more light receiving bodies 2.

In the case of the intaglio glyph 702, an indication of identification is schematically illustrated in FIGS.

It is etched in the light receiver 2, characterized in that it forms a shape that is deeper than the surface of the light receiver (2).

In the case of the intaglio pattern 722, an indication of identification is shown schematically in FIGS. 1 to 5,

The intaglio glyph 702 is characterized by the intaglio glyph 722 that the shape and shape of the intaglio glyph 702 passes through two or more light receivers 2.

In the case of the concave-convex pattern 703, an indication of identification is shown schematically in FIGS. 1 to 5,

It is characterized in that the concave and convex portions etched in the light receiver 2 form a shape that is simultaneously displayed.

In the case of the uneven pattern 733, the indication of identification is shown in FIGS. 1 to 5,

The above-mentioned concave-convex pattern 703 is characterized in that the concave-convex pattern 733 is passed through two or more light receiving bodies 2 and the shape and shape thereof.

In the case of the groove pattern 704, an indication of identification is shown in FIGS. 1 to 5.

It is etched in the light receiving body 2, characterized in that it forms a shape that is dug deeper or recessed deeper than the surface of the light receiving body 2, characterized in that the size and shape of the shape smaller than the upper intaglio pattern 702 do.

In the case of the groove pattern 744, an indication of identification is schematically illustrated in FIGS. 1 to 5,

A groove pattern 744 is characterized in that the above groove pattern 704 passes through two or more light receivers 2 and the shape and shape thereof are displayed.

In the case of the hole pattern 705, an indication of identification is schematically illustrated in FIGS. 1 to 5,

It is etched in the light receiver 2 and is characterized in that it is formed by a hole or the like to penetrate the light receiver 2 to form a shape.

In the case of the hole pattern 755, an indication of identification is schematically illustrated in FIGS. 1 to 5,

The hall pattern 705 is characterized in that the shape and shape of the hole pattern 705 is passed through two or more light receivers 2 to be displayed.

In the case of the projecting glyph 706, an indication of identification is schematically illustrated in FIGS. 1 and 3 to 5,

It is displayed on the light receiver 2, and is characterized in that its shape is formed by sticking out or blowing out more than the surface of the light receiver 2.

In addition, a specific material is attached to the surface of the light receiver 2, or the surface of the light receiver 2 is made thin so that a specific part of the light receiver 2 rises upward to form the shape.

Glyphs such as upper, 701, 702, 703, 704, 705, 706, 711, 722, 733, 744, 755, etc. In the case of 7), an indication of identification is shown schematically in FIGS. 1 to 5,

For the purpose of the light rendering function, the light receiving body 2 is provided with (701), (702), (703), (704), (705), (706), (711), (722), (733), ( 701, 702, 703, 704, 705, 706 are carved and etched into the pattern 7 in various patterns, such as 744, 755, etc. It is characterized by forming the shape of the pattern portion 7, such as 711, 722, 733, 744, 755.

Also, glyphs such as 701, 702, 703, 704, 705, 706, 711, 722, 733, 744, 755, etc. 7) is a multi-faceted, curved surface, and a multi-faceted surface, characterized in that formed in the shape of various patterns mixed with the curved surface, spherical surface.

In the light receiving body 2 and the like of the light directing function display device 1 composed of two or more light receiving bodies 2,

An auxiliary light 850 including an incandescent lamp, a fluorescent lamp, an LED lamp, etc. may be provided, and the auxiliary auxiliary light 850 in which the auxiliary light 850 is embedded in a part of the light receiver 2 or in the light receiver 2, The non-embedded auxiliary light 852 provided between the light receiving bodies 2, the space-filling auxiliary light 853 provided in the internal space of the light receiving body 2, etc. can be installed, and it is characterized by the buried auxiliary In the case of the light 851, the functional characteristics are shown on FIG. 23, and the auxiliary light 850 is embedded in the light receiving body 2, etc. of the light directing function display device 1. A buried auxiliary light 851 characterized by forming a display, wherein a part of the buried auxiliary light 851 is embedded in the light receiving body 2 of the light directing function display device 1, To form a shape in which all of the buried auxiliary light 851 is embedded in the light receiving body 2 of the function display device (1) It features.

In the case of the non-embedded auxiliary light 852, its functional characteristics are shown on FIG. 23, and between two or more light receivers 2 of the light directing function display device 1 in an open state and an unsealed space. It is characterized in that the non-embedded auxiliary light 852 to be installed.

In the case of the space-embedded auxiliary light 853, the functional characteristics are illustrated and displayed on FIG. 23, and the space-filled auxiliary light in the internal space such as the light receiving body 2 of the modeled light directing function display device 1 is illustrated. The space-filling auxiliary light 853 can be provided, and the molding light receiving body 601, 602, 603, 604, 605, etc. can be provided. The space-filling auxiliary light 853 can be installed therein.

In addition, the subsidiary auxiliary light 851 is formed by forming a color on the bulbs and lamps constituting the embedded subsidiary light 851, the non-embedded auxiliary light 852, the space buried auxiliary light 853, or by adding a color coating such as color coating. ), The non-embedded auxiliary light 852, the space-filled auxiliary light 853, and the like can express colored rays.

Also, (1200), (1201), (1202), (1203), (1300), (1301), (1302), (1303), (1400), (1401), (1402) of FIG. 1403, 1500, 1501, 1502, 1503, 1600, 1610, 1700, 1710, 1800, and the like as auxiliary display light having a light directing function. The light may be displayed on the light receiving body 2 of the light directing function display device 1 using the light emitted from the buried auxiliary light 851, the non-embedded auxiliary light 852, and the space-filled auxiliary light 853. .

In the case of ultraviolet and infrared rays such as 1204, 1205, 1304, and 1305, non-invisible light is invisible, and a secondary role such as the spectral role of ultraviolet light and the haze phenomenon of infrared light is described. When used for the auxiliary light 850, the effect is very limited.

The auxiliary light 850 such as 851, 852, 853 is provided to two or more light receivers 2 of the light directing function display device 1 composed of two or more light receivers 2 having a light directing function. , (1200), 1201,1202,1203,1300,1301,1302,1303,1400,1401,1402,1403 1500, 1501, 1502, 1503, 1600, 1610, 1700, 1710, 1800, etc. 851, 852, 853, and the like to form an auxiliary light 850.

In the light directing function display device 1 composed of two or more light receiving bodies 2, the two or more light receiving bodies 2 having the coupling portion 3 have the shape of a point at an observation angle of 360 degrees up, down, left and right. Point-shaped three-dimensional light receiver 8, which is formed and displayed, line-shaped three-dimensional light receiver 9, which is displayed by forming a line shape, planar three-dimensional light receiver 10, which is displayed by forming a surface (3), and (8), (9), (10), (11) and the like. 1) is characterized in that the polyhedron, curved, spherical or polyhedral, curved, spherical, etc. are displayed in the shape of a variety of patterns mixed with each other, in the case of the point-shaped three-dimensional light receiving body 8, Fig. 17 The structure and shape are shown in Fig. 2, and at least two light-receiving bodies having a coupling portion 3 ( 2), which can be embedded or attached to the light receiving body 2 or the like of the light directing function display device 1 composed of two or more light receiving bodies 2 for the purpose of the light directing function. It is characterized in that it can be used in connection with the function, structure, characteristics and the like of the three-dimensional light-receiving member 8 in shape.

In the case of the linear three-dimensional light receiving member 9, its structure and shape are shown schematically on FIG. 18, and are characterized by being composed of two or more light receiving members 2 having the coupling portion 3 formed thereon, In the embodiment of the above, it is characterized in that it can be used in the synthetic yarns and wovens shown.

Further, the function, structure and characteristics of the linear three-dimensional light receiver 9, such as being embedded or attached to the light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2, and the like. It can be used in conjunction with such.

 In the case of the planar three-dimensional light receiving body 10, the structure and shape are shown schematically on FIG. 19, and characterized in that it consists of two or more light receiving bodies 2 with the coupling portion 3 formed thereon, For the purpose, the function and structure of the planar three-dimensional light receiving body 10, such as being embedded or attached to the light receiving body 2, etc. of the light directing function display device 1 composed of two or more light receiving bodies 2, Characteristic that can be used in conjunction with the characteristics.

In the case of the multi-stereoscopic light-receiving member 11, the structure and shape are shown schematically on FIG. 20,

The light receiving body 2 of the light directing function display device 1, which is composed of two or more light receiving bodies 2 having a coupling part 3 formed thereon, and for the purpose of light directing function. It is characterized in that it can be used in conjunction with the function, structure, characteristics and the like of the three-dimensional light-receiving member 11 of the shape of a complex three-dimensional, such as being embedded or attached to.

The light directing function display device 1 composed of two or more light receiving bodies 2 is light, in which light energy irradiated from the light source 2500 is converted and formed into electromagnetic waves of emitted light of the light receiving body 2 to emit light. Refraction modulated transmission beam 1200, refraction modulated transmission beam 1200 and color display transmission beam 1201 of the light-receiving member 2, which are display beams of one unit output light having a directing function, and refraction modulated transmission beam 1202 of colored light. ), Refractive-type modulated transmission light of colored light and color-coded transmission light 1203 of light-receiving body 2, refractive-type modulation transmission ultraviolet ray 1204 of ultraviolet light, refractive-type modulation transmission infrared ray of infrared ray 1205, refractive-modulation transmission light of infrared ray Separation ray 1400 of the light beam, refractive modulation modulated transmission beam and color display of the light-receiving member 2 Separation ray 1401 of the transmitted light beam, Separation ray 1402 of the refractive-type modulation transmission light beam of colored light, Refraction modulation of colored light beam Of the separated light 1403 of the transmitted light and the color display transmitted light of the light receiving body 2 Occation,

An example of the shape is shown on FIG. 21, and the light energy irradiated from the light source 2500 is converted, and is formed by electromagnetic waves of the emitted light of the light receiver 2 to emit light. Refractive modulated reflected light 1300, refractive modulated reflected light and colored display reflected light 1301 of the light-receiving member 2, colored modulated reflected light 1302, colored refracted modulated light, and the like. Color display reflecting light 1303 of the reflected light and the light-receiver 2, refractive-modulated reflecting ultraviolet ray 1304 of ultraviolet light, refracting-modulated reflecting infrared ray of infrared light 1305, splitting light 1500 of refractive-modulated modulated light ray, Separation ray 1501 of refractive index modulated reflection ray and color-sensing reflection ray of light receiver 2, Separation ray 1502 of refractive-type modulation reflection light of colored light, Refraction modulation modulation ray of colored light and color of light receiver 2 In the case of split light 1503 of the display reflecting light,

An example of the shape is illustrated and shown on FIG. 22, and the light energy irradiated from the light source 2500 is converted to form an electromagnetic wave of the emitted light of the light receiver 2 to emit light. Diffracted light 1600 of transmitted light, diffracted light 1610 of reflected light, diffused light 1700 of transmitted light, diffused light 1710 of reflected light, which is the display light of unit emission light,

In the case of the cross-mixed ray 1800 in which two or more transmitted rays or reflected rays collide with each other or cross each other and are mixed and displayed, an example of the shape is schematically illustrated on FIGS. 21 and 22. Due to the structure of the light receiving body 2 of the light directing function display device 1 composed of the light receiving body 2, the light energy radiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the light receiving body 2 to achieve dynamic movement. At this time, transmission and reflection can be made in association between two or more light receivers 2.

In the above, when the electromagnetic wave of the emitted light of the light receiver 2 repeatedly transmits two or more light receivers 2 of the light directing function display device 1, it is classified as transmitted light.

When the above-mentioned electromagnetic wave of the emitted light of the light receiver 2 is reflected by two or more light receivers 2 of the light directing function display device 1, the remaining continuous light beams are divided into reflected light beams. Note that the emission light emitted from one light receiver 2 is not invented as the production light of the light directing function in the present invention. In the present invention, the directing light of the light directing function is invented as the directing light of the light directing function, the transmitted light of the transmission phenomenon between the two or more light receiving body (2) or the two or more light receiving body (2), the reflected light forming the reflection phenomenon. It should be recalled that.

In addition, in the case of transmitted light and reflected light, the light energy irradiated from the light source 2500 transmits all of the two or more light receivers 2 in all directions, or any one light receiver between the two or more light receivers 2 ( 2) the interior of the two or more light receivers 2 by converting them into electromagnetic waves and transmitting or reflecting them in the opposite direction, i. Or it is characterized in that it is represented by the directing light on the light directing function from the outside.

(1200), (1201), (1202), (1203), (1204), (1205), (1300), (1301), (generated by the light directing function display device 1 described below) 1302, 1303, 1304, 1305, 1400, 1401, 1402, 1403, 1500, 1501, 1502, 1503, 1600 Among the directing rays, such as, 1610, 1700, 1710, and 1800, the refraction modulated transmission beam 1200 is light energy irradiated from the light source 2500. 1) is converted into the electromagnetic wave of the emitted light of the light receiving body 2, part of which is absorbed by the light receiving body 2 with other energy, and the electromagnetic wave energy of the remaining emitted light is made of electromagnetic radiation into a linear band-shaped ray. Electromagnetic waves of the emitted light of the light receiving body 2, the refractive index of which is variously modulated by the structure and shape of the light receiving body 2, the volume and the positional variation, and the characteristics of the material, while passing through the light receiving body 2 1200),

Display inside or outside of two or more light receivers 2, etc. of the light directing function display device 1, until they cause destructive interference with electromagnetic waves of emitted light such as other light receivers 2, or until kinetic energy disappears. It is characterized by.

What is the refractive-modulated transmitted light and the color display transmitted light 1201 of the light receiver 2,

Light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the light receiving body 2 of the light directing function display device 1, and the refractive index modulated transmission beam 1200 having variously modulated refractive indices is used. Transmitting the excited light receiver 2 while converting it into electromagnetic waves of the emission light of the wavelength band corresponding to the color of the light receiver 2 having a color, to display the color of the light receiver 2 having a color, or to have a color As the electromagnetic wave 1201 of the emission light of the wavelength band corresponding to the color feeling of (2),

What is displayed inside or outside the two or more light receivers 2 of the light directing function display device 1 until they cause destructive interference with electromagnetic waves of the emitted light of the other light receivers 2 or until the kinetic energy is extinguished. Features,

The light directing function display device 1 may be displayed when the light receiving body 201 is made of a transparent material and the light receiving body 202 is made of a transparent material having color.

The refractive-modulated transmitted light 1202 of colored light means that the light energy of colored light irradiated from the light source 2500 is converted into the electromagnetic wave of the emitted light of the light receiving body 2 of the light directing function display device 1, and the other part is different. The structure and shape of the light receiver 2 are absorbed by the light receiver 2 as energy, and the electromagnetic wave energy of the remaining emitted light passes through the light receiver 2 with a linear band of light in the form of a linear band. As the electromagnetic wave 1202 of the emitted light of the light receiving body 2 in which the refractive index is variously modulated by operations such as volume, position variation, and material characteristics,

Is displayed inside or outside the two or more light receivers 2 of the light directing function display device 1 until they cause destructive interference with electromagnetic waves of the emitted light of the other light receivers 2 or until the kinetic energy disappears. It is done.

What is the refractive-modulated transmitted light of colored light and the color-displayed transmitted light 1203 of the light receiver 2,

The light energy of the colored light irradiated from the light source 2500 is converted into the electromagnetic wave of the emitted light of the light receiving body 2 of the light directing function display device 1, so that the refractive index modulated transmitted light 1202 of the colored light is modulated in various ways. ) Is transmitted to the electromagnetic wave of the emission light of the wavelength band corresponding to the color of the light receiving body 2 while passing through the light receiving body 2 having color, thereby displaying the color of the light receiving body 2 having color, or As the electromagnetic wave 1203 of the emission light of the wavelength band corresponding to the color of the excitation light receiver 2,

Is displayed inside or outside the two or more light receivers 2 of the light directing function display device 1 until they cause destructive interference with electromagnetic waves of the emitted light of the other light receivers 2 or until the kinetic energy disappears. It is done.

The light energy of the colored light irradiated from the light source 2500 is converted into the electromagnetic wave of the emitted light of the light receiving body 2 of the light directing function display device 1, so that the refractive index modulated transmitted light 1202 of the colored light is modulated in various ways. ) Passes through the light receiving body 2 having the color of the light directing function display device 1,

A light energy of colored light is converted into a combination of light of color matching in combination with the emitted light energy of a light-receiving body 2 having a color sense, so as to emit electromagnetic waves 1203 of different colored light having different wavelength bands. Characterized in that it is displayed inside or outside the light receiving body 2 of the light directing function display device 1 until it causes a destructive interference with electromagnetic waves of the emitted light of the light receiving body 2 or the kinetic energy is extinguished. .

In addition, when the light energy of the colored light is the same color as the light receiving body (2) having the color, the light energy of the colored light is combined with the electromagnetic wave of the emitted light of the light receiving body (2) with color to provide characteristics such as constructive interference. Represented by the synthesized electromagnetic wave 1203,

Characterized in that it is displayed inside or outside the light receiving body 2 of the light directing function display device 1 until it causes a destructive interference with the electromagnetic wave of the emitted light of the other light receiving body 2 or the kinetic energy is extinguished. do.

The refraction-modulated transmitted light 1204 of the ultraviolet rays is characterized by the upper refraction-modulated transmitted light 1200, while being converted to the incident light of the ultraviolet light irradiated from the light source 2500, the visible refraction of the ultraviolet light The modulated transmitted light 1204 is characterized in that it stays inside or outside the light receiving body 2 of the light directing function display device 1.

In addition, it is invisible due to the characteristics of ultraviolet rays, and the molding holes (5), (55) or the hole pattern (705) corresponding to the ultraviolet wavelength band of the light receiving body (2) of the light directing function display device (1). , 755 to transmit only invisible multiple ultraviolet rays, so that the light energy irradiated from the light source 2500 is converted into the electromagnetic wave of the emitted light such as the light receiver 2, and has a color of visible light band. (2) When the electromagnetic waves or the like of the emitted light collide with each other, or are combined or mixed with each other, multiple invisible multiples inside or outside the two or more light receivers 2 constituting the light directing function display device 1 It is characterized by forming a refractive index modulated transmission line 1204 of ultraviolet light, which is a unit output light of multiple ultraviolet light, characterized in that the spatial division of light to achieve the effect of spectroscopy distinguished from the ultraviolet light.

Infrared refractory modulated transmission beam 1205 is an infrared refracted modulated transmission beam 1205, characterized by a higher refractive index modulated transmission beam 1200 as the incident light beam of infrared light irradiated from the light source 2500 is converted. Therefore, the light directing function display device 1 is characterized in that it stays inside or outside the light receiving body 2 or the like.

In addition, the characteristics of the infrared rays are invisible. When the infrared rays stay inside or outside the light receiving body 2 of the light directing function display device 1, the light energy emitted from the light source 2500 is In contact with the inside and the outside of the light receiving body 2 due to characteristics such as heat radiation emission of the invisible infrared ray 1205 while colliding or multiplexing each other with electromagnetic waves or the like of the emitted light of the light receiving body 2 converted When the heated air rises, inside or outside the light directing function display device 1, electromagnetic waves and the like of the emitted light of the light receiving body 2 are optically distorted in the air plane in contact with each other, and thus a particular phenomenon such as haze To achieve.

The refraction modulated reflected light 1300 is light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the light receiving body 2 of the light directing function display device 1 and part of the light energy is converted into other energy. The electromagnetic wave energy of the remaining light emitted by the light body 2 reflects the light receiver 2 with a linear band-shaped display beam of electromagnetic wave radiation, and the structure, shape and volume of the light receiver 2 and the like. Electromagnetic waves 1300 of the emitted light of the light receiving body 2 in which the refractive index is variously modulated by manipulation of positional change and material characteristics, etc., cause or cancel out interference with the electromagnetic waves of the light emitted from the other light receiving body 2. It is characterized by being displayed inside or outside the two or more light receiving bodies 2 of the light directing function display device 1 until energy is dissipated.

The refraction-modulated reflecting ray and the color display reflecting ray 1301 of the light receiving body 2 are light waves irradiated from the light source 2500 to emit electromagnetic radiation of the light receiving body 2 of the light directing function display device 1. Converted, and the refractive index modulated reflecting light 1300 of which the refractive index is variously modulated reflects the light receiving body 2 of the reflective material and converts it into electromagnetic waves of the emission band corresponding to the color of the other light receiving body 2 having color. As the electromagnetic wave 1301 of the emission light of the wavelength band corresponding to the color of the light-receiving body 2 having color or displaying the color of the light-receiving body 2 having color,

What is displayed inside or outside the two or more light receivers 2 of the light directing function display device 1 until they cause destructive interference with electromagnetic waves of the emitted light of the other light receivers 2 or until the kinetic energy is extinguished. It features.

The refractive-modulated reflected light 1302 of colored light means that the light energy of colored light irradiated from the light source 2500 is converted into electromagnetic waves of colored emission light of the light receiving body 2 of the light directing function display device 1 and partially. Is absorbed by the light receiver 2 with other energy, and the electromagnetic wave energy of the remaining emitted light reflects the light receiver 2 in a linear band-shaped beam of photons made of electromagnetic radiation, and the structure of the light receiver 2 and Electromagnetic waves 1302 of the emitted light of the colored light receiver 2 with various refractive indices modulated by manipulations of shape, volume, positional variation, and material characteristics, etc., offset with electromagnetic waves of the light emitted from the other light receiver 2. It is characterized by being displayed inside or outside the two or more light receivers 2 of the light directing function display device 1 until they cause interference or kinetic energy disappears.

Refraction-modulated reflecting rays of colored light and color display of the light-receiver 2 What is light energy of colored light irradiated from the light source 2500 means that the light energy of the light-directing function display device 1 ) Is converted into an electromagnetic wave of the emitted light, and the refractive index modulated reflected light 1302 of colored light having variously modulated refractive indices reflects the light receiver 2 of the reflective material, corresponding to the color of the light receiver 2 having color. As the electromagnetic wave 1303 of the emission light of the wavelength band which is converted into the electromagnetic wave of the emission light of the wavelength band and displays the color of the light-receiving body 2 having color, or corresponds to the color of the light-receiving body 2 with color,

Is displayed inside or outside the two or more light receivers 2 of the light directing function display device 1 until they cause destructive interference with electromagnetic waves of the emitted light of the other light receivers 2 or until the kinetic energy disappears. It is done.

The light energy of colored light irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the light receiving body 2 of the light directing function display device 1, and the refractive index modulated reflection ray 1302 of colored light having variously modulated refractive indices. ) Reflects the light-receiving member 2 of the reflective material of the light directing function display device 1,

As the electromagnetic wave 1303 of the emitted light of the other colored light which is converted into a combination of the light of color matching in combination with the emitted light energy of the other light-receiving body 2 having the color sense, and having a different wavelength band,

Characterized in that it is displayed inside or outside the light receiving body 2 of the light directing function display device 1 until it causes a destructive interference with the electromagnetic wave of the emitted light of the other light receiving body 2 or the kinetic energy is extinguished. do.

In addition, when the light energy of the colored light is the same color as the light receiving body (2) having the color, the light energy of the colored light is combined with the electromagnetic wave of the emitted light of the light receiving body (2) with color to provide characteristics such as constructive interference. Represented by the synthesized electromagnetic wave 1303,

Characterized in that it is displayed inside or outside the light receiving body 2 of the light directing function display device 1 until it causes a destructive interference with the electromagnetic wave of the emitted light of the other light receiving body 2 or the kinetic energy is extinguished. do.

Ultraviolet refractive modulated reflected light 1304 is characterized by the upper refractive index modulated reflected light 1300, while the incident light of the ultraviolet light irradiated from the light source 2500 is converted, invisible, ultraviolet refractive shape The modulated reflection light 1304 stays inside or outside the light receiving body 2 of the light directing function display device 1.

In addition, it is characterized by the characteristics of the ultraviolet light, and the molding grooves (4), (44) or groove pattern (704) corresponding to the ultraviolet wavelength band in the light receiving body (2) of the light directing function display device (1). 744 to reflect only the invisible multiple ultraviolet rays, so that the light energy irradiated from the light source 2500 is converted into the electromagnetic wave of the emitted light such as the light receiver 2, and has a color of visible light band. (2) When the electromagnetic waves or the like of the emitted light collide with each other, or are combined or mixed with each other, multiple invisible multiples inside or outside the two or more light receivers 2 constituting the light directing function display device 1 It is characterized by forming a refractive-modulated reflected light (1304) of ultraviolet light, which is a unit output light of multiple ultraviolet light, characterized in that the spatial division of light to achieve the effect of spectral to be distinguished from the ultraviolet light.

Infrared refractory modulated reflected light 1305 is an infrared refracted modulated reflected light 1305, characterized by an upper refracted modulated reflected light 1300 while being converted into incident light of infrared light irradiated from the light source 2500. Therefore, the light directing function display device 1 is characterized in that it stays inside or outside the light receiving body 2 or the like.

In addition, the characteristics of the infrared rays are invisible. When the infrared rays stay inside or outside the light receiving body 2 of the light directing function display device 1, the light energy emitted from the light source 2500 is Heated by contacting two or more light receivers 2 due to characteristics such as heat radiation emission of an invisible infrared ray 1305 while colliding or multiplexing with electromagnetic waves of the emitted light of the converted light receiver 2 and the like. When the air rises,

Inside or outside the light directing function display device 1, electromagnetic waves of the emitted light of the other light receiving body 2 are optically distorted in the air surface in contact with each other, thereby forming a specific phenomenon such as haze, thereby achieving a light directing function. It is characterized by.

The light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2 is moved, rotated, stopped, moved, rotated, etc. by external physical force to achieve dynamic deformation. Displayed separately when

The separation beam 1400 of the refractive modulation modulated transmission beam 1200 is a separation beam 1400 of the refractive modulation modulation transmission beam, which includes the characteristics of the refractive modulation modulation transmission beam 1200.

When the light receiving body 2 or the like of the light directing function display device 1 performs dynamic deformation by repeatedly moving, rotating, or stopping, moving, rotating, etc. by an external physical force, the refractive-modulated transmission beam 1200 Inside the light receiving body 2 of the light directing function display device 1 or the like until the light is momentarily separated and causes destructive interference with the electromagnetic waves of the emitted light of the other light receiving body 2 or the kinetic energy disappears. Characterized in that it is displayed on the outside.

Separation rays 1401 of the refractive-modulated transmitted light and the color display transmitted light of the light receiver 2 include the features of the refractive-modulated transmitted light and the color-display transmitted light 1201 of the light receiver 2. , As a split beam 1401 of the refractive-modulated transmit beam and the color display transmit beam of the light receiver 2, the light receiver 2 of the light directing function display device 1 is moved by an external physical force, When rotating or stopping, moving or rotating repeatedly to achieve dynamic deformation,

Until the refractive modulated transmitted light and the color-sensing transmitted light 1201 of the light receiver 2 are instantaneously separated, causing a destructive interference with the electromagnetic waves of the emitted light of the other light receiver 2 or the kinetic energy disappears. It is characterized in that it is displayed inside or outside the light receiving body (2) of the light directing function display device (1).

Separation beam 1402 of refractive-modulated transmitted light of colored light is separated light 1402 of refracted-modulated transmitted light of colored light containing the features of the refractive-modulated transmitted light 1202 of colored light. When the light receiving body 2 or the like of the function display device 1 performs dynamic deformation by repeatedly moving, rotating, or stopping, moving, rotating, etc. by an external physical force,

The refraction modulated transmitted light 1202 of the colored light is momentarily separated to cause a destructive interference with the electromagnetic waves of the emitted light of the other light receiver 2 or until the kinetic energy is dissipated. It is characterized by being displayed inside or outside the light receiving body 2 or the like.

Separation beams 1403 of colored modulated transmission beams of colored light and color display transmission beams of light receiver 2 are different from refractive index modulated transmission beams of colored light and color display transmission beams 1203 of light receiver 2 The light-receiving body 2 of the light directing function display device 1 and the like as the separated light 1403 of the colored modulated transmission light of the colored light and the color-sensitive display transmission light of the light receiving body 2 containing the features. When the dynamic deformation is achieved by repeatedly moving, rotating, or stopping, moving, rotating, etc. by the force, the refractive-type modulation transmission beam of colored light and the color display transmission beam 1203 of the light receiver 2 are momentarily separated. It is displayed inside or outside of the light receiving body 2 of the light directing function display device 1 until it causes a destructive interference with electromagnetic waves of the emitted light of the other light receiving body 2 or the kinetic energy disappears. It is done.

The split light 1500 of refraction modulated reflecting light is the split light 1500 of refraction modulated reflecting light, which includes the characteristics of the refraction modulated reflecting light 1300, wherein the number of the light directing function display devices 1 When the housing 2 or the like repeatedly moves, rotates, or stops, moves, rotates, or otherwise undergoes dynamic deformation by an external physical force, the refractive modulated reflecting ray 1203 is momentarily separated from the other receivers. It is characterized by being displayed inside or outside the light receiving body 2 of the light directing function display device 1 until it causes a destructive interference with electromagnetic waves of the emitted light of (2) or until kinetic energy disappears.

The separated rays 1501 of the refractive modulated reflecting rays and the color display reflecting rays of the light receiving body 2 include the features of the refractive index modulating reflecting light and the color displaying reflecting light 1301 of the light receiving body 2, As the split light 1501 of the refraction-modulated reflecting ray and the color display reflecting ray of the light receiving body 2, the light receiving body 2, etc. of the light directing function display device 1 is moved, rotated, or rotated by an external physical force. When we make dynamic deformation by repeating, stopping, moving, rotating, etc.,

Until the refraction modulated reflected light and the color-displayed reflected light 1301 of the light receiver 2 are instantaneously separated, causing an interfering interference with the electromagnetic waves of the emitted light of the other light receiver 2 or dissipating kinetic energy, The light directing function display device 1 is characterized in that it is displayed inside or outside the light receiving body (2).

Separation beam 1502 of refractive-type modulated reflected light of colored light is a split light 1502 of refractive-type modulated reflected light of colored light containing the features of the refractive-modulated reflected light 1302 of colored light. When the light receiving body 2 or the like of the device 1 repeatedly moves, rotates, or stops, moves, rotates, etc. by external physical force, and performs dynamic deformation, the refractive-modulated reflected light 1302 of colored light Instantaneously separated, either inside or outside the light receiving body 2, etc. of the light directing function display device 1 until they cause a destructive interference with electromagnetic waves of the emitted light of the other light receiving body 2 or until the kinetic energy is dissipated. It is characterized by being displayed.

What is the characteristic of the refractive-modulated reflected light of colored light and the color-coded reflected light of the light-receiver 2, and the characteristics of the refractive-modulated reflected light of colored light and the color-display reflected light 1303 of the light receiver 2 As a separate beam 1503 of the colored modulated reflecting ray of colored light and the color display reflecting ray of the light receiving body 2, the light receiving body 2 and the like of the light directing function display device 1 are external physical forces. By repeating the movement, rotation, or stop, movement, rotation, etc., to achieve dynamic deformation, the refraction-modulated reflected light of colored light and the color display reflecting light 1303 of the light receiver 2 are momentarily separated,

Characterized in that it is displayed inside or outside the light receiving body 2 of the light directing function display device 1 until it causes a destructive interference with electromagnetic waves of the emitted light of the other light receiving body 2 or the kinetic energy is extinguished. do.

The light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2 is repeatedly moved, rotated, stopped, moved, rotated, etc., by external physical force, thereby performing dynamic deformation. (1200), (1201), (1202), (1203), etc., passing through two or more light receivers (2) corresponding to that feature is displayed or that the feature is displayed in a stationary state without dynamic deformation. In the case of diffracted light 1600 where the transmitted light is diffracted in contact with a narrow gap or corner of two or more light receivers 2, the transmitted light such as the upper 1200, 1201, 1202, 1203, etc. The light receiving body 2 of the light directing function display device 1, which is composed of two or more light receiving bodies 2, is repeatedly moved, rotated or stopped, moved, rotated, etc., by external physical force, thereby performing dynamic deformation. (1200) (12) abutting a narrow gap or edge of two or more light receivers (2) formed or formed in a stationary state without dynamic deformation As the diffraction light 1600 of the optical image generated when the electromagnetic wave surface of the emitted light of the light receiver 2 corresponding to the transmitted light such as 01), 1202, 1203, etc. is distorted or the distorted electromagnetic wave surfaces interfere with each other. The light directing function display device 1 is characterized in that it is displayed inside or outside the light receiving body (2).

Diffracted light 1610 in which reflected light, such as (1300), (1301), (1302), (1303), that reflects two or more light receivers (2) is diffracted in contact with a narrow gap or edge of the two or more light receivers (2) ), The light receiving body 2 of the light directing function display device 1 in which the reflected light beams, such as the upper, 1300, 1301, 1302, and 1303, are composed of two or more light receiving members 2; Narrow gaps or corners of two or more light receivers 2 whose backs are formed in a static state by moving, rotating or stopping, moving, rotating, etc. by external physical force or in a stationary state without dynamic deformation. Optics generated when the electromagnetic waves of the emitted light of the light receiver 2 corresponding to the reflected rays such as 1300, 1301, 1302, 1303, and the like are distorted or the distorted electromagnetic waves interfere with each other The diffracted light 1610 of the image is displayed inside or outside the light receiving body 2 or the like of the light directing function display device 1.

In the case of the diffused light 1700 of the transmitted light, the light received body 2 of the light directing function display device 1, which includes the transmitted light of the upper 1200 made of multicolored light, consists of two or more light received bodies 2, or the like. Diffuse light (1700) that forms a dispersion in which transmitted light of (1200) is divided into upper and lower parts of multi-colored light passing through the light receiving body (2), etc. when the prism or similar triangular volume is formed. ), As an example of rainbow rays,

It is characterized in that the display is made inside or outside the light receiving body 2 or the like of the light directing function display device 1 composed of two or more light receiving bodies 2.

In addition, when the light receiving body 2 and the like of the light directing function display device 1 composed of two or more light receiving bodies 2 form a characteristic or shape on a material which repeats total reflection,

When the light energy irradiated from the light source 2500 is converted and the total reflection is repeated with electromagnetic waves having different wavelengths as electromagnetic waves of the emitted light of the light receiving body 2, the electromagnetic waves having different wavelengths are distinguished and displayed to achieve light dispersion. , The visible light scattered by the transmitted light of (1200), which is displayed inside or outside the light receiving body (2) of the light directing function display device (1) consisting of two or more light receiving bodies (2). It is done.

In the case of the scattered light 1710 of the reflected light, the light receiving body 2 of the light directing function display device 1, wherein the reflected light of 1300 is composed of two or more light receiving bodies 2, which is made of multicolored light, is optical. When the prism of the image or a similar triangular volume is formed, the scattered light 1710 forming a dispersion in which the reflected light of the upper (1300) consisting of multicolored light transmitted in contact with the light receiving body 2, etc. is divided and displayed for each wavelength band. Is an example of the rainbow light, characterized in that the display is made inside or outside the light receiving body 2 or the like of the light directing function display device 1 composed of two or more light receiving bodies 2.

In addition, when the light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2 has a characteristic or shape of material that repeats total reflection, the light energy emitted from the light source 2500 is When the total reflection is converted to electromagnetic waves of different wavelengths as the electromagnetic waves of the emitted light of the light receiver 2 and the like, the scattered light of the reflected light of the upper (1300) of the upper (1300), which splits the light while displaying the electromagnetic waves having different wavelengths, is displayed. 1710)

It is characterized in that the display is made inside or outside the light receiving body 2 or the like of the light directing function display device 1 composed of two or more light receiving bodies 2.

At least one of the transmitted light passing through the two or more light receivers 2 and the reflected light reflecting the two or more light receivers 2 or more, the two or more transmitted light, reflected light, etc. collide with each other or deviate from each other and mixed Displayed

For cross mixed light 1800,

Transmitted rays such as upper (1200), (1201), (1202), (1203) and their separated rays (1400), (1401), (1402), (1403) and upper (1300), (1301), ( 1302, 1303, and the like, and their separated rays 1500, 1501, 1502, and 1503 are two or more photons intersected with each other. Display rays 1800, or

Or transmitted rays such as upper (1200), (1201), (1202), (1203), and the separated rays (1400), (1401), (1402), (1403), and the like (1300), (1301). 1130, 1501, 1501, 1502, 1503, and the like, and collide with each other,

Color matching, which is a combination of light in optical form, is mixed and mixed with each other, and the color is modulated and displayed as cross-mixed rays 1800 of electromagnetic waves of emitted light, such as a modulated light 2, and at least two light receivers 2 It is characterized in that it is displayed inside or outside the light receiving body (2) of the light directing function display device (1) consisting of.

In addition, the light energy irradiated from the light source 2500 is converted, and made of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1,

(1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. Lee, 201, 202, 203, 204, 205, 206, 211, 212, 213, 214, 215, 216, Modeling receivers 660, 601, 602, 603, 604, 605, (217, 221, 222, 223, 224, etc. A light receiving body 2 corresponding to a molding light receiving body 6 such as 610, 611, 612, 613, 614, etc.,

Modeling frame 400 and the specific functional liquid material 650, the coupling portion (3), such as (301), (302), (303), (304), (305), (306), (307), and Molding grooves (4), (44), molding holes (5), (55), (701), (702), (703), (704), (705), (706), (711), ( Pattern parts 7 such as 722, 733, 744, 755, auxiliary light 850, 8, 9, 851, 852, 853, etc. (10) or (11) to manipulate or manipulate the characteristics of the material, such as color, scale, volume and shape, positional fluctuation, etc., such as points, lines, faces, and a light-receiving body 2 of a multi-stereoscopic shape. Electromagnetic waves of the emitted light, such as the light receiving body 2 of the light directing function display device 1, by the manipulation technique such as combining, mixing, or distributing the provided features or the like, collide with each other, or multiplex, or mix and Spectroscopically,

Characterized in that it is implemented as a single unit light, constituting the light directing function.

 The light directing function display device 1 composed of two or more light receiving bodies 2 includes 201, 202, 203, 204, 205, 206, 211, and 212. Modeling light receivers 660, 601, 213, 214, 215, 216, 217, 221, 222, 223, 224, etc. Receptor corresponding to modeling light receivers 6 such as 602, 603, 604, 605, 610, 611, 612, 613, 614, etc. 2), the molding unit 400 and the specific functional liquid material 650, and the coupling portion of (301), (302), (303), (304), (305), (306), (307), etc. (3) and molding grooves (4), (44), molding holes (5), (55), (701), (702), (703), (704), (705), (706), ( Glyphs 7 such as 711, 722, 733, 744, 755, and auxiliary lights 850 and 8, such as 851, 852, 853, etc. (9), (10), (11) to manipulate the characteristics of the material, such as points, lines, planes, composite three-dimensional light-receiving body (2), color, scale, volume and shape, position variation, etc. First, the light directing function display device 1, which is formed by an operation technique such as combining or mixing and distributing the manipulated features or the like with each other, is first set up. Two or more light-receiving members which are operated by the light directing function, which is subsequently linked to and displayed on the light directing function display device 1, is converted to form the light directing function display device 1. (2) (1200), (1201), (1202), (1203), (1204), (1205), (1300), (1301), (1302), (1303) , (1304), (1305), (1400), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), ( 1700), (1710), (1800), etc. of one unit of the light emitting function of the light directing function,

Display light (visible light) or non-display light (ultraviolet light, infrared light) and light energy irradiated from the multiple light sources 2500 are converted into two or more light receivers 2 constituting the light directing function display device 1 (1200), (1201), (1202), (1203), (1204), (1205), (1300), (1301), (1302), (1303), consisting of a combination of electromagnetic waves of emitted light. ), (1304), (1305), (1400), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), Combination of one unit output light having a light directing function corresponding to 1700, 1710, 1800, and the like, display light (visible light) or non-display light (ultraviolet light, infrared light),

The line manipulation technique of the light directing function display device 1, which continuously collides with each other, or is multi-coupled or spectroscopic, and forms a light directing function, and the light energy irradiated from the light source 2500 is converted to display the light directing function. (1200), (1201), (1202), (1203), (1204), (1205), (1205), and (1300), which are made of electromagnetic waves of emitted light such as two or more light receivers 2 constituting the device 1. (1301), 1302,1303,1304,1305,1400,1401,1402,1403,1500,1501,1502,1503 ), (1600), (1610), (1700), (1710), (1800), etc. of one unit of the light emitting function of the light directing function,

Display light (visible light) or non-display light (ultraviolet light, infrared light) and light energy irradiated from the multiple light sources 2500 are converted into two or more light receivers constituting the light directing function display device 1 ( 2) (1200), (1201), (1202), (1203), (1204), (1205), (1300), (1301), (1302), (1302), consisting of a combination of electromagnetic waves of emitted light such as 1303, (1304), (1305), (1400), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610) Combination of one unit emitting light of the light directing function corresponding to the (1700), (1710), (1800), or more, the display light (visible light) or non-display light (ultraviolet, infrared),

Continuously designing and manipulating the light directing function, characterized in that they collide with each other, or multiplely or spectroscopically, to achieve a light directing function, 201, 202, 203, 204 , (205), (206), (211), (212), (213), (214), (215), (216), (217), (221), (222), (223), ( 224, 601, 602, 603, 604, 605, 610, 611, 612, 613, 614, etc. A light receiving body 2 corresponding to a molding light receiving body 6, etc., a molding frame 400 and a specific functional liquid material 650, 301, 302, 303, 304, 305, 306, 307 coupling parts 3 and molding grooves 4, 44, molding holes 5, 55, 701, 702, 703 (7), (704), (705), (706), (711), (722), (733), (744), (755), (7), (851) (852), Material characteristics such as auxiliary light 850 such as 853 and (8), (9), (10), and (11), point, line, surface, and light-receiving body (2) in the shape of a composite. , Color, scale, volume and shape, and position variations, or any combination of the manipulated features, etc. , By such a distribution, the operating technique, comprising, in the light directing function display (1),

Characterized in that the light directing function is designed and manipulated first,

By the post-operation technique of the light directing function display device 1, the light directing function display device 1 can be variously operated.

Further, light energy, etc. irradiated from the multiple light sources 2500 is converted into a combination of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1, 1200. ), (1201), (1202), (1203), (1204), (1205), (1300), (1301), (1302), (1303), (1304), (1305), (1400), 1402, 1402, 1403, 1500, 1501, 1502, 1503, 1600, 1610, 1700, 1710, 1800, etc. Combination of unit light of directing function, display light (visible light) or non-display light (ultraviolet ray, infrared ray), etc.,

The light receiving body 2 of the light directing function display device 1, in which light energy irradiated from the light source 2500 is converted, which is successively collided with each other, or multiplexed or spectroscopically, to achieve a light directing function. In order to implement a light directing function by a combination of unit emission light, electromagnetic waves of emitted light such as

The light directing function display device 1 is pre-operated or a light directing function combining a display light (visible light) or a non-display light (ultraviolet light, infrared light) of one unit emission light is pre-operated.

It is characterized in that the light directing function display device 1 can be manipulated in various dimensions.

When operating the light directing function that combines the display light (visible light) or non-display light (ultraviolet, infrared) of unit emission light,

Pre-sketch the light directing function on a canvas or display the light directing function on the electronic drawing in detail, and spatially divide the color, shape, and position of the made light, or combine, mix, and distribute the light to produce precise light. A function can be operated beforehand.

The light directing function display device 1 composed of two or more light receiving bodies 2 is characterized by being capable of manipulating the color, shape and shape of light with at least two light receiving bodies 2, At least two light receivers 2 forming the function display device 1

It is characterized by consisting of the light receiving body 2, including functional characteristics such as (201), (202), (203), (204), (205), (206),

It is characterized by consisting of the light receiving body 2, including the shape characteristics such as (211), (212), (213), (214), (215), (216), (217),

It is characterized by consisting of the light receiving body 2, including material characteristics such as (221), (222), (223), (224),

Characterized in that the molding frame 400 forms a molding light receiving body 660 which is formed by curing the specific functional liquid material 650 and formed into a light receiving body 2,

Consisting of molded light receivers 6 such as 601, 602, 603, 604, 605, 610, 611, 612, 613, 614, etc. And a light receiving member 2 of a dot, line, surface, composite stereoscopic light output display device 1, such as (8), (9), (10), and (11). Modeling grooves 4, 44, Modeling holes 5, 55, which are displayed on at least two light receiving members 2 constituting the light directing function display device 1, Glyphs 7 such as 703, 704, 705, 706, 711, 722, 733, 744, 755, etc. The multi-sided surface is characterized in that the spherical surface, the curved surface, etc. are displayed in the shape of various patterns mixed with each other, and is provided in the at least two light receiving members 2 constituting the light directing function display device (851) ), (852), (853), such as to form an auxiliary light (850),

The color of light energy radiated from the light source 2500, the color of electromagnetic waves emitted from one of the two light receivers 2, and the other number of light receivers 2 While the electromagnetic waves of the emission light of the color of the electromagnetic wave emitted from the light collide with each other,

Color matching, which is a combination of light, to achieve the color of the third light formed by the electromagnetic waves of the emitted light of the third toned light, the color of the light being different,

When light energy irradiated from the light source 2500 is incident on at least two light-receiving bodies 2 constituting the light directing function display device 1,

At least two photoreceptors 2 constituting the light directing function display device 1 react to form electromagnetic waves of emission light having the color of the two photoreceptors 2,

It is characterized by being able to display all colors of light varying the wavelength of the visible light source,

Auxiliary light 850, such as 851, 852, 853, which is provided on at least two light-receiving bodies 2 constituting the light directing function display device 1, is characterized by forming electromagnetic waves of emitted light. And the light energy irradiated from the light source 2500 is converted into electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1, 1200, 1201, (1202), 1203,1204,1205,1300,1301,1302,1303,1304,1305,1400,1401,1402 ), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. Unit light,

Visible light (visible light) or non-display light (ultraviolet, infrared), and

Light energy or the like irradiated from the multiple light sources 2500 is converted into a combination of electromagnetic waves of emitted light such as two or more light receivers 2 constituting the light directing function display device 1,

(1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit light of the corresponding light directing function, or more,

Combination of display rays (visible rays) or non-display rays (ultraviolet rays, infrared rays),

Continuously, colliding with each other, or multiplexing or spectroscopically to achieve a light directing function,

At least 2, forming the light directing function display device 1 by forming a coupling part 3 such as 301, 302, 303, 304, 305, 306, 307, etc. By forming the number of light receivers 2,

Until at least two numbers of light-receiving members 2 constituting the light directing function display device 1 stay inside or be displayed, or until the destructive interference phenomenon or kinetic energy is exhausted by the function thereof,

It is characterized by being operable to stay or be displayed inside or outside the at least two light receivers 2 by electromagnetic waves of emitted light such as the light receivers 2 and the like.

The light directing function display device 1 composed of two or more light receivers 2,

Ultraviolet rays irradiated from the light source 2500 stay inside or outside the light receiving body 2 of the light directing function display device 1;

In addition, the characteristics of the ultraviolet light is characterized in that invisible,

Forming holes 5, 55, or hole patterns 705, 755 corresponding to the ultraviolet wavelength band are formed in the light receiving body 2, etc. of the light directing function display device 1, so that the invisible multiple By only transmitting ultraviolet light,

Electromagnetic waves of the emitted light, such as the light receiver 2 having the color of the visible light band in which the light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light such as the light receiver 2, collide with each other, or multiplexed or mixed When

The light directing function display device 1 includes electromagnetic waves of the emitted light such as a light receiver 2 having a color of visible light band in which light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light such as the light receiver 2. Inside or outside the two or more light receiving bodies 2 constituting the space, the spatial division of light is achieved while achieving the effect of the spectral to be distinguished from multiple ultraviolet light, etc.

Forming grooves 4, 44, or groove patterns 704, 744 corresponding to the ultraviolet wavelength band are formed in the light receiving body 2, etc. of the light directing function display device 1, so that the multiple invisible By reflecting only ultraviolet light,

Electromagnetic waves of the emitted light, such as the light receiver 2 having the color of the visible light band in which the light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light such as the light receiver 2, collide with each other, or multiplexed or mixed When the light energy emitted from the light source 2500 is converted into the electromagnetic wave of the emitted light such as the light receiver 2, the electromagnetic wave of the emitted light such as the light receiver 2 having the color of the visible light band is a light directing function display device. Characterized in that the spatial division of light is achieved while achieving the effect of spectral display distinguished from multiple ultraviolet rays or the like, which are invisible from inside or outside the two or more light receiving bodies 2 constituting (1),

The infrared light irradiated from the light source 2500 is converted into two or more light receivers 2 constituting the light directing function display device 1, and the other light energy irradiated from the light source 2500 is converted into Display of light directing function when hot air, which is in contact with the inside and outside of the light receiving body 2, rises due to characteristics such as heat radiation emission of invisible infrared rays while colliding or multiplexing with electromagnetic waves of emitted light, etc. In the interior or exterior of the device 1, electromagnetic waves and the like of the emitted light of the light receiving body 2 are optically distorted in the air plane in contact with each other, thereby producing a specific phenomenon such as a haze, to achieve a light directing function.

The light directing function display device 1 composed of two or more light receiving bodies 2 having a minimum length of one side of which is at least nanometers (nm) is a light directing function of two or more light receiving bodies 2 composed of ultra-small nanoparticles. The display device 1 is characterized in that two or more light receivers 2 composed of ultra-small nanoparticles, such as 301, 302, 303, 304, 305, 306, Or coupling portion 3 is formed, such as 307, or

Molding grooves 4, 44, molding holes 5, 55, 703, 704, 705, 706, etc. Pattern parts 7 such as 711, 722, 733, 744, and 755 are formed, and two or more light-receiving members 2 composed of ultra-small nanoparticles are the smallest nano-particles. It consists of a modeling receiver 660 of ultra-small nanoparticles, which is formed by curing the specific functional liquid material 650 by the formed mold 400, (601), (602), (603), (604). (6), (9) characterized in that the molded photoreceptor (6) such as (605), (610), (611), (612), (613), (614) is made of ultra-small nanoparticles. ), (10), (11), and the like, two or more light receiving bodies (2) constituting the light directing function display device (1) in the form of a dot, line, plane, complex, etc. are made of ultra-small nanoparticles. do.

In the case of utilizing the light directing function display device 1 made of two or more light receivers 2 composed of ultra-small nanoparticles, the two or more light receivers 2 constituting the light directing function display device 1 By embedding or attaching or protruding the light directing function display device 1 of the ultra-small nanoparticles, there is an advantage in that the function of the light directing function display device 1 can be realized more precisely.

The light directing function display device 1 composed of two or more light receivers 2,

Characterized in that electrical, electronic and mechanical devices can be attached to two or more light receiving bodies 2 constituting the light directing function display device 1,

Electrical, electronic, and mechanical devices attached to two or more light receiving bodies 2 constituting the light directing function display device 1 move or rotate, stop, or move in the forward, backward, up, down, left, and right directions. When you make a dynamic change that repeats the rotation,

The two or more light receivers 2 constituting the light directing function display device 1 are dynamic, or the electromagnetic waves of the emitted light such as the light receiver 2 constituting the dynamic fluctuation interfere with each other, causing irregular or irregularities. Characterized by achieving dynamic fluctuations,

1200, which consists of electromagnetic waves of emitted light, such as a light receiving body 2 that is dynamically changed, by electric, electronic, and mechanical devices attached to two or more light receiving bodies 2 constituting the light directing function display device 1, etc. , (1201), (1202), (1203), (1204), (1205), (1300), (1301), (1302), (1303), (1304), (1305), (1400), ( 1401, 1402, 1403, 1500, 1501, 1502, 1503, 1600, 1610, 1700, 1710, 1800, etc. Display light (visible light) or non-display light (ultraviolet light, infrared light) of one unit emission light of the directing function collide with each other, or multiple association or spectroscopy, to achieve a light directing function on the dynamic variation.

By electric, electronic and mechanical devices attached to two or more light receiving bodies 2 constituting the light directing function display device 1, etc.,

(1200), (1201), (1202), (1203), electromagnetic waves of emitted light, such as the light receiving body (2) in which light energy irradiated from the light source (2500) is converted, are incident or are formed in multiple combinations. ), 1204, 1205, 1300, 1301, 1302, 1303, 1304, 1305, 1400, 1401, 1402, 1403, Display light of one or more unit emission light having a light directing function corresponding to (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. Combinations, such as visible rays) or non-display rays (ultraviolet rays, infrared rays), are formed in multiple combinations, and are continuously collided with each other, or multiple associations or spectroscopy, to achieve a light rendering function on dynamic variation.

Two or more light receivers 2 constituting the light directing function display device 1 are made by electric, electronic and mechanical devices attached to the two or more light receivers 2 constituting the light directing function display device 1, and the like. In the case of the dynamic fluctuation, the expressive light function is to move and rotate the shapes of multi-dimensional and complex three-dimensional and non-three-dimensional light freely, so that the shapes of the light collide with each other, or spectral, mixing and free-combining. There is an advantage that can be implemented in a high-dimensional light directing function.

The light directing function display device 1 according to an embodiment of the present invention is not limited to the contents of the features of the light directing function display device 1 described above, but within the range in which the technical features of the present invention are allowed. By combining, mixing, or distributing the features of the light directing function display device 1 described above with each other, the operation of the light directing function display device 1 is variously performed to suit the purpose of the required light directing function. can do.

EXAMPLE

24, the light directing function display device 1 is schematically shown and made of a component material of the lighting device.

24, the light directing function display device 1 includes a groove pattern 704, a molding groove 4, a molding hole 55, a groove pattern 704, a light receiving member 201 made of a transparent material without color sense, It is characterized in that the light receiving body 202 of the transparent material with a color, made in the form of a heat-compression bonding (303).

 The light directing function display device 1 shown in Fig. 24 accommodates a light source 2500 and forms display light beams such as 1200 and 1201 to achieve a light directing function.

 In FIG. 25, the light directing function display device 1 is schematically shown as being implemented as an optical display device.

 The light directing function display device 1 shown in FIG. 25 is composed of two or more spherical light receiving bodies 215, a thermal compression bonding 303, a molding hole 55, a linear three-dimensional light receiving body 9, and the like. It is characterized by.

 The light directing function display device 1 shown in FIG. 25 accommodates a light source 2500, and forms light beams such as 1200, 1201, 1202, and 1300 to achieve a light directing function. It is done.

In Fig. 26, the light directing function display device 1 is schematically shown as being embodied as a synthetic yarn of fabrics.

 The light directing function display device 1 shown in FIG. 26 includes two or more soft light receivers 221 and a light receiver 202 of color transparent material, a soft light receiver 221 and a colorless transparent material. The light receiving body 201, the adhesive bond 302 is bonded with an adhesive, characterized in that consisting of a molding groove (4).

 The light directing function display device 1 shown in Fig. 26 accommodates a light source 2500, and forms light beams such as 1201 and 1301 to achieve a light directing function.

27, 28, and 29 show that the light directing function display device 1 is made of a component material of the video display device.

 The light directing function display device 1 shown in Fig. 27 is a component material of a video display device, and is mounted between a front substrate A and a rear R.G.B panel B of a video display device.

The light directing function display device 1 is composed of two or more regular hexagonal holes (ACs), the light receiving body 201 and the inner vacuum space of the light receiving body 2 having a colorless transparent material. (2) is formed of a combination of the molded photoreceptor 605, and the black or the color of the light-receiving opaque material (205), 206 and a combination of the modeling receiver 610 of the colorless It is characterized by.

Pixels of the rear panel R.G.B panel B of the image display device may also be composed of pixels of the same regular hexagon (Pixel)-(B-C).

 28, the functional characteristics of the light directing function display apparatus 1 are shown and shown.

In the pixel of the rear RGB panel B of the video display device, colored light on the electric and electronic display acts as a light source 2500, so that the light-receiving member of black or no opaque material is present. Through the holes of the light receiving body 2, which is a combination of the 205, 206 and the molding light receiving body 610, the light receiving body 201 and the light receiving body 2 of the transparent material having no color Refraction modulation of colored light by converting the electromagnetic wave of the emitted light of the light receiving body 2 in the modeling light receiving body 605 into which the light receiving body 2 is filled in the inner vacuum space and passing through the front substrate A of the image display device. A light-receiving function characterized in that the light is transmitted through the transmitted light (1202), the light receiving body 201 of the transparent material having no color and the modeling light receiving body filled with the light receiving body 2 in the internal vacuum space of the light receiving body (2) In the hole in 605, the light receiver 2 in the hole is external physical Function to make the dynamic state repeating stop, movement and rotation in the directions of front, back, up, down, left and right by force, and display the dynamic state or refracting the refractive-modulated transmitted light 1202 of colored light. The main feature is to achieve.

 29, the production process of the light directing function display device 1 is shown schematically.

In the case of the front transparent molded light receiver (E-605) on the molded light receiver 605, which is composed of a combination of the light receiving body 201 and the molding light receiver 610 of a transparent material having no color,

Forming grooves 4 in which regular hexagons are repeated in the molding frame 400, and the transparent liquid specific functional liquid material 650 is sequentially repeatedly injected (A-1) to form the light receiving body 610 of the multilayer thin film. ), A light-receiving body (B-210) of a transparent multilayer thin film formed in the manufacturing process (B),

According to the secondary manufacturing process (C), after curing with a molding receiver 201, 610 of a transparent material having no color in the mold 400, the functional specific liquid material 650 and the fluorescent material (e ) Filled with the molded photoreceptor (E) of the regular hexagonal photoreceptors (201, 610) formed by mixing and coating (e-1),

Color-receiving light-receiving body 201, D-1 and colorless transparent light-receiving material 201, D-2 is combined, and the air is removed and vacuum-shaped, multi-layered thin film receiving body ( In the vacuum space of the E-605, the molding light receiver E-605 of the multilayer thin film filled with the molding light receivers E of (201, 610) is completed, and the inside of the sealed regular hexagon hole is completed. The vacuum molding hole 55 is characterized by constituting the front transparent molding receiver E-605, which is regularly repeated to form a shape.

Black back-lit molding receiver (E-610) consisting of a combination of black or colorless opaque material receivers 205, 206 and molding receiver 610 )In the case of,

Forming grooves (4) in which the regular hexagon is repeated in the molding frame (400), in the process of sequentially injecting a transparent liquid specific functional liquid material (650) in sequence (A-1), there is a black color or There is a black color of the multilayer thin film, which is cured in the manufacturing process (A-2) by sequentially mixing and curing the light-receiving materials 205 and 206 of the colorless opaque material, or A colored functional receiver 650 and a fluorescent substance (e) are mixed and coated (e-1) on the laminated modeling receiver 610, which is composed of the light-receiving members 205 and 206 of a colorless opaque material. A modeling light receiver (E-610) having a back black (E-610) in which the molding light receiver (E-610) of the multilayer thin film is completed and the molding hole 55 of an open regular hexagonal hole is repeated. It characterized in that the configuration.

The front transparent molding receiver (E-605) and the rear black (black) molding receiver (E-610) are combined by adhesive bonding 302 or various methods to form a light directing function display device (1). The flexible light receiving body 221 is formed, and the front transparent molding light receiver (E-605) and the back black molding light receiver (E-610) are bonded to each other (302). Or by combining in various ways, it is characterized by forming a curved, light-directing function display device 1, which can be implemented by the light receiving body 213 of two or more curved bodies.

In addition, the upper, front transparent molding receiver (E-605) and the back black molding receiver (E-610) have a nano-structured regular hexagonal hole having a side length of more than nanometers (nm). holes) to form a light directing function display device (1).

In addition, the above-mentioned embedding means that any one or more of the light receivers 2 of the light directing function display device 1 composed of two or more light receivers 2, the light receivers 2, 660, 6, etc. And a portion or the like of the processed light receiving body 2 is combined with each other in a liquid phase on a specific functional liquid material 650 to form the light receiving body 2 of the light directing function display device 1, and the light directing function display device. To the light receiver 2 of any one or more of the light receiver 2, such as (660), (6), embedded in the two or more light receivers 2 constituting (1), and the cut and processed light receiver (2) Two or more light receivers constituting the light directing function display device 1 to be embedded to form a shape of the light receiver 2 in which two or more light receivers 2 are combined or combined. There is a feature on the advantage that the one or more light receivers 2) can be freely rewritten.

For example, as shown in FIG. 29, a laminated modeling receiver 610 is combined or complexed with a receiver 2 such as 205 and 206 embedded in a specific functional liquid material 650 of the modeling mold 400. It is labeled.

The light directing function is displayed by the light directing function display device 1 by interpreting the above-mentioned "light directing function". Two or more light receivers 2 composed of the material constituting (1) are affected as light energy, and the light receivers 2 that receive light energy are spontaneous emission or thermal radiation emission in the optical phase. The electromagnetic radiation of the emitted light by (Thermal radiation emission) is formed to produce the electromagnetic waves of the emitted light of the two or more light-receiving bodies 2, and the light directing function is achieved as a principle of inducing a light directing function.

The conversion of the light energy radiated from the light source 2500 when the light energy radiated from the light source 2500 is converted into electromagnetic waves of the emitted light of the two or more light receiving bodies 2 constituting the light directing function display device 1. Is made by conversion of electromagnetic waves of the emitted light of the light receiving body 2 first contacted by the primary deformation, and the electromagnetic wave of the emitted light contacts the other light receiving body 2 by the secondary deformation, and emits the other light receiving body 2. While secondary conversion into electromagnetic waves of light, conversion of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device is sequentially performed.

The electromagnetic waves of the emitted light of the light receiving body 2 sequentially make the refractive phenomenon always deformed using the light receiving body 2 made of a material as a medium.

In addition, the electromagnetic waves of the emitted light of the light receiving body 2 which are sequentially formed are refracted and transmitted or reflected by the two or more light receiving bodies 2, and the light receiving body 2 is made of two or more light receiving bodies 2 made of a material. 2) A new combination of light consisting of electromagnetic waves of the emitted light repeats the dynamic movement, consisting of two or more light receivers 2 and the like, depending on the volume shape of the material, The secondary feature of forming the volume phenomena of light, in which electromagnetic waves are collected and displayed, forms an aggregate of light in a light directing function.

The light directing function of the light directing function display device 1 of the present invention is characterized in that, in the case of a transmissive action, electromagnetic waves of the emitted light of the light receiving body 2 generated by passing through two or more light receiving bodies 2 are formed on the light directing function. When the light directing function display device 1 has a part consisting of at least two light receivers 2, the light energy irradiated from the light source 2500 is emitted from one light receiver 2 The transmitted light which is backed out and transmits another one of the light receiving bodies 2 as the electromagnetic wave of the emitted light to form the electromagnetic wave of the secondary emitted light is classified as the transmitted light having the minimum light directing function of the present invention.

In addition, in the case of the reflective action, when any one of the light receivers 2 of the light directing function display device 1 composed of at least two light receivers 2 is made of a reflective material, the primary deformed light receivers ( The electromagnetic wave of the emitted light of 2) is in contact with the secondary as the electromagnetic wave of the emitted light of the light receiver 2, which is converted while the light energy irradiated from the light source 2500 is incident on any part of at least two light receivers 2. The minimum of the present invention is that reflecting the light receiving body 2 of the reflecting material and returning to any other part of the light receiving body 2 to form reflected light as electromagnetic waves of the emitted light of the light receiving body 2 is displayed. It was classified into the reflected light on the light directing function.

In the present invention, the light directing function can be briefly defined as that the light energy irradiated from the light source 2500 of the light emitted from the two or more light receiving bodies 2 constituting the light directing function display device 1 made of a material. The conversion of the electromagnetic wave to the creation of a new shape of light, which consists of electromagnetic waves of the emitted light, should be interpreted as a light directing function.

As mentioned above, although an exemplary embodiment of the present invention has been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may realize the present invention in another specific form without changing its technical spirit or essential features. It will be appreciated that it may be practiced. Therefore, it should be understood that one embodiment described above is illustrative in all respects and not restrictive.

※ Explanation of code ※

1: The light directing function display device which consists of an operation of light directing function, the operation of the display apparatus, and the implementation technology of the display apparatus. Abbreviated as light directing function display device,

2:: 201, 202, 203, 204, 205, 206, 211, 212, 213, 214, 215, 216 ,

Modeling receivers 660, 601, 602, 603, 604, 605 consisting of 217, 221, 222, 223, 224, etc.

Representative symbol of the light receiver, consisting of molding light receivers 6, such as 610, 611, 612, 613, 614, etc.

201: a light-receiving body of colorless transparent material,

202: a light-receiving body of a transparent material with color

203: a light-receiving member of a translucent material without color

204: the light-receiving body of the color translucent material,

205: a light-receiving body of opaque material without color

206: a light-receiving body of opaque material with a color

211: a polyhedron,

212: mixed light body of polyhedron and curved body,

213: light receiving body of a curved body,

214: mixed light body of a spherical body and a spherical body,

215: spherical light receiver,

216: mixed light body of spherical and polyhedron,

217: mixed photoreceptors of polyhedrons and spherical and curved bodies,

221: soft receiver,

222: semi-soft receiver,

223: semi-hard receiver,

224: hard light receiver,

3: Representation code of the coupling part, (301,302,303,304,305,306,307),

301: groove bonding,

302: adhesive bonding using adhesive,

303, 303a, 303b: hot press bonding,

304: bolted joint,

305: clasp engagement,

306: pin coupling,

307: weaving bonds,

400: molding frame,

4: molding groove,

5: molding hole,

44: a molding groove passing through two or more light receivers 2,

55: molding hole passing through two or more light receiving bodies 2,

6: Representative symbols such as molding receivers (601,602,603,604,605,610,611,612,613,614),

601: a modeling light receiving body in which an internal space is formed in the light receiving body 2,

602: Modeling light receiving body in which an internal vacuum space is formed on the light receiving body 2,

603: a modeling receiver in which a specific functional liquid material 650 is injected into the modeled internal space of the receiver 2,

604: Modeling light receiver in which a specific functional liquid material 650 is injected into the molded inner space of the light receiving body 2 and filled with at least one light receiving body 2,

605: Modeling light receiving body in which at least one light receiving body 2 is filled in the formed internal vacuum space of the light receiving body 2,

610: a molding receiver formed by cutting and processing a molding receiver 660 formed by curing a specific functional liquid material 650 in the mold 400,

611: A plastic light receiving body formed by displaying a regular or irregular wave shape by curing a specific functional liquid material 650 sequentially over time in a repetitive dynamic state in the operation molding frame 400,

612: The specific functional liquid material 650 and the one or more light receivers 2 are filled in the operation molding frame 400, so that the specific functional liquid material 650 and the one or more light receivers 2 are repeated in a dynamic state. Molded number formed by regular or irregular wave shape and one or more light receivers 2 being stopped and moved and rotated in various patterns in order to be cured in order, thereby displaying the operation shape of the one or more light receivers 2 which are regular or irregular. Bollard,

613: Glyphs such as (701), (702), (703), (704), (705), (706), (711), (722), (733), (744), (755), etc. Molded light receiving body formed by cutting and processing the light receiving body 2 in which the portion 7 is formed,

614: Specific functional liquid material 650 in molding grooves 4, 44, and molding holes 5, 55 formed in the light receiving body 2.

Molded photoreceptor formed by cutting and processing the photoreceptor 2 cured by filling

650: colorless transparent liquid material (651), colorless transparent liquid material (652), colorless translucent liquid material (653), colored translucent liquid material (654), color is A specific functional liquid material consisting of any one or more of an opaque liquid material 655, an opaque liquid material 656 having no color,

651: a transparent liquid material without color

652: a transparent liquid substance with color

653: colorless translucent liquid material,

654: a color translucent liquid material,

655: opaque liquid substance without color,

656: a opaque liquid material with a color

660: a molding light receiving body made by curing a specific functional liquid material 650 in the molding frame 400,

7: emblem (701, 702, 703, 704, 705, 706, 711, 722, 733, 744, 755)

701: Embossed Glyphs,

702: Engraved Glyph,

703: irregularities,

704: home pattern,

705: hole pattern,

706: protrusion pattern,

711: an embossed pattern formed through two or more light receiving bodies (2),

722: an intaglio pattern formed through two or more light receivers 2,

733: Uneven pattern formed through two or more light receiving bodies (2),

744: a groove pattern formed through two or more light receivers 2,

755: a hole pattern formed through two or more light receivers 2,

850: auxiliary light, (851,852,853) secondary light,

851: buried auxiliary light embedded in part of the light receiver 2 or in the light receiver 2,

852: non-embedded auxiliary light provided between two or more light receiving bodies 2 that are not sealed;

853: space buried auxiliary light installed in the molded inner space of the light receiving body 2,

8: a light directing function display device of a point-shaped three-dimensional light receiver consisting of two or more light receivers (2),

9: a light directing function display device of a linear three-dimensional light receiver consisting of two or more light receivers 2,

10: a light directing function display device of a planar three-dimensional light receiver consisting of two or more light receivers (2),

11: a light directing function display device of a multi-stereoscopic light receiver consisting of two or more light receivers (2),

1200: refraction-modulated transmitted light,

1201: refractive-type modulated transmitted light and color display transmitted light of the light receiving body (2),

1202: refraction-modulated transmission beam of colored light,

1203: refractive-type modulated transmission beam of colored light and color display transmission beam of light receiver 2,

1204: refraction modulated penetrating ultraviolet rays of ultraviolet light,

1205: refraction-modulated transmission infrared of infrared,

1300: refractive modulation modulated light,

1301: refractive-modulated reflecting light and color display reflecting light of the light receiving body (2),

1302: refractive modulation modulated light of colored light,

1303: refractive-modulated reflecting rays of colored light and color-display reflecting rays of the light receiving body 2,

1304: refraction modulated reflection ultraviolet rays of ultraviolet light,

1305: refraction-modulated infrared of infrared,

1400: split beam of refraction modulated transmission beam,

1401: split light of the refractive modulated transmitted light and the color display transmitted light of the light receiving body (2),

1402: split beam of refractive modulated transmission beam of colored light,

1403: split light of refractive-type modulated transmission light of colored light and color display transmission light of photoreceptor 2,

1500: split light of refraction-modulated reflected light,

1501: split light of the refractive modulated reflected light and the color display reflecting light of the light receiving body 2,

1502: dividing ray of refraction-modulated reflecting ray of colored light,

1503: split-light of refractive-type modulated reflecting ray of colored light and of color display reflecting ray of light receiving body (2),

1600: diffracted light in which transmitted light passing through two or more light receivers 2 is diffracted between narrow gaps of two or more light receivers 2,

1610: diffracted light in which the reflected light reflecting two or more light receivers 2 diffracts between narrow gaps of the two or more light receivers 2,

1700: scattered light of transmitted light passing through two or more light receivers 2,

1710: scattered light of reflected light reflecting two or more light receivers 2,

1800: Two or more transmitted rays or reflected rays, such as a kind of transmitted light passing through two or more light receivers 2 and a kind of reflected light reflecting two or more light receivers 2, cross or collide with each other and appear mixed or mixed. Cross mixed rays,

Claims (13)

1. The light directing function display device 1 which is a light directing function display device which consists of an operation of the light directing function which consists of two or more light receiving bodies 2, the operation of the display apparatus, and the implementation technology, such as the display apparatus,

   Irradiated with ultraviolet rays of sunlight, visible rays, infrared rays, and the like,

   Irradiated ultraviolet rays such as light bulbs, incandescent lamps, fluorescent lamps, LED lamps, visible light, infrared rays and colored light applied to the bulbs, incandescent lamps, fluorescent lamps, LED lamps, etc., which are irradiated;

   Including colored light of electric and electronic display devices to be irradiated,

   In some cases,

   UV rays, visible rays, infrared rays, and the like, which are reflected and irradiated to an object,

   It includes ultraviolet rays, visible rays, infrared rays, etc., such as light bulbs, incandescent lamps, fluorescent lamps, and LED lamps, which are current light emitting elements, which are irradiated and reflected on an object,

   Including colored light from electrical and electronic display devices that are reflected and irradiated to objects,

   Direct and indirect phases of light electromagnetic waves (light energy), etc.

   Receiving light source (abbreviated as light source 2500);

   The light receiver 2 of the light directing function display device 1, which is composed of two or more light receivers 2,

   It is characterized in that the specific functional liquid material 650 injected into the mold 400 is made of a cured molding light receiver 660,

   Color-receiving body 201 of transparent material without color as modeling light receiver 660, color-receiving body 202 of transparent material with color as modeling light receiving body 660, translucent transparent colorless as modeling light-receiver 660 The light-receiving material 203 of the material, the light-receiving material 204 of the translucent material with color as the molding light receiving body 660, the light-receiving material 205 of the opaque material without color as the molding light receiving body 660, the molding water Of the light-receiving member 206 of the opaque material with color as the housing 660,

   Consists of any one or more,

   The light receiver 2 of the light directing function display device 1, which is composed of two or more light receivers 2,

   Consisting of a molding light receiver 660,

   Polyhedron receiver 211, polyhedron and curved body mixed receiver 212, curved body receiver 213,

   Among the mixed light receiver 214 of the spherical body and the spherical body, the light receiving body 215 of the spherical body, the mixed light body 216 of the spherical body and the polyhedron, the mixed light body 217 of the polyhedron and the curved body, and the spherical body,

   It characterized by consisting of any one or more,

   The light receiver 2 of the light directing function display device 1, which is composed of two or more light receivers 2,

   Consisting of a molding light receiver 660,

   Among the soft light receiver 221, the semi-soft light receiver 222, the semi-hard light receiver 223, and the hard light receiver 224,

   Any one or more,

   The light receiver 2 of the light directing function display device 1, which is composed of two or more light receivers 2,

   The specific functional liquid material 650 injected into the mold 400 is made of a cured molding light receiver 660,

   Specific functional liquid material 650,

   Transparent liquid material without color (651), transparent liquid material (652) with color, translucent liquid material (653) without color, translucent liquid material (654) with color, opaque without color From a liquid material 655, a opaque liquid material with color 656, etc.

   The specific functional liquid material 650, characterized in that the specific functional liquid material 650 made of any one or more liquid substances,

   Transparent liquid material without color (651), transparent liquid material (652) with color, translucent liquid material (653) without color, translucent liquid material (654) with color, opaque without color A liquid material 655, a opaque liquid material 656 with a color, and the like, by repeatedly recombining,

   Characterized by being capable of displaying all visible colors or displaying multiple colors in combination of two or more colors;

   The modeling light receiver 660 constitutes the light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2,

   The modeling frame 400 and the modeling receiver 660 include functional characteristics of the receiver 2 such as 201, 202, 203, 204, 205, 206, and the like. do or,

   The modeling frame 400 and the modeling receiver 660 have the shape of the receiver 2 such as (211), (212), (213), (214), (215), (216) and (217). And volumetric features of the shape, or

   The molding frame 400 and the molding light receiver 660 include material characteristics of the light receiving body 2 such as 221, 222, 223, and 224.

   A light receiving body 2 of the light directing function display device 1 composed of two or more light receiving bodies 2;

   Modeling mold 400 and molding receiver 660,

   Polyhedron consisting of four or more planar polygons such as triangles, squares, and pentagons, curved surfaces of which all or part of the surface is curved,

   Spherical or spherical shaped like a ball

   Polyhedron, curved surface, spherical body, etc. are characterized in that it is displayed in the shape of various patterns mixed with each other,

   In the light directing function display device 1 composed of two or more light receiving bodies 2,

   Coupling portion 3 is formed, the kind of coupling portion 3,

   Groove coupling 301 which is etched in the light receiver 2 and has a shape in which two or more light receivers 2 are engaged with each other in a groove shape that forms a shape that is deeper than the surface of the light receiver 2 or deeply recessed. ), An adhesive bond 302 that combines two or more photoreceptors 2 using an adhesive adhesive,

   Heat-compression bonding 303 formed by pressing two or more light-receiving bodies 2 to each other by pressing the soft adhesive surfaces,

   As a configuration of bolts, two or more light receivers 2 are formed by using a bolt coupling 304 that forms a screw groove in the bolt and the light receiver 2 and rotates to each other, and a clasp having various shapes on the two or more light receivers 2. ) Shackle coupling (305) of the shape coupled to each other,

   Pin coupling 306 having a shape having a pin shape having a long and thin shape and a pin hole in at least two light receivers 2, penetrating the pins so that at least two light receivers 2 are bonded to each other,

   Woven bonds 307 of the shape weaving two or more light receiving bodies 2 together, etc.,

   The coupling portion 3 is formed on two or more light receiving bodies 2 constituting the light directing function display device 1;

   The shape of the coupling part 3, such as 301, 302, 303, 304, 305, 306, 307,

   If it is a surface, a spherical surface or a surface, it is characterized in that the surface is formed in the shape of various patterns mixed with each other,

   Adhesive use adhesive bond 302, bolt bond 304, shackle bond 305, pin bond 306, etc. which form the bond part 3, liquid adhesive, a bolt, a latch, a pin, etc.,

   The minimum length of one side of the light receiving body 2 which forms the shape by processing the light receiving body 2 or the like constituting the light directing function display device 1 and constitutes the light directing function display device 1 And nanometers (nm) or more.
2. The method according to claim 1,

   The light directing function display device 1 composed of two or more light receivers 2,

   Formed on the light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2,

   The deep recessed shape is formed on the surface of the light receiving body 2, and the deep recessed shape forms a long-lined shape and a planar shaped groove 4 having a constant area.

   Formed through the light-receiving member 2, it forms a hole or the like, and forms a planar shaped hole 5 having a linear shape and a constant area of elongated shape,

   The molding groove 4 is formed of molding grooves 44 formed through two or more light receiving bodies 2 constituting the light directing function display device 1,

   The molding hole 5 is formed of a molding hole 55 formed by passing through two or more light receiving bodies 2 constituting the light directing function display device 1,

   The shape of the molding grooves 4, 44, the molding holes 5, 55,

   A multi-faceted, spherical or spherical surface, a curved surface, a spherical surface, the spherical surface, the spherical surface, characterized in that the display is made in the shape of various patterns mixed with each other.
3. The method according to claim 1,

   The light directing function display device 1 composed of two or more light receivers 2,

   By operating the light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2,

   Molded light receiver 601 having an inner space in the light receiver 2,

   Molded light receiver 602 having an internal vacuum space formed in the light receiver 2,

   A modeling receiver 603 in which a specific functional liquid material 650 is injected into the modeled internal space of the receiver 2,

   A modeling receiver 604 in which a specific functional liquid material 650 is injected into the modeled internal space of the receiver 2 and filled with one or more receivers 2, etc.,

   Characterized in that it comprises a modeling light receiving body 605, etc. in which at least one light receiving body 2 is filled in the molded internal vacuum space of the light receiving body 2,

   Shapes such as modeling light receivers 601, 602, 603, 604, 605,

   Polyhedron, curved, spherical or polyhedral, curved, spherical, etc. are displayed in the shape of various patterns mixed with each other,

   The modeling light receivers 601, 602, 603, 604, 605, etc. form the light receiver 2 of the light directing function display device 1, which is composed of two or more light receivers 2, respectively. Characterized by forming,

   Modeling receivers 601, 602, 603, 604, 605, etc.

   Two or more light receivers 2 constituting the light directing function display device 1 are sealed to each other to form a molding light receiver 601, 602, 603, 604, 605, or the like. Light display function display device characterized in that.
4. According to claim 1,

   The light directing function display device 1 composed of two or more light receivers 2,

   The light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2,

   By the molding frame 400, the molding member 660 formed by curing the specific functional liquid material 650 injected into the molding frame 400 is cut and processed to form the molding member 610,

   By the motion molding frame 400, which repeats the movement, rotation or stop, movement, and rotation in various patterns, the specific functional liquid material 650 injected into the motion molding frame 400 is sequential over time in a repetitive dynamic state. The cured object is cut and processed to form a regular or irregular wave shape to form a molding receiver 611,

   The specific functional liquid material 650 and one or more light receivers 2 injected or filled in the operation mold 400 by the operation mold 400 which repeats movement, rotation or stop, movement, and rotation in various patterns. ) Is hardened sequentially over time in a repetitive dynamic state, and the filled specific functional liquid material 650 and one or more light receivers 2 move, rotate or stop, move, and rotate in various patterns to repeat regular or irregular shapes. The cutting object is formed by cutting and processing the molded object formed by displaying the operation mode of the specific functional liquid material 650 and the one or more light receivers 2, thereby forming the molded light receivers 612.

   Glyphs 7 such as 701, 702, 703, 704, 705, 706, 711, 722, 733, 744, 755, etc. Cut and processed the light receiving body 2 is formed to form a molding light receiving body 613,

   Cutting and processing the photoreceptor 2 formed by injecting or filling a specific functional liquid material 650 into the molding grooves 4, 44, and the molding holes 5, 55 formed in the photoreceptor 2. To form a molded light receiver 614,

   Shapes of the shaped light receivers 610, 611, 612, 613, 614 are shown in the shape of various patterns in which polyhedrons and surfaces, spherical bodies or polyhedrons, surfaces, spheres, etc. are mixed with each other. Done,

   The modeling light receivers 610, 611, 612, 613, 614, etc. form a light receiver 2 of the light directing function display device 1 composed of two or more light receivers 2; Light display function display device.
5. According to claim 1,

   The light directing function display device 1 composed of two or more light receivers 2,

   In the light receiving body 2 and the like of the light directing function display device 1 composed of two or more light receiving bodies 2,

   The pattern part 7 is formed,

   The shape of the pattern part 7

   An embossed pattern 701, which is etched in the light receiver 2, is etched or etched in contrast with the concave portion of the light receiver 2, and is markedly sharper than the concave portion of the light receiver 2. Made up,

   Etched in the light receiving body 2, characterized in that it forms a shape that is deeper than the surface of the light receiving body 2, forming a negative pattern 702,

   Concave and convex pattern 703, which is etched in the light receiver 2, characterized in that the concave and convex portions are formed at the same time,

   It is etched in the light receiver 2, characterized in that it forms a shape that is dug deeper or recessed deeper than the surface of the light receiver 2, it is characterized in that the shape and size of the shape smaller than the intaglio pattern 702 A hole pattern 705, characterized in that the groove pattern 704 is formed, and the hole pattern 705 is etched by the light receiver 2, and is displayed as a hole through the light receiver 2 to form a shape. ), And is formed on the light receiving body 2, and forms a protrusion pattern 706, characterized in that the shape is formed by sticking out or blowing out more than the surface of the light receiving body 2,

   An embossed pattern 711 forms an embossed pattern 711, characterized in that the embossed pattern 701 passes through two or more light receiving bodies 2 constituting the light directing function display device 1 to form a shape.

   The intaglio pattern 702 forms an intaglio pattern 722, which is characterized by passing through two or more light receiving bodies 2 constituting the light directing function display device 1 to form a shape.

   The uneven pattern 703 passes through two or more light receiving bodies 2 constituting the light directing function display device 1 to form a shape, thereby forming an uneven pattern 733.

   The groove pattern 704 passes through two or more light receiving bodies 2 constituting the light directing function display device 1, and forms a shape of the groove pattern 744,

   The hole pattern 705 passes through two or more light receiving bodies 2 constituting the light directing function display device 1, and forms the shape of the hole pattern 755; Glyphs 701, 702, 703, 704, 705, 706, 711, 722, 733, 744, 755 A light directing function display device in which a shape such as a face is displayed in a shape of various patterns in which a face, a surface, a face, or a face, a face, a face, or the like are mixed with each other.
6. According to claim 1,

   The light directing function display device 1 composed of two or more light receivers 2,

   In the light receiving body 2 and the like of the light directing function display device 1 composed of two or more light receiving bodies 2,

   Auxiliary light 850 consisting of a light bulb, incandescent lamp, fluorescent lamp, LED lamp, etc. can be installed,

   Auxiliary light 850,

   Buried auxiliary light 851 which is partially embedded in the light receiver 2 or in the light receiver 2,

   A non-embedded auxiliary light 852 provided between the light receiving bodies 2,

   It is characterized in that the space-filling auxiliary light (853) to be installed in the interior space of the light receiver (2), etc. can be provided,

   In the case of the buried auxiliary light 851, the buried auxiliary light 850 is embedded in a part of the light receiving body 2 of the light directing function display device 1 or inside the light receiving body 2 to form a display of the shape. What is characterized by forming the auxiliary light (851),

   In the case of the non-embedded auxiliary light 852, the non-embedded auxiliary light 852, which is provided between two or more light receivers 2 of the light directing function display device 1 in an open state and an unsealed space. Characterized by forming a,

   For space buried auxiliary light 853,

   And a space buried auxiliary light 853, characterized in that the space buried auxiliary light 853 can be installed in the modeled internal space of the light receiving body 2 of the light directing function display device 1. ,

   The space-filling auxiliary light 853 can be provided in the interior space of the molding light receiving body 6 such as 601, 602, 603, 604, 605, and the like.

   By applying color to light bulbs and lamps, or by adding color coatings such as toning coatings, such as incandescent lamps, fluorescent lamps, and LED lamps, the buried auxiliary light 851, the non-filled auxiliary light 852, and the space buried auxiliary light 853, etc. The auxiliary light 850 is characterized by being colored light,

   (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. Display light (visible light), ratio of one or more unit emission light having a light directing function

   Display light (ultraviolet rays, infrared rays) light display function of the display light (visible light) or non-display light (ultraviolet, infrared) of the auxiliary light 850, such as (851), (852), (853) Device.
7. According to claim 1,

   The light directing function display device 1 composed of two or more light receivers 2,

   Two or more light receivers 2 constituting the light directing function display device 1 form the coupling portion 3,

   Characterized in that it consists of a point-shaped three-dimensional light-receiving member (8) displayed in the shape of a point at an observation angle of 360 degrees up, down, left, and right,

   Two or more light receivers 2 constituting the light directing function display device 1 form the coupling portion 3,

   Characterized by consisting of a linear three-dimensional light-receiving member 9, which is displayed in a line shape at a viewing angle of 360 degrees up, down, left, and right,

   Two or more light receivers 2 constituting the light directing function display device 1 form the coupling portion 3,

   It consists of a planar three-dimensional light-receiving member 10, which is displayed in a plane shape at the observation angles of up, down, left, and right of 360 degrees,

   Two or more light receivers 2 constituting the light directing function display device 1 form the coupling portion 3,

   Consists of a three-dimensional light receiving body 11 of a compound three-dimensional shape, which is displayed by forming a compound three-dimensional shape consisting of two or more light receiving bodies 2,

   Forming the light directing function display device (1),

   The shape of the three-dimensional light receiving body 8 of the point shape, the three-dimensional light receiving body 9 of the linear shape, the three-dimensional light receiving body 10 of the planar shape, the three-dimensional three-dimensional light receiving body 11,

   Polyhedron, curved, spherical or polyhedron, curved, spherical, etc. light display function display device in the form of various patterns mixed with each other
8. The method according to any one of claims 1 to 7,

   The light directing function display device 1, which is composed of two or more light receiving bodies 2,

   (201), (202), (203), (204), (205), (206), (211), (212), (213), (214), (215), (216), (217 Modeling receivers 660, 601, 602, 603, 604, 605, 610, consisting of 221, 222, 223, 224, etc. And a light receiving body 2 corresponding to a molding light receiving body 6 such as 611, 612, 613, 614, etc.

   Modeling frame 400 and the specific functional liquid material 650, the coupling portion (3), such as (301), (302), (303), (304), (305), (306), (307), and Molding grooves (4), (44), molding holes (5), (55), (701), (702), (703), (704), (705), (706), (711), ( Pattern parts 7 such as 722, 733, 744, 755, auxiliary light 850, 8, 9, 851, 852, 853, etc. (10), (11), such as the light receiving body (2) of the point, line, surface, light emitting function display device 1 of the complex three-dimensional shape,

   By operating techniques such as manipulating the characteristics of materials, color, scale, volume and shape, position variation, etc., or combining or mixing and distributing the manipulated characteristics, etc.,

   The light energy irradiated from the light source 2500 is converted into electromagnetic waves of the emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1, so that the shapes of refraction, transmission, and reflection are variously modulated. Characterized in that,

   Refractive modulation modulated light (1200),

   Color-coded transmitted light 1201 of the refractive-modulated transmitted light and the light receiver 2,

   Refraction modulated transmitted light 1202 of colored light,

   Refractive-type modulated transmitted light of colored light and color-coded transmitted light 1203 of the light receiver 2,

   Refractive index modulation ultraviolet ray 1204 of ultraviolet rays,

   Infrared refractory modulated transmission infrared (1205),

   Refractive-modulated reflected light (1300),

   Color-coded reflected light 1301 of the refractive modulated reflected light and the light-receiving body 2,

   Refractive modulated reflected light 1302 of colored light,

   Refraction-modulated reflected light of colored light and color-coded reflected light 1303 of the light receiving body 2,

   Refraction modulated reflection ultraviolet rays (1304),

   Infrared Refraction Modulated Reflective Infrared (1305),

   Split beam of refraction modulated transmitted beam (1400),

   Split-beam 1401 of refractive-type modulated transmission beam and color display transmission beam of light receiver 2,

   Separation ray 1402 of the refractive-modulation transmission beam of colored light,

   Split-beam 1403 of refraction-modulated transmission beam of colored light and color display transmission beam of light-receiving member 2,

   Split rays of refraction-modulated reflected ray (1500),

   Split light 1501 of refracted modulated reflected light and color-coded reflected light of light receiver 2,

   Split light 1502 of refractive-modulated reflected light of colored light,

   Split light 1503 of refractive-type modulated reflected light of colored light and color-coded reflected light of light receiver 2,

   Diffracted light 1600 of transmitted light, diffracted light 1610 of reflected light,

   Scattered light 1700 of transmitted light, scattered light 1710 of reflected light,

   Such as a cross-mixed ray 1800 in which two or more transmitted rays, reflected rays, or the like cross each other or collide with each other to be displayed.

   Characterized in that it comprises a display light (visible light) or a non-display light (ultraviolet, infrared) of one unit output light of the light directing function,

   Light energy irradiated from the light source 2500 is converted, and made of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1,

   (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit of the corresponding light directing function,

   Visible light (visible light) or non-display light (ultraviolet, infrared), and

   Light energy or the like irradiated from the multiple light sources 2500 is converted into a combination of electromagnetic waves of emitted light such as two or more light receivers 2 constituting the light directing function display device 1,

   (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit light of the corresponding light directing function, or more,

   Combination of display rays (visible rays) or non-display rays (ultraviolet rays, infrared rays),

   Successively colliding with each other, or multiplexing or spectroscopy to achieve a light directing function,

   The light directing function, which remains or is displayed inside or outside the two or more light receiving bodies 2 constituting the light directing function display device 1, or until the destructive interference phenomenon or the kinetic energy is exhausted to its fullest extent. A light directing function display device comprising electromagnetic waves and the like of emitted light such as a light receiving body 2.
9. The method according to any one of claims 1 to 8,

   The light directing function display device 1 composed of two or more light receivers 2,

   (201), (202), (203), (204), (205), (206), (211), (212), (213), (214), (215), (216), (217 ), (221), (222), (223), (224), etc. Modeling light receiving body (660), (601), (602), (603), (604), (605), (610) A light receiving body 2 corresponding to a molding light receiving body 6 such as 611, 612, 613, 614, etc.

   Molding frame 400 and the specific functional liquid material (650),

   301, 302, 303, 304, 305, 306, 307, etc., coupling part 3 and molding grooves 4, 44, molding hole 5 , 55,

   Glyphs 7 such as 701, 702, 703, 704, 705, 706, 711, 722, 733, 744, 755, etc. Wow,

   Auxiliary light 850 such as 851, 852, 853, and the light receiving body 2 of points, lines, planes, and complex stereoscopic shapes of (8), (9), (10), and (11). ) Such as,

   By operating techniques such as manipulating the characteristics of the material, color, scale, volume and shape, positional change, etc., or combining or mixing and distributing the manipulated features, etc.,

   The light directing function display device 1 is first designed and operated,

   Subsequently displayed on the light directing function display device 1,

   Light energy irradiated from the light source 2500 is converted, and made of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1,

   (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit of the corresponding light directing function,

   Visible light (visible light) or non-display light (ultraviolet, infrared), and

   Light energy or the like irradiated from the multiple light sources 2500 is converted into a combination of electromagnetic waves of emitted light such as two or more light receivers 2 constituting the light directing function display device 1,

   (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. Unit light of the corresponding light directing function;

   Combination of display rays (visible rays) or non-display rays (ultraviolet rays, infrared rays),

   Successively collided with each other, or multiplexed, or spectroscopic to produce light

   The line manipulation technique of the light directing function display apparatus 1,

   Light energy irradiated from the light source 2500 is converted, and made of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1,

   (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit of the corresponding light directing function,

   Visible light (visible light) or non-display light (ultraviolet, infrared), and

   Light energy or the like irradiated from the multiple light sources 2500 is converted into a combination of electromagnetic waves of emitted light such as two or more light receivers 2 constituting the light directing function display device 1,

   (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit light of the corresponding light directing function, or more,

   The combination of display rays (visible rays) or non-display rays (ultraviolet rays, infrared rays),

   Successively colliding with each other or multiplexing or spectroscopically to achieve a light rendering function,

   We first designed and manipulated the light directing function,

   (201), (202), (203), (204), (205), (206), (211), (212), (213), (214), (215), (216), (217 ), (221), (222), (223), (224), Modeling Receiver (660), (601), (602), (603), (604), (605), (610), ( A light receiver 2 corresponding to a molded light receiver 6 such as 611, 612, 613, 614, etc.

   Molding frame 400 and the specific functional liquid material (650),

   301, 302, 303, 304, 305, 306, 307, etc., coupling part 3 and molding grooves 4, 44, molding hole 5 , 55,

   Glyphs 7 such as 701, 702, 703, 704, 705, 706, 711, 722, 733, 744, 755, etc. Wow,

   Auxiliary light 850 such as 851, 852, 853, and the light receiving body 2 of points, lines, planes, and complex stereoscopic shapes of (8), (9), (10), and (11). ) Such as,

   By operating techniques such as manipulating the characteristics of the material, color, scale, volume and shape, positional change, etc., or combining or mixing and distributing the manipulated features, etc.,

   In the light directing function display device 1,

   Characterized in that the light directing function is designed and manipulated first,

   By the post-operation technique of the light directing function display device 1,

   A light directing function display device capable of variously operating a light directing function display device (1).
10. The method according to any one of claims 1 to 8,

    The light directing function display device 1, which is composed of two or more light receiving bodies 2,

    Characterized in that the color, shape and shape of the light can be manipulated with at least two light receivers 2,

    At least two light receivers 2, including any one or more of the modeling light receivers 6 of 604, 605, 612, and 614 constituting the light directing function display device 1; (A), (202), (203), (204), (205), (206), and the functional characteristics of the light receiver (2),

    Characterized in that it includes the volumetric characteristics of the shape of the light receiving body 2 such as (211), (212), (213), (214), (215), (216), (217),

    It characterized in that it comprises the characteristics of the material of the light receiving body 2, such as (221), (222), (223), (224),

    Characterized in that the light receiving body 2 is formed of a molding light receiving body 660 which is cured and formed by the operation of the specific functional liquid material 650 by the molding frame 400,

    Consisting of molded light receivers 6 such as 601, 602, 603, 604, 605, 610, 611, 612, 613, 614, etc. Characterized by

    (8), (9), (10), (11), and the like, comprising a light receiving body (2) of a dot, line, surface, composite stereoscopic light directing display device (1), and the like. ,

    Displayed on at least two light receivers 2 constituting the light directing function display device 1,

    Molding Grooves (4), (44), Molding Holes (5), (55), (703), (704), (705), (706), (711), (722), (733), (74)

    4), characterized in that the pattern portion 7 such as 755 is displayed in the shape of various patterns in which a multi-sided surface, a curved surface, or a multi-sided surface, a spherical surface, a curved surface, etc. are mixed with each other,

    Characterized in that the auxiliary light (850), such as (851), (852), (853), which is provided on at least two light receiving member (2) forming the light directing function display device (1), characterized in that

    The color of light energy radiated from the light source 2500, the color of electromagnetic waves emitted from one of the two light receivers 2, and the other number of light receivers 2 While the electromagnetic waves of the emission light of the color of the electromagnetic wave emitted from the light collide with each other,

    Color matching, which is a combination of light, to achieve the color of the third light formed by the electromagnetic waves of the emitted light of the third toned light, the color of the light being different,

    When light energy irradiated from the light source 2500 is incident on at least two light-receiving bodies 2 constituting the light directing function display device 1,

    At least two photoreceptors 2 constituting the light directing function display device 1 react to form electromagnetic waves of emission light having the color of the two photoreceptors 2,

    It is characterized by being able to display all colors of light varying the wavelength of the visible light source,

    Installed on at least two light receivers 2 constituting the light directing function display device 1,

    Auxiliary light 850, such as (851), (852), (853) is characterized in that the electromagnetic wave of the emitted light,

    Light energy irradiated from the light source 2500 is converted, and made of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1,

    (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit of the corresponding light directing function,

    Visible light (visible light) or non-display light (ultraviolet, infrared), and

    Light energy or the like irradiated from the multiple light sources 2500 is converted into a combination of electromagnetic waves of emitted light such as two or more light receivers 2 constituting the light directing function display device 1,

    (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit light of the corresponding light directing function, or more,

    Combination of display rays (visible rays) or non-display rays (ultraviolet rays, infrared rays),

    Continuously, colliding with each other, or multiplexing or spectroscopically to achieve a light directing function,

    At least 2, forming the light directing function display device 1 by forming a coupling part 3 such as 301, 302, 303, 304, 305, 306, 307, etc. By forming the number of light receivers 2,

    Until at least two numbers of light-receiving members 2 constituting the light directing function display device 1 stay inside or be displayed, or until the destructive interference phenomenon or kinetic energy is exhausted by the function thereof,

    A light directing function display device in which electromagnetic waves, etc. of emitted light, such as the light receiving body 2, stay or are displayed inside or outside at least two numbers of light receiving bodies 2.
11. The method according to any one of claims 1 to 8,

    The light directing function display device 1, which is composed of two or more light receiving bodies 2,

    Ultraviolet rays irradiated from the light source 2500 stay inside or outside the light receiving body 2 of the light directing function display device 1;

    In addition, the characteristics of the ultraviolet light is characterized in that invisible,

    Forming holes 5, 55, or hole patterns 705, 755 corresponding to the ultraviolet wavelength band are formed in the light receiving body 2, etc. of the light directing function display device 1, so that the invisible multiple By only transmitting ultraviolet light,

    The electromagnetic waves of the emitted light such as the light receiver 2 having the color of the visible ray band in which light energy irradiated from the light source 2500 is converted into the electromagnetic waves of the emitted light such as the light receiver 2,

    Inside or outside the two or more light receiving bodies 2 constituting the light directing function display device 1,

    It is characterized by forming a spatial division of light while achieving the effect of spectral, which is distinguished and displayed by multiple invisible ultraviolet rays and the like,

    Forming grooves 4, 44, or groove patterns 704, 744 corresponding to the ultraviolet wavelength band are formed in the light receiving body 2, etc. of the light directing function display device 1, so that the multiple invisible By reflecting only ultraviolet light,

    The electromagnetic waves of the emitted light such as the light receiver 2 having the color of the visible ray band in which light energy irradiated from the light source 2500 is converted into the electromagnetic waves of the emitted light such as the light receiver 2,

    Inside or outside the two or more light receiving bodies 2 constituting the light directing function display device 1,

    It is characterized by forming a spatial division of light while achieving the effect of spectral, which is distinguished and displayed by multiple invisible ultraviolet rays and the like,

    To two or more light receiving bodies 2 constituting the light directing function display device 1,

    Infrared rays emitted from the light source 2500,

    While colliding or multiplexing each other with electromagnetic waves and the like of the emitted light of the light receiver 2 obtained by converting light energy emitted from the light source 2500,

    Due to characteristics such as heat radiation emission of invisible infrared rays, the light source 2 is contacted from inside or outside.

    When heated air rises,

    Inside or outside the light directing function display device 1, electromagnetic waves of the emitted light, such as the light receiving body 2,

    Light display function display device to achieve a light-directed function by achieving a specific phenomenon, such as haze, by being displayed as a distorted refractive phenomenon in the air surface in contact.
12. The method according to any one of claims 1 to 8,

    The light directing function display device 1 composed of two or more light receiving bodies 2, in which the minimum length of one side is more than nanometers (nm),

    It is characterized in that the light directing function display device 1 is formed of two or more light receiving bodies 2 or the like composed of ultra-small nanoparticles.

    Coupling portions 3 such as 301, 302, 303, 304, 305, 306, 307, etc. are formed in two or more light receiving bodies 2 composed of ultra-small nanoparticles. Or

    Molding grooves 4, 44, molding holes 5, 55, 703, 704, 705, 706, etc. Glyphs 7 such as 711, 722, 733, 744, and 755 are formed,

    (201), (202) of micro-nanoparticles, wherein at least two light-receiving bodies (2) composed of micro-nanoparticles are formed by curing a specific functional liquid material (650) by a molding frame (400) consisting of micro-nanoparticles. ), (203), (204), (205), (206), (211), (212), (213), (214), (215), (216), (217), (221), Consisting of molding light receivers 660 such as 222, 223, and 224,

    Modeling light receivers 6 such as 601, 602, 603, 604, 605, 610, 611, 612, 613, 614, etc. Characterized in that it consists of particles

    (8), (9), (10), (11), etc., which constitute the light directing function display device 1 in the form of dots, lines, planes, and composites

    A light directing function display device comprising two or more light receiving bodies (2) made of ultra-small nanoparticles.
13. The method according to any one of claims 1 to 8,

    The light directing function display device 1, which is composed of two or more light receiving bodies 2,

    Characterized in that electrical, electronic and mechanical devices can be attached to two or more light receiving bodies 2 constituting the light directing function display device 1,

    Electrical, electronic, and mechanical devices attached to two or more light receiving bodies 2 constituting the light directing function display device 1 move or rotate, stop, or move in the forward, backward, up, down, left, and right directions. When you make a dynamic change that repeats the rotation,

    The two or more light receivers 2 constituting the light directing function display device 1 also make dynamic fluctuations,

    Characterized in that the electromagnetic waves of the emitted light, such as the light-receiving body 2 constituting the dynamic fluctuation, interfere with each other to form a regular or irregular dynamic fluctuation,

    By electric, electronic and mechanical devices attached to two or more light receiving bodies 2 constituting the light directing function display device 1, etc.,

    Consisting of electromagnetic waves of emitted light, such as the light receiving body 2, which make a dynamic variation,

    Light energy irradiated from the light source 2500 is converted, and made of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1,

    (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. The display light (visible light) or non-display light (ultraviolet light, infrared light) of one unit emission light of the corresponding light directing function collides with each other, or is multi-associated or spectroscopically

    Characterized in that it achieves a light directing function on the dynamic variation,

    By electric, electronic and mechanical devices attached to two or more light receiving bodies 2 constituting the light directing function display device 1, etc.,

    Electromagnetic waves of the emitted light, such as the light receiving body 2 to which the light energy irradiated from the light source 2500 is converted, are configured to be incident or multi-combination continuously,

    Consisting of electromagnetic waves of emitted light, such as the light receiving body 2, which make a dynamic variation,

    Light energy irradiated from the light source 2500 is converted, and made of electromagnetic waves of emitted light such as two or more light receiving bodies 2 constituting the light directing function display device 1,

    (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit of the corresponding light directing function,

    Visible light (visible light) or non-display light (ultraviolet, infrared), and

    Consisting of electromagnetic waves of emitted light, such as the light receiving body 2, which make a dynamic variation,

    Light energy or the like irradiated from the multiple light sources 2500 is converted into a combination of electromagnetic waves of emitted light such as two or more light receivers 2 constituting the light directing function display device 1,

    (1200), 1201,1202,1203,1204,1205,1300,1301,1302,1303,1304,1305,1400 ), (1401), (1402), (1403), (1500), (1501), (1502), (1503), (1600), (1610), (1700), (1710), (1800), etc. One unit light of the corresponding light directing function, or more,

    Combination of display rays (visible rays) or non-display rays (ultraviolet rays, infrared rays),

    In succession, colliding with one another or multiple

    The dynamic fluctuation image remains until the internal or external display of two or more light receiving bodies 2 constituting the light directing function display device 1 is displayed, or until the destructive interference phenomenon or the kinetic energy is exhausted by its function. , Light directing function display device which makes a light directing function.

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