• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The object of the present invention is a light-material coupling and emitting apparatus for coupling and emitting light and a material. The object of the present invention is to use the light coupled with a gaseous material or a material in a certain state. According to the present invention, the light is coupled with a gas, a liquid or any state (plasma state) of the material, and the coupled light and the material are emitted towards a target object or a predetermined region. When it reaches the target object or the predetermined region, the material reacts with other material that exists around the target object or the predetermined region. According to one embodiment, when the light coupled with a first material is emitted from the light-material coupling and emitting apparatus, the first material coupled with the light is detached from the light and then reacts chemically with a second material. The device uses a specific effect caused by this chemical reaction. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2718579A2
    申请号:ES201831192
    申请日:2018-12-10
    公开日:2019-07-02
    发明作者:Jong Duck Park;Young Choon Kim
    申请人:Jong Duck Park;Young Choon Kim;
    IPC主号:
    专利说明:

    [0001]
    [0002]
    [0003] Technical sector
    [0004]
    [0005] The present invention relates to an apparatus for coupling and emitting light and material. More specifically, the present invention relates to an apparatus for coupling a beam of light and a material in any state, for example a gaseous, liquid or solid material, and emitting the coupled light and material.
    [0006]
    [0007] Background of the invention
    [0008]
    [0009] Unless otherwise indicated, the contents set forth in this section are not prior art with respect to the claims of this application. Consequently, the contents set forth in this section should not be interpreted as prior art by the mere fact of being described in this section.
    [0010]
    [0011] In physics, the term "light" refers to electromagnetic radiation of any wavelength, and light exhibits the properties of waves, such as reflection, refraction, interference, diffraction, and Doppler effect. Light of relatively short wavelengths it propagates in a straight line.When the light propagates through a medium and passes to a different medium, a part of the light is reflected and another part is refracted at the interface between the different media. a wave or a particle has been in effect for a long time. The theory of light particles and the theory of pulses of light strongly opposed each other in the seventeenth century, but supporting Newton the theory of particles prevailed during the century XVIII In the nineteenth century, however, Thomas Young's "double slit" experiment led to wave theory, and Maxwell argued in electromagnetic theory that light was a form of radiation. electromagnetic ion. In the twentieth century, particle theory was again confirmed by Planck's quantum theory, and since then the wave-particle duality of light, which exhibits properties of both waves and particles, is generally accepted. Light basically exhibits properties of straight line propagation, reflection and refraction. Recently, research has been conducted on experiments to stop or confine light using the nature of light.
    [0012] Description of the invention
    [0013]
    [0014] The present invention consists in using light coupled with a gaseous material or a material in a certain state (powder of a solid). The light is coupled with a gas, a liquid, or a material in any state (plasma), and the coupled particles of light and material are emitted towards a target object or a predetermined region. When the coupled light and material reach the target object or the predetermined region, the material reacts with another existing material around the target object or the predetermined region.
    [0015]
    [0016] Additionally, in one embodiment, when the light coupled with a material is emitted from a light-material coupling and an emitting apparatus towards a target object, the material coupled with the light is released from the light due to the collision of the light with the target, and materials separated from light react chemically with each other or with an existing material in the air.
    [0017]
    [0018] Additionally, in order to allow the light coupled with the material and retained in a coupling unit to propagate through the coupling unit, the temperature, current and the like of the coupling unit are controlled to increase the transmittance of said unit.
    [0019]
    [0020] A light-material coupler and emitter apparatus, according to one of the embodiments, controls the emission of light coupled with material, thus also controlling a temperature around a target object and purifying the air around said object.
    [0021]
    [0022] In particular, the light-material coupler and emitter apparatus provides energy to a stimulation medium, such as a gas, a liquid or a semiconductor material and directs the light to the stimulation means so that the light is transformed to possess a single wavelength and the property of traveling in a straight line. When the mass of the material to be coupled with the light is greater than a predetermined value, the intensity and wavelength of the light are controlled to compensate for an excessive mass so that the light and the material can be coupled to each other. other easily. Additionally, the light-material coupler and emitter apparatus provides energy to a stimulation means to generate a light with a single length of wave and resonate said light with another wave of light to increase the coupling force between the light and the material. On the other hand, a diaphragm is installed at one end of a material that retains the light to control the mass of the material (for example, explosives) that is to be coupled with the light, thus causing friction with the light and intensifying an electrostatic effect , which will result in an increase in the coupling force between the light and the material.
    [0023]
    [0024] Additionally, in the apparatus, the coupling surface between the light and the material, in which the light remains, forms a limit point state between the transmission and the absorption of the light. In the limit point state, the light is not transmitted, absorbed or reflected.
    [0025]
    [0026] Additionally, the light-material coupler and emitter apparatus operates in such a way that the light rays coupled with the materials are emitted to cross each other in a position in space or to collide with an object, such as a building so that The materials coupled with the light rays can detach from the light rays and then react chemically with materials dispersed in the air. Additionally, the light rays coupled respectively with different materials are emitted to collide with one another in a position in space so that the materials can detach from the light rays and once separated they can react chemically with each other.
    [0027]
    [0028] Additionally, the light-material coupling and emitting apparatus couples light rays with hydrogen and emits said rays to a position in space such that the light rays can collide with each other and the hydrogen separated from the light rays can react with the oxygen in the air and form water molecules (H2O). Water molecules disperse in the air, creating a screen effect. When a monitor's light is emitted to the water molecules, it is possible to display a monitor display screen in the air.
    [0029]
    [0030] As described above, the light-material coupler and emitter apparatus couples the light with a material and emits the light coupled with the material, so that the environment around a target can be purified, using a phenomenon that occurs when a second material collides with the material separated from the emitted light when said light collides with a target, carrying light and a scent around a person, obtaining a temperature control effect causing absorption or emission of heat in the air, or by displaying a monitor screen in the air.
    [0031]
    [0032] The effects, features and advantages of the present invention are not limited to the effects, features and advantages described above, and other effects, features and advantages may be derived from the following detailed description or the configurations cited in the appended claims.
    [0033]
    [0034] Brief description of the figures
    [0035]
    [0036] The foregoing and other objects, features and advantages of the present invention will be more clearly understood from the following detailed description considered in conjunction with the accompanying drawings, in which:
    [0037]
    [0038] Fig. 1 is a block diagram illustrating a data processing procedure carried out in a light-material coupler and emitter apparatus that couples light particles and material particles and emits the coupled particles, in accordance with an embodiment of The present invention.
    [0039]
    [0040] Figure 2 is a view illustrating an application example of the light-material coupling and emitting apparatus according to an embodiment of the present invention.
    [0041] The figures from 3A to 3E are views illustrating operations of the light-material coupler and emitter apparatus according to an embodiment of the present invention.
    [0042]
    [0043] The figures from 4A to 4E are conceptual diagrams illustrating the coupling and emission (irradiation) of light and material in a system according to an embodiment of the present invention.
    [0044]
    [0045] The figures from 5A to 5D are views illustrating embodiments of the present invention in which the light particles coupled with material particles are emitted and subsequently the material particles are separated from the light particles when the light coupled particles and material reach a goal.
    [0046]
    [0047] The figures from 6A to 6G are views illustrating examples of application of the present invention.
    [0048] Description of preferred embodiments
    [0049]
    [0050] The advantages and features of the present invention and how to achieve them will become apparent with reference to the embodiments described in detail below and the accompanying drawings. The present invention, in any case, can be carried out in many different ways and should not be construed to be limited to the embodiments set forth herein. Rather, these embodiments are provided so that the present disclosure is thorough and complete and the concept of the invention is fully transmitted to those skilled in the art. Accordingly, the present invention will be defined exclusively by the scope of the appended claims. Similar numbers refer to similar elements throughout the following description in this document. Furthermore, when describing embodiments of the present disclosure, well-known functions or constructions will not be described in detail as they could unnecessarily obscure the essence of the present invention. The following terms are described in consideration of the functions of the embodiments of the present invention and may accordingly vary according to the intentions of the users, operators or the like. Therefore, the definition of each term should be interpreted based on the contents presented throughout this description.
    [0051]
    [0052] Fig. 1 is a block diagram illustrating a data processing procedure carried out in a light-material coupler and emitter apparatus that couples light particles and material particles and emits the coupled particles, in accordance with an embodiment of The present invention.
    [0053]
    [0054] With respect to Figure 1, a light-material coupler and emitter apparatus 100, according to an exemplary embodiment of the present invention, includes a controller 50, an emission unit 40, and a coupling unit 30. In one embodiment Exemplary, the light 10 to be coupled with a particular material is not limited to visible light but may be radiation of any wavelength range, from radio waves to gamma rays. In addition, in the exemplary embodiment, the apparatus 100 additionally includes a stimulated emission system to transform spectral radiation into controlled radiation that travels in a straight line and has a narrow spectrum centered around a single wavelength. The stimulated emission system is controlled according to an exemplary embodiment. Alternatively, spectral radiation can be used as it is without including a technique. of stimulated emission. The material 20 can be any form of matter that can be coupled with the light. For example, it can be a gas, a liquid or a solid. The functions of the coupling unit 30 couple the light 10 and the material 20. The emission unit 40 includes an X-axis driving unit and a Y-axis driving unit, which are used to target the light coupled with the material. At a certain point. The controller 50 controls the emission unit 30, the coupling unit 40, the light 10, and the material 20. To this end, the controller 50 controls a series of data processing operations necessary to couple the light and the material. Figure 2 is a view illustrating an application example of the light-material coupling and emitting apparatus according to an embodiment of the present invention.
    [0055]
    [0056] As illustrated in Figure 2, in order to remove mice from a building, an odorous material that has a specific effect on mice is coupled with light, and light and odorous material are emitted together towards Mice around the building. Then a beam of light and the material coupled reaches the building and the material coupled with the light is separated from it and dispersed to repel or kill the mice.
    [0057]
    [0058] Figure 3A illustrates components of the light-material coupler and emitter apparatus. The numerical reference 10 refers to the light, the numerical reference 11 denotes a light source in the on state, and the numerical reference 12 denotes a light source in the off state. The numerical reference 13 denotes a means of stimulation to transform the light emitted by the light source 11 into a beam with a single wavelength that travels in a straight line. The stimulation medium 13 may be a liquid, gaseous or semiconductor material, which may vary depending on the embodiments. Numerical reference 14 denotes the energy to cause stimulated emission. Energy 14 stimulates the stimulation medium to emit light of a single wavelength. In an embodiment in which spectral radiation is used as it is, energy 14 is not necessary.
    [0059]
    [0060] The controller 50 controls the power supply status according to the class and density of the stimulation medium and in accordance with the target values of various parameters to cause stimulated emission. A reflector 15 is used to increase the emission efficiency in the stimulated emission process. The reference numeral 31 denotes a confinement unit for confining particles of material and particles of light. The confinement unit 31 moves in a predetermined direction when it confines particles of light and particles of material and moves in a different direction when it allows light to move towards the coupling unit 32, thereby causing stimulated emission. The coupling unit 32 refers to a material to retain the light inside. The numerical reference 21 denotes a power unit that feeds the device material. The coupling unit 32 is tuned to have a limit point between transmission, absorption and reflection of light. That is, at the limit point, there is no transmission or absorption of light. When the light reaches the limit point, the light does not propagate but remains and vibrates in a region due to the properties of both the particles and the (electromagnetic) light waves. That is, the light cannot move forward but remains in the same place. This vibration leads to friction with light. Thus, in one embodiment, a diaphragm (vibration plate) 33 is incorporated to improve the effect of vibration at the limit point of the material, which increases the effect of light friction.
    [0061]
    [0062] Alternatively, the friction effect is increased by a design in which the limit point is arranged in a material that can vibrate at a frequency of terahertz. When the friction between the light and the material appears, an electrostatic effect occurs, resulting in a coupling between the light particles and the material molecules. When the mass of a particle of material to be coupled with a first ray of light is greater than a reference mass to a certain degree, the first ray is resonated with a second ray in intensity, amplitude and wavelength to increase the coupling force of light and material, compensating for the excess mass of the material particle. On the other hand, when the vibration effect is adjusted to a certain target value, even particles of material that have a relatively large mass can be coupled with the particles of light. The controller 51 checks the resonance state of the wavelengths of a first ray of light, a second ray of light and so on up to a nth ray of light, and controls the energy supplied to the stimulation means 14 to increase the effect of resonance. When a control command is issued to issue a beam of light particles coupled with material particles, the controller 51 controls the temperature and current that are applied to the coupling unit to supply power to the material so that the transmittance factor of the material is increased. As a result, the transmittance of the material increases to exceed the absorption rate and therefore the light trapped in the material can be emitted.
    [0063] In a system of Figure 3B, when a stimulated energy emission 14a is supplied to a stimulation means and a light source 11a is turned on so that spectral radiation is emitted to a stimulated emission unit, the spectral radiation is transformed into controlled radiation centered around a single wavelength that has the property of moving in a straight line due to the stimulated emission effect. In this case, according to one embodiment, the controller controls the stimulation means, the energy stimulation, the light and the like to meet the objective values of the wavelength and the linearity of light propagation. The light passing through the stimulated emission unit slows down and remains in a material (i.e., the coupling unit 32a).
    [0064]
    [0065] Figure 3C illustrates a system in which the process that is executed in Figure 3B is repeated once more. Through this repetition, it is possible to promote the synthesis and resonance of light and improve the coupling force between the light and the material. The repetition count can be increased two, three, or as many times as necessary. On the other hand, through the coupling and resonance of the light, the amplitude of the light waves can be increased to a certain extent, so that a wind effect can be obtained.
    [0066]
    [0067] Figure 3D illustrates a state in which a light source 11c is turned off. In this state, a single wavelength light with the property of traveling in a straight line, produced by the systems of Figures 13B and 13C, will be fixed on the material of the coupling unit 32c. Then, the confinement unit 31 whose first position is shown in Figure 13a moves in one direction so that it is positioned as the confinement unit 31c, whereby light and material are confined in the same space. The numerical reference 21c denotes an input through which the material is fed to be coupled with the light. According to one embodiment, a gas, a liquid, or a solid (for example, red pepper powder) is introduced into the apparatus through the inlet. Numeric references 17c and 18c denote states in which the light remains in the coupling unit 32c. Due to the effects of the systems of Figures 3B and 3CD, that is, due to the resonance of the intensity and wavelength of the light, the coupling force between the light and the material and the intensity of the light are increased . The numerical reference 17c denotes a state in which particles and waves (electromagnetic waves) 18c of the light remain and vibrate on the surface of the unit of coupling The numerical reference 22c denotes a state in which the introduced material is coupled with the light waves. The concept of coupling between the light and the material will be described in more detail below. Figure 3E is a diagram illustrating a light emission process coupled with a material. A controller 32d cancels the limit point effect by confining the light by adjusting the temperature, current, energy or other parameters, which allows the light to be transmitted beyond the limit point.
    [0068]
    [0069] The figures from 4A to 4E are conceptual diagrams illustrating the concept of coupling and emission (irradiation) of light and material in a system according to an embodiment of the present invention.
    [0070]
    [0071] To aid in the understanding of the embodiments, the description of Figures 3A to 3E is complemented below. One of the conditions for coupling the light and the material is that the light and the material must remain in the same space for a certain period of time. The speed at which light passes through a material is inversely proportional to the light absorption coefficient of the material. When the light strikes the surface of a certain material, it normally passes through or is reflected by that surface. In any case, when the emission of light stops, said phenomenon (transmission and reflection) on the surface of the material disappears immediately. In embodiments, the terms "confine the light" or "retain the light" mean a state in which the light does not fade from the surface of the material but is trapped on said surface when the emission of light from a source of Light is interrupted.
    [0072]
    [0073] In the figures from 4A to 4E, the numerical references 17a, 18a, 17b, 18b, 17c, and 18c do not denote remaining images of light, but a light retention effect in each of the embodiments of the present invention. That is, the surfaces that retain the light, that is, the coupling surfaces of light and material 32a, 32b and 32c form a limit point between transmission and absorption of light. Specifically, when the limit point between transmission and absorption is reached, the light remains on the retention surface as if it were confined. Therefore, at this point, neither transmission nor light absorption occurs. At that time, even the reflection of light does not take place. The effect obtained with light retention will be described with reference to Figures 4A to 4E.
    [0074] Figure 4A illustrates a state in which a single wavelength straight line light 11a is directed towards the coupling surface 32. The coupling surface 32 is a surface of material that is tuned to be at the limit point in the that there is no absorption, transmission or reflection of light.
    [0075]
    [0076] Figure 4B illustrates a state in which the light 17a remains as if it were confined in a region 32a. At this time, the light waves 18a also remain, and the light source 11a is off.
    [0077]
    [0078] Figure 4C illustrates a state in which the light emitted by a source 11b moves to points 17a and 18a near region 32a. In the system of Figure 4C, the light emitted by the light source 11b is a single wavelength light that travels in a straight line.
    [0079]
    [0080] Figure 4D illustrates a state in which the light emitted by the light sources 11a and 11b are combined with each other in the coupling unit 32c. At this time, since the wavelengths and frequencies mentioned are identical, the light resonance effect appears. The vibration of the retained light intensifies due to the resonance effect. At this point, an electrostatic phenomenon appears due to friction between the light and the coupling unit 32c.
    [0081]
    [0082] Depending on the state of the material to be coupled with the light, a diaphragm (vibration plate) 33 is controlled to increase the electrostatic effect. That is, the vibration intensity of the tuned material to retain the light is increased to increase friction between the diaphragm and the light. According to these embodiments, the vibration frequency of the light and the vibration frequency of the material are controlled so that they are identical and cause resonance between the light and the material. In this way, the intensity of the light and the coupling force between the light and the material are increased. The confinement unit 31c moves along a predetermined path to one side so that a coupling space can be closed. A material to be coupled with the light is introduced into the space through an entrance 21c. In this case, the material to be coupled with the light can be a gas, a liquid or a solid (in a specific state) according to the objects of the embodiments. When negatively charged (-) material molecules approach light, positive (+) charges of light waves migrate to the material, and negative (-) charges migrate to the opposite side. Therefore, the negatively charged (-) material molecules and positive (+) charges of light waves are coupled with each other.
    [0083]
    [0084] Figure 4E illustrates a state in which a switch of a controller 53d is turned on to allow the light that is coupled with the material to propagate. As a result, the limit point state between transmission and absorption of light changes abruptly to a state of transmission in which light can pass through the material. In order to emit the light with maximized resonance, the controller controls the instantaneous current supplied to the coupling unit 32d or increases the temperature of the coupling unit 32d. Then, the limit point state in which the light is retained collapses, and the light can travel to an objective point. At this time, since the transmittance is maximized, the material 22d coupled with the light can be emitted together with the light waves 19d.
    [0085] The figures from 5A to 5D are views illustrating an operating example of an embodiment of the present invention in which the light particles coupled with the material particles are emitted, and then the material particles are detached from the particles. of light when the coupled light and the coupled material particles reach an objective point.
    [0086]
    [0087] A method of coupling a material and light, a light emission unit, and a method of decoupling light and a material from each other, are not limited to the examples illustrated in Figures 5A through 5D. Figure 5A illustrates an example in which the light coupled with a material is directed towards a building so that it collides with said building, the material is released from the light when it collides with the building such that the material disperses around of the building.
    [0088]
    [0089] Figure 5B is an example in which a first ray of light coupled with a material is emitted towards a target point, a second ray of light having a certain temperature is emitted so that it crosses the first ray of light, the material is released of the first ray in an area where the first and the second ray of light intersect each other. Figure 5C is an example in which a first ray of light coupled with a material of interest and a second ray coupled with the material of interest are emitted so that they cross each other at a certain point in space, the material is detached of the first and second rays, due to the collision between both rays of light, and the material that emerges from said rays of light reacts chemically with certain material (for example, oxygen, nitrogen, etc.) dispersed in the air. The figure 5D is an example in which visible light of a specific color is coupled with a material, and the coupled light and material are emitted together. There may be several combinations of lights and emitted materials and there may be several methods of separating the material from the coupled light.
    [0090]
    [0091] The figures from 6A to 6G are diagrams illustrating examples of application of the present invention.
    [0092]
    [0093] Figure 6A illustrates an example in which an odorous gaseous material 22 that repels mice or rats or that has an insecticidal effect, is coupled with a beam of light and said beam of light is emitted to hit a building. When the beam of light hits the building, the material is released from the beam of light and scattered around the building, repelling or killing mice or rats. The application of the present invention is not limited to the eradication of mice or rats. That is, the present invention can be used for the elimination of mosquitoes, flies and other insects.
    [0094]
    [0095] Figure 6B illustrates an example of adjusting the atmospheric temperature on a building causing the chemical reaction of a material coupled with a beam of light.
    [0096]
    [0097] As illustrated in Figure 6B, a first ray of light emitted from the left side and a second ray of light emitted from the right side intersect each other at a point on a target building so that the first ray of light and the second ray of light can collide with each other. Thus, a material coupled with the first ray of light and a material coupled with the second ray of light react chemically with each other. This chemical reaction causes heat generation or absorption, thus obtaining a temperature control effect around the building. That is, using the heat of reaction of a chemical reaction, a cooling and heating effect is obtained. Figure 6C illustrates an example in which the light rays are caused to remain at a point on a coupling surface of a coupling unit causing resonance between the waves of the light rays 19 and 19d, thereby increasing the amplitudes of light waves to the point that they are perceived by a person. When the light rays are emitted to collide with a person, it is possible to obtain a wind effect without natural wind.
    [0098]
    [0099] On the other hand, according to one embodiment, a material to be coupled with a beam of light is an odorous gas that emits a beach aroma 22d. In this case, when the lightning strikes a human body, the person can smell a beach.
    [0100]
    [0101] Figure 6D illustrates an effect in which a monitor screen is displayed in the air. As illustrated in Figure 6D, according to one embodiment, the hydrogen-coupled light particles are emitted from the left side and the right side so that they cross each other at a point in space. Thus, the particles of light collide with each other at that point. At that time, hydrogen is released from the particles of light and reacts with the oxygen present in the air. Thus forming water molecules (H2O). Water molecules create a screen effect in the air. That is, when a monitor light is emitted from the central part towards the generated water molecules, a monitor screen can be formed in the air. In this case, when the monitor light to display the word “LOVE” is emitted, due to the properties of the light that has a unique wavelength and moving in a straight line, which is produced by the system illustrated in the figure 3, the effect of Figure 6D can be obtained according to the distribution of the water molecules that have a screen effect, the sharpness of the monitor light, and the intensity of the light. Figure 6E illustrates an example in which the present invention is used to control the movement of migratory birds and the like in order to cope with avian influenza. As illustrated in Figure 6E, a material that repels birds is coupled with a beam of light, the beam emission angle is adjusted using a rotation unit so that the beam of light can be emitted towards an area of air through which birds move. When the birds enter the area, the ray of light hits or illuminates the birds, or the material coupled with the light influences the birds., Thus controlling the direction in which the birds fly.
    [0102]
    [0103] Figure 6F illustrates an example in which a beam of light coupled with a material is emitted to a coordinated position in a radar machine by means of an adjustment in the angle of emission of the beam of light using an X-axis rotation unit and a Y axis rotation unit such that the light beam hits a missile in a case where the missile has been launched.
    [0104]
    [0105] When the particles of an explosive material or a bomb-like material are coupled with light particles and then emitted towards a missile, it is possible to start the missile explosion in the air causing the collision between the missile and the material particles.
    [0106] Figure 6G illustrates an embodiment in which a beam of light emitted from a light device such as an LED lamp is used as a light source. In this embodiment, the power source to cause a stimulated emission is turned off. The present invention uses a light confinement effect on a material that is tuned to keep the light and the material tightly coupled so that the light cannot be absorbed or transmitted by the material. That is, a material is provided on one of whose surfaces the transmission and absorption of light are in equilibrium within a closed space of an apparatus. When the material in the apparatus is illuminated with light, the light remains at a point on the surface of the material and, therefore, the surface of the material shows a lighting effect. In addition, if necessary, the balance between transmission and absorption can be broken so that light can propagate through the material. At this time, the lighting effect of the material is canceled and the light is emitted from the material.
    [0107]
    [0108] Although the present invention has been described with reference to examples of embodiments, said embodiments are presented to describe the technical spirit of the invention for illustrative purposes only, and those skilled in the art will perceive that various modifications and changes therein are possible, without depart from the spirit of the invention. Accordingly, it should be understood that the scope of protection of the present invention is defined by the claims set forth below rather than by the description presented herein.
    权利要求:
    Claims (12)
    [1]
    1. An apparatus for coupling and emitting light and material comprising:
    Light to be coupled with a material;
    A gaseous, liquid or solid material to be coupled with light;
    A coupling unit configured to stop the propagation of light and to couple the light and the material;
    An emission unit configured to emit the light coupled with the material towards a target; Y
    A controller configured to control the light, the material, the coupling unit and the emission unit.
    [2]
    2. An apparatus according to claim 1, wherein the light is tuned to be transformed into a single wavelength light, according to the nature and mass of the material to be coupled with the light, the distance to the target point and the coordinate of the target point.
    [3]
    3. An apparatus according to claim 1, wherein the mass of the material to be coupled with the light is heavier than a predetermined mass, the light is synthesized with a second light so that it resonates in intensity, vibration, and wavelength , thereby increasing the coupling force between the light and the material to compensate for an excessive mass.
    [4]
    4. An apparatus according to claim 1, wherein a first material that has the property of providing a state in which the light is not transmitted or absorbed is placed on the side surface of a predefined space in which the light penetrates , thus stopping the propagation of light when the light reaches the surface of the first material so that the light remains on said surface, and then a second material to mate with the light is injected into the predefined space so that the light is coupled With the second material.
    [5]
    5. An apparatus according to claim 1, wherein a vibration plate installed on one side of the material where the light is retained is controlled to cause the vibration of the material, so that the molecules of the material are strongly coupled with the particles of light.
    [6]
    6. An apparatus according to claim 1, wherein in a state in which the light is retained by a material that has a limit point where neither light transmission nor absorption occurs, the material is heated to 70 ° or more to start the propagation of light through it.
    [7]
    An apparatus according to claim 1, wherein a first ray of light is coupled with hydrogen and then emitted towards a predetermined target point in the space to collide with a second ray of light or certain object so that the coupling between the hydrogen and the first ray breaks; the decoupled hydrogen from the first ray of light reacts chemically with the oxygen in the air to form water molecules (H2O); water molecules disperse to create a monitor effect in the air; and a monitor light is emitted from a central part towards the water molecules so that a monitor screen is formed in the air.
    [8]
    An apparatus according to claim 1, wherein the light particles are coupled with particles of an odorous gas or a pesticide and the coupled particles are emitted towards a predetermined target at a predetermined distance so that the coupled particles collide with a certain object, such as a building, a tree, an iron block or a stone, thus causing the particles of the odorous gas or the pesticide to disengage from the light particles and thus disperse in the air, thus repelling rats, mosquitoes , flies or pests.
    [9]
    An apparatus according to claim 1, in which the exothermic heat or the endothermic heat of a reaction between a first material and a second material is calculated .; a first ray of light and a second ray of light are coupled with the first material and the second material; and the first ray and the second ray respectively coupled with the first and second material are emitted towards an objective position at a certain distance such that the first ray coupled with the first material collides with the second ray coupled with the second material or collides with a certain object to decouple the first material and the second material of the first ray of light and the second ray of light, thus causing a chemical reaction between the first material and the second material to obtain an effect of adjusting the temperature of the surrounding air through an exothermic reaction or an endothermic reaction.
    [10]
    10. An apparatus according to claim 1, wherein the light is coupled with an explosive material formed to explode at a certain impact intensity and in which the coupled material and light are emitted towards a target such as a flying missile the missile
    [11]
    11. An apparatus according to claim 1, wherein:
    A second light is emitted towards the light that remains in the coupling unit so that it resonates with said light, thereby controlling the wavelength of the light;
    An aromatic material is coupled with the resonant light; Y
    The resonant light coupled with the aromatic material is emitted towards a person so that the person can feel wind attributable to the wavelengths of the light and smell an aromatic perfume.
    [12]
    12. An apparatus for attaching and emitting light and material, the apparatus being configured such that a material having a limit point between transmission and absorption of light is installed on one side of a predetermined space, and light is emitted towards the material from a light source, in which the emitted light remains in the material to give a light effect and the light effect is canceled causing the light remaining in the material to propagate through it.
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    同族专利:
    公开号 | 公开日
    US20190240637A1|2019-08-08|
    ES2718579R1|2019-07-09|
    KR20190081741A|2019-07-09|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    2019-07-02| BA2A| Patent application published|Ref document number: 2718579 Country of ref document: ES Kind code of ref document: A2 Effective date: 20190702 |
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    2020-06-18| FC2A| Grant refused|Effective date: 20200612 |
    优先权:
    申请号 | 申请日 | 专利标题
    KR1020170184487A|KR20190081741A|2017-12-29|2017-12-29|Device for combining light and matter|
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