KR101848842B1 - Laser lighting apparatus - Google Patents

Abstract

The present invention relates to a laser illumination apparatus, and more particularly, to a laser illumination apparatus using a laser diode.
The laser illumination apparatus according to an embodiment of the present invention includes a laser diode emitting laser light, a secondary light having a wavelength different from that of the laser light excited by a part of the laser light incident and incident on the laser light, A plate-shaped light conversion member for outputting mixed light of light, and a bubble mirror for reflecting the mixed light that enters the plate-shaped light conversion member around the plate-like light conversion member, , The entire side of its side; And a reflective layer formed on the surfaces of the upper surface and the lower surface except for the incident area where the laser light is incident and the exit area of the mixed light located at the focus of the parabola.

Description

[0001] The present invention relates to a laser lighting apparatus,

The present invention relates to a laser illumination apparatus, and more particularly, to a laser illumination apparatus using a laser diode.

Light emitting diodes (LEDs), which are one of the point light sources, have been widely used in various fields ranging from optical components for display purposes to alternative light sources for energy saving as time goes by.

In order for such a light emitting diode to be used as general illumination, it is necessary to provide a light distribution that can satisfy various lighting applications. In order to achieve this, Korean Patent No. 10-0919760 (September 24, 2009) discloses a technique for improving the light directivity of a lighting device. However, in order to form a parallel light, a light emitting diode has a large and heavy optical A system is required and a heat dissipation system is also required because heat is generated a lot.

Korean Patent Registration No. 10-0919760

The present invention provides a laser illumination device capable of more effectively providing parallel light using a laser diode.

A laser illuminator according to an embodiment of the present invention includes a laser diode for emitting laser light; A plate-like light converting member for emitting secondary light of a wavelength different from that of the laser light which is excited and emitted by a part of the incident laser light, and a mixed light of the remaining laser light; And a bubble mirror which surrounds the plate-like light-conversion member and reflects the mixed light incident from the plate-like light-conversion member, wherein the plate-like light-conversion member has an entire surface on its side surface; And a reflective layer formed on the surfaces of the upper surface and the lower surface except for the incident area where the laser light is incident and the exit area of the mixed light located at the focus of the parabola.

The plate-shaped light conversion member may be made of a composite material of a phosphor powder and a ceramic powder that emits the secondary light.

The plate-shaped light conversion member may be a single crystal or a sintered body made of a fluorescent material that emits the secondary light.

The plate-shaped light conversion member may include a light extracting structure formed in at least a part of the outgoing area.

The light extracting structure may be located at the focal point of the parabola.

The phosphor may include at least one of a YAG-base phosphor, a TAG-base phosphor, a LuAG-base phosphor, a silicate-base phosphor, an orthosilicate-base phosphor, an aluminate-base phosphor, an oxide-base phosphor, a nitride-base phosphor, an oxynitride- .

The laser diode may further include a reflection member positioned outside the parabolic mirror and reflecting the laser beam to cause the laser beam to be incident on the plate-shaped light conversion member.

The laser diode may penetrate the rear surface of the paraboloid and allow the laser light to enter the plate-shaped light conversion member.

The laser illumination apparatus according to embodiments of the present invention can provide parallel light near a point light source and reduce the size and weight of the illumination apparatus by using a laser diode, compared with a conventional illumination apparatus using a light emitting diode.

Further, the light extraction structure is formed on the plate-shaped light conversion member to efficiently emit the mixed light which was difficult to be emitted from the plate-like light conversion member due to the internal reflection, and the laser light is not reflected on the surface of the plate- So that the color conversion efficiency of the laser light can be enhanced. Further, the light extracting structure can be restricted to a partial region of the light exit surface to be closer to the point light source, and such point light source can more effectively provide parallel light by passing the focus through the parabola.

On the other hand, when the plate-shaped light conversion member is located at the focal point of the paraboloid, it can exhibit the best parallel light, and the plate-shaped light conversion member is formed by mixing the phosphor powder and the ceramic powder or the whole plate- So that denaturation by heat and deterioration of characteristics can be prevented. The reflection layer may be formed on the surface of the plate-shaped light conversion member except for the light extraction structure, so that the mixed light can be effectively emitted through the light extraction structure.

1 is a cross-sectional view of a laser illumination apparatus according to an embodiment of the present invention;
2 is a cross-sectional view illustrating a plate-shaped light conversion member having a light extracting structure according to an embodiment of the present invention;
3 is a sectional view showing a modified example of the laser illumination apparatus according to an embodiment of the present invention.
4 is a sectional view showing a laser light incidence method of a laser illumination apparatus according to an embodiment of the present invention;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. In the description, the same components are denoted by the same reference numerals, and the drawings are partially exaggerated in size to accurately describe the embodiments of the present invention, and the same reference numerals denote the same elements in the drawings.

1 is a cross-sectional view illustrating a laser illumination apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a laser illumination apparatus according to an embodiment of the present invention includes a laser diode 110 for emitting laser light 10; The mixed light of the secondary light of the wavelength different from that of the laser light 10 excited by a part of the incident laser light 10 and the remaining laser light 10 A light conversion member 120 in the form of a plate for emitting light; And a porcelain (130) that reflects the mixed light (20) incident on the plate-shaped light conversion member (120) around the plate-shaped light conversion member (120).

The laser diode 110 is a semiconductor device that emits laser light by an electrical signal. The laser diode 110 emits light in a narrow wavelength band (i.e., laser light) as compared with a light emitting diode, and emitted light has a linearity. In addition, since the laser diode 110 amplifies light to emit laser light, the laser diode 110 has a higher output than a light emitting diode, has a smaller size and consumes less power than a conventional laser. Further, the laser diode 110 which can operate at high speed and emits blue light or ultraviolet light has an advantage that there is no reduction in efficiency even at a high current.

1, a condenser lens 140 may be disposed between the laser diode 110 and the plate-shaped light conversion member 120, and the condenser lens 140 may be disposed between the laser diode 110 and the plate- The laser light 10 may be condensed on the plate-shaped light conversion member 120. [ The laser light 10 emitted from the laser diode 110 is relatively wide with a diameter of about 5 mm and is condensed through the condenser lens 140 so that the diameter of the laser light 10 in the plate- Can be 1 to 2 mm. In this case, it is preferable that the condenser lens 140 is arranged so that the focus of the condenser lens 140 is located near the focus of the capsule lens 130 so that the laser light 10 is condensed near the focus of the capsule lens 130 have.

The plate-like light conversion member 120 is incident on the laser light 10 and is excited by a part of the incident laser light 10 to emit secondary light having a wavelength different from the wavelength of the laser light 10, (10) and the mixed light (20) of the second laser light (10) excited. The plate-shaped light conversion member 120 may include a phosphor that is excited by the irradiated light and emits light of a different wavelength from the irradiated light. Since the plate-shaped light-converting member 120 is plate-shaped, it is easier to form than the light-converting member having another shape.

The plate-shaped light conversion member 120 may be made of a composite material of a phosphor powder emitting secondary light and a ceramic powder having heat resistance. The phosphor is excited by a part of the incident laser light 10 to emit a secondary light having a wavelength different from the wavelength of the laser light 10. The phosphor may be a phosphor made of an inorganic fluorescent compound, It may be a quantum dot fluorescent substance which occurs at a narrow wavelength band. When the quantum dot fluorescent material is used, the emission wavelength of the quantum dot fluorescent material can be adjusted according to the size of the quantum dots and the absorption wavelength band can be adjusted. Therefore, parallel light can be generated at an arbitrary wavelength by controlling the relative position of the fluorescent material and the fluorescent material 130 It is possible to generate light having various divergent angles. The phosphor is more preferably a phosphor selected from the group consisting of a YAG-base phosphor, a TAG-base phosphor, a LuAG-base phosphor, a silicate-base phosphor, an orthosilicate-base phosphor, an aluminate-base phosphor, an oxide-base phosphor, a nitride-base phosphor, an oxynitride- And may include at least one. (Y _1-xy Gd _x Ce _y ) ₃ Al ₅ O ₁₂ , (Y _{1- x} Ce _x ) ₃ Al ₅ O ₁₂ , (Y _{1-x Ce x) 3 (Al 1-} y Ga y) 5 O 12, (Y 1-xy Gd x Ce y) 3 (Al 1-z Ga z) YAG -based fluorescent material such as ₅ O ₁₂ and (Y _{1-x- y} Lu _x Ce _y ) ₃ Al ₅ O ₁₂ , silicate phosphors such as (Sr, Ca, Ba, Mg) ₂ SiO ₄ : Eu, (Ca, Sr) Si ₂ N ₂ O ₂ : Eu and the like can be used. In addition, a phosphor that emits green secondary light when irradiated with light can be a LuAG-based phosphor such as (Y _{1-x- y} Lu _x Ce _y ) ₃ Al ₅ O _12, and Y ₃ (Al, _{Ga) 5 O 12: Ce,} CaSc 2 O 4: Ce, Ca 3 (Sc, Mg) 2 Si 3 O 12: Ce, (Sr, Ba) 2 SiO 4: Eu, (Si, Al) 6 (O, N) _8: there is Eu, Mn, etc. may be used: Eu (β-sialon), (Ba, Sr) 3 Si 6 O 12 N 2: Eu, SrGa 2 S 4: Eu, BaMgAl 10 O 17. In addition, when irradiated with light to be excited and emits secondary light of a red color, (Ca, Sr, Ba) 2 Si 5 (N, O) 8: Eu, (Ca, Sr, Ba) Si (N, O) 2 : Eu, (Ca, Sr, Ba) AlSi (N, O) 8: Eu, (Sr, Ba) 3 SiO 5: Eu, (Ca, Sr) S: Eu, (La, Y) 2 O 2 S: Eu, K ₂ SiF ₆ : Mn, CaAlSiN: Eu, or the like can be used.

Light is mixed with light in a complementary color relationship or mixed with all three primary colors of light (i.e., red light, green light, and blue light), and white light can be produced using the phosphors. In one embodiment, when the color of the laser beam 10 is blue, a white light (that is, mixed light of white) is made by using a phosphor (for example, YAG fluorescent material) emitting yellow secondary light, (For example, a LuAG-based phosphor) that emits green secondary light and a phosphor that emits red secondary light (e.g., a nitride-based phosphor) can be used together to produce white light. On the other hand, light (or mixed light) of a desired color may be formed using the laser light 10 having the predetermined color and the above-mentioned phosphors.

The ceramic (or ceramic powder) may include alumina (Al ₂ O ₃ ), which may be transparent or semitransparent to allow light to be incident thereon, and heat resistance may be sufficient to prevent deterioration of the phosphor due to heat. And is not particularly limited. Conventionally, a method of mixing a fluorescent material in a powder form into a plate (an organic (or polymer) binder such as a silicone resin and applying the mixture to a plate member has been used. However, since the silicone resin has low thermal stability, It is difficult to use the laser light 10 in high output laser light 10, and the phosphor is also denatured by heat and causes deterioration of characteristics. However, in the present invention, it is not necessary to use a silicon binder having low thermal stability by mixing a phosphor powder and a ceramic powder having heat resistance to form a plate-shaped light conversion member 120. Since the ceramic powder has heat resistance, And the thermal stability of the plate-shaped light conversion member 120 is excellent since the characteristics are not degraded. On the other hand, since the plate-shaped light conversion member 120 including a ceramic is naturally roughened at the time of its formation, the light extraction effect can be obtained without separately forming the light extracting structure 121, It is not necessary to pass the process of smoothing the surface of the conversion member 120 and the process of forming the light extracting structure 121 on the plate-shaped light conversion member 120, thereby reducing the number of processes for producing the laser illumination device.

In addition, the plate-shaped light conversion member 120 may be a single crystal or a sintered body made of a phosphor that emits secondary light. In the case where the plate-shaped light conversion member 120 is a single crystal made of a fluorescent material, since the fluorescent material is a single crystal, the heat conversion is insignificant, the characteristic deterioration is small, and there is no need to use a silicon binder. Since the plate-like light conversion member 120 is a single crystal made of a phosphor, it is easy to make a structure for guiding light incidence of the laser light 10 or light emission of the mixed light 20 because the refractive index is uniform throughout. If the incident angle of the light is greater than the critical angle, total internal reflection occurs. If the entire plate-like light conversion member 120 is made of the single-crystal phosphor, the refractive indices of all the surfaces are the same. Therefore, in order to reduce the reflectance of the laser light 10 It is easy to determine the incident angle of the laser light 10 (for making the incident angle of the laser light smaller than the critical angle). In addition, since the plate-shaped light conversion member 120 is a single crystal and has a uniform refractive index and is in a plate shape, the surface is homogeneous, so that light incidence and light output can be smoothly performed, and color conversion efficiency can be improved.

When the plate-shaped light conversion member 120 is a sintered body made of a phosphor, the plate-shaped light conversion member 120 may be a sintered body formed by molding a phosphor powder and then heat-treated (sintered) at a high temperature. Since the plate-like light-converting member 120 is made of only a phosphor, color conversion of incident light can be effective, and since a powder of one material is used, the powder can be well-fused.

On the other hand, when the light conversion member is formed into a plate shape, it is easy to form the shape when a single crystal made of a fluorescent material is used as a light conversion member. The phosphor may be an organic crystal phosphor including an anthracene of a scintillator.

The photomask 130 reflects the mixed light 20 incident on the photomultiplier 130 among the mixed light 20 emitted from the plate-like light conversion member 120 around the plate-shaped light conversion member 120 So that the mixed light 20 advances parallel to the front of the laser illuminator without spreading. This parallel light is referred to as parallel light. The parallel light is concentrated and can be irradiated far. Meanwhile, the photomask 130 may reflect the laser beam 10 to cause the laser beam 10 to be incident on the plate-shaped light conversion member 120. When the laser light 10 is incident on another material in the air, the laser light 10 loses its convergence and spreads in an arbitrary direction without spreading. In this case, the laser light 10 10 is determined by the direction of the irradiation of the secondary light intensity laser light 10 excited by a part of the laser light 10 and the mixed light 20 of the secondary light and the remaining laser light 10 is also determined in a certain direction And then emitted in various directions on the plate-shaped light conversion member 120. [ The mixed light 20 emitted in various directions in this manner allows the photopaper 130 to move in one direction (that is, in front of the laser illuminator). The photoreceptor 130 may have a reflective coating on the inner surface, and may be a metal thin film coating such as aluminum, silver, or the like to enhance the reflection efficiency. It may also be a highly reflective coating, which may be a thin film coating of two or more metal materials mixed and may be variously made according to methods known in the art.

The photopaper 130 may include a light projecting portion and may be provided with a laser beam 10 (see FIG. 10) on the plate-like light conversion member 120 inside the photopaper 130 from the outside of the rear surface or side surface of the photopaper 130 through the light- Can be made incident. The light transmitting portion may be in the form of a hole. If the light transmitting portion has a hole shape, the diameter of the hole must be small in order to minimize the disappearance of the mixed light 20 emitted from the plate-like light converting member 120 through the light transmitting portion, The laser light 10 must be condensed and passed through the condenser lens 140 so that the light 10 can pass through the small transparent portion.

The plate-shaped light conversion member 120 may be positioned at the focal point of the photopaper 130. [ The light passing through the focus of the photopaper 130 in the photopaper 130 is reflected by the inner surface of the photopaper 130 and moves parallel to the axis of the photopaper 130. The photoprocessing member 120 The mixed light 20 emitted from the plate-shaped light conversion member 120 and incident on the inner surface of the bubble mirror 130 is reflected by the inner surface of the bubble mirror 130 and converted into parallel light . Accordingly, the mixed light 20 can be made parallel to the front of the laser illuminator without spreading, so that the shape of the point light source can be maintained.

FIG. 2 is a cross-sectional view showing a plate-shaped light converting member formed with a light extracting structure according to an embodiment of the present invention. FIG. 2 (a) (b) is a plate-like light-converting member having a light extracting structure on two surfaces thereof, and FIG. 2 (c) is a plate-shaped light converting member having a light extracting structure on a part of the surface thereof.

Referring to FIG. 2, the plate-shaped light conversion member 120 may include a light extracting structure 121 formed on at least one of upper and lower surfaces facing each other. Here, the upper surface and the lower surface mean two broad surfaces opposite to each other in the plate-shaped light conversion member 120, and the upper and lower plates are assumed to have a plate-like light conversion member 120 spread widely, But it does not have a special positional meaning. That is, the plate-shaped light conversion member 120 may include a light extracting structure 121 formed in at least a part of the outgoing region. In addition, the plate-shaped light conversion member 120 may cause light incidence and light emission on the same plane, light incidence and light emission may occur on mutually opposing planes, one or more planes on which light incidence occurs, There may be more than one face where light emission occurs. The light extracting structure 121 may be formed on only one of the surface where the light incidence occurs and the surface where the light emerges when the light incidence and light exit occur on the mutually facing surfaces, The light extracting structure 121 may be formed on both sides where the light extracting structure 121 is formed.

When the surface of the plate-like light conversion member 120 is flat, approximately 10% of the incident laser light 10 is reflected, and the mixed light 20 emitted is not emitted from the surface at one time, and about 50% The light extracting structure 121 can reduce the reflectance of the incident laser beam 10 at the surface where the light incidence occurs and can reduce the reflectance of the mixed light beam 20 can be smoothly extracted. The light extraction structure 121 has a greater purpose of light output than the purpose of light incidence because the light extraction structure 121 does not emit light of about 50% or more of the mixed light 20 inside the plate-shaped light conversion member 120 but generates internal reflection. It is preferable to form the light extracting structure 121 on the surface where light emission occurs and it is more preferable to form the light extracting structure 121 on both the surface where light incidence occurs and the surface where light emerges.

The light extracting structure 121 causes the light path of the incident or emitted light to be refracted or to cause light scattering so that the light is effectively incident on the plate-shaped light-converting member 120 or the plate-shaped light-converting member 120. If the incident angle is greater than the critical angle, total reflection occurs. The critical angle is determined by the wavelength of light and the refractive index of the incident surface. Therefore, in order to reduce the reflectivity of the laser beam 10, the wavelength of the laser beam 10 must be adjusted or the refractive index of the incident surface must be changed. In order to change the refractive index of the incident surface, the incident surface material must be changed or the incident angle of the laser light 10 must be changed. The light extracting structure 121 serves to change the incident angle of the laser light 10. The shape of the light extracting structure 121 may be variously configured in a hemispherical shape, a pyramid shape, a cone shape, a wedge shape, a triangular-pyramid shape, a quadrangular pyramid shape or a shape extending in one direction. And the shape of the light extracting structure 121 may be different depending on the formation position of the light extracting structure 121. On the other hand, when the light extracting structure 121 is not separately formed on the plate-shaped light converting member 120, when the plate-like light converting member 120 is formed, the surface is naturally roughly used as the light extracting structure 121 It is possible.

At this time, the light extracting structure 121 may include a repeated concave-convex structure. The protrusions or protrusions are continuous, and protrusions or recesses can be repeated regularly.

The light extracting structure 121 may be formed on only one side as shown in FIG. 2 (a), but may be a protruding portion protruding toward the outward direction. The protrusions may be formed by patterning, or they may be formed in addition to the plate. The plate and the protrusions may be made of the same material or different materials. Using a protrusion of a different material from the plate can also achieve a change in the refractive index of the incident surface by changing the material of the incident surface. On the other hand, the light extracting structure 121 may be formed as a depressed portion concaved inwardly, and the depressed portion may also be formed by patterning. The surface on which the light extracting structure 121 is formed may be a light emitting surface, and may be a light incident surface, or may be a light incident surface and a light emitting surface.

The light extracting structure 121 may be formed on two opposite surfaces as shown in FIG. 2 (b), and may be a protruding portion protruding outwardly or a concave portion recessed inwardly. When the light extracting structure 121 is formed on two opposing surfaces, the laser light 10 can be incident on one surface and the mixed light 20 can be emitted to the other surface. The mixed light 20 is emitted not only to the front side of the laser illuminator but also to the inner surface of the rear porcelain 130 so that the mixed light 20 is reflected by the porcelain 130 It can be a parallel light having excellent light directivity without spreading.

In addition, the light extracting structure 121 may be formed only on a portion of one of the upper surface and the lower surface of the plate-shaped light conversion member 120. The light extracting structure 121 may be formed by restricting only a part of the upper surface or the lower surface of the plate-shaped light converting member 120 as shown in FIG. 2 (c). In this case, 20 can be emitted, so that the mixed light 20 can be emitted closer to the point light source. Since the plate-shaped light-converting member 120 has an area, only a part of the mixed light 20 emitted passes through the focal point of the lens barrel 130, so that the mixed light 20 emitted from the plate- The light extracting structure 121 is limited to a partial area of the plate-shaped light conversion member 120 positioned at the focal point of the photopaper 130 in order to increase the ratio of the mixed light 20 passing through the focus of the photopaper 130 A large amount of the mixed light 20 can be emitted from the focal point of the photocolumning 130. Here, the partial area may have a width of 5 mm or less, and in this case, the mixed light 20 can be emitted closer to the point light source. If the width of a certain region is larger than 5 mm, the size of the point light source is increased and the advantage of the laser diode 110 is canceled. In this case, the laser light 10 is reflected by the surface of the plate-shaped light-converting member 120 by about 10%, and when the width of the light- The laser beam 10 having a wavelength of about 50% or more is not emitted because the reflection is repeated in the plate-shaped light conversion member 120, and the light efficiency is lowered. Therefore, the partial area may be limited to a range where the width is larger than 0 mm and smaller than 5 mm.

The light extracting structure 121 may be a photonic crystal structure that reflects light of a specific wavelength. The photonic crystal structure reflects only light of a specific wavelength and transmits the remaining light except for a specific wavelength. The photonic crystal structure may transmit or reflect the laser light 10 having a certain wavelength through the photonic crystal structure. A photonic crystal structure in which the laser light 10 is transmitted is formed in a part of the plate-shaped light conversion member 120 where the laser light 10 is incident, and a mixed light 20 is formed in a part of the light- It is possible to form a photonic crystal structure through which light is transmitted. When the photonic crystal structure in which the laser light 10 and the mixed light 20 are reflected is formed in the remaining region, the laser light 10 is effectively incident and the mixed light 20 can be effectively emitted. The light extracting structure 121 is formed in a light extracting structure 121 that is not a photonic crystal structure but has a different refractive index from the region where the laser beam 10 is incident and the region from which the mixed light 20 is emitted to the remaining region, Can be achieved. On the other hand, the light extracting structure 121 may have an anisotropic structure to transmit light of a specific wavelength and reflect light of other wavelengths.

The light extracting structure 121 may be formed in a predetermined pattern. Although the light extracting structure 121 may be formed irregularly, if the light extracting structure 121 has regularly regular patterns, the same effect can be obtained in the same region. In other words, a shape having a refractive index corresponding to the incident position of the laser light 10, a shape having a refractive index corresponding to the position where the mixed light 20 is emitted, The extraction structure 121 can be formed. If the light extracting structure 121 has a certain pattern, the respective patterns may not interfere with each other, so that the incident laser light 10 and the mixed light 20 can be effectively emitted. On the other hand, the pattern may be formed to have an interval of 0.01 to 0.1 mu m between the respective patterns. If the interval of the patterns is closer than 0.01 탆, the respective patterns interfere with each other, and if the distance is longer than 0.1 탆, the area where the laser light 10 can be reflected becomes wider and the light efficiency is lowered.

3 is a cross-sectional view showing a modified example of the laser illumination apparatus according to an embodiment of the present invention.

Referring to FIG. 3, the light extracting structure 121 may be positioned at the focal point of the photopaper 130. The light passing through the focal point of the photopaper 130 in the photopaper 130 can be reflected by the inner surface of the photopaper 130 and go in parallel with the axis of the photopaper 130, The mixed light 20 emitted from the plate-shaped light conversion member 120 and incident on the inner surface of the bubble mirror 130 is reflected by the inner surface of the bubble mirror 130 to be parallel light Can be converted. When the light extracting structure 121 from which the mixed light 20 is emitted is positioned at the focal point of the photopaper 130, the mixed light 20 emitted can be focused more accurately on the photopaper 130, The mixed light 20 passes through the focal point of the lens barrel 130, so that ideal parallel light can be produced. Accordingly, the mixed light 20 is not spread, and the shape of the point light source can be maintained more than the focal point of the photopaper 130 is located elsewhere in the plate-shaped light conversion member 120. The light extracting structure 121 may be located at the focal point of the photopaper 130 while facing the inner surface of the photopaper 130 to emit the mixed light 20 toward the inner surface of the photopaper 130. In this case, all the mixed light 20 to be emitted is reflected on the inner surface of the lens barrel 130 through the focus of the lens barrel 130, so that all the mixed light 20 can produce parallel light. Since the plate-shaped light-converting member 120 has an area, it is preferable to position the light-extracting structure 121 formed on only a part of the plate-shaped light-converting member 120 at the focal point of the lens barrel 130.

The plate-shaped light conversion member 120 may include a reflective layer 122 formed on at least a side surface thereof. The side surface refers to a surface of the plate-shaped light-converting member 120 excluding the upper surface and the lower surface, and it means that the plate is positioned side-by-side when the light-converting member 120 is spread widely. If the reflective layer 122 is formed on the side surface of the plate-like light conversion member 120, the mixed light 20 can be emitted in a predetermined direction through a wide upper surface or a lower surface without being dispersed in various directions. The surface of the plate-shaped light-converting member 120 as well as the surface of the plate-like light-converting member 120 except for the region where the laser light 10 is to be incident and the region where the mixed light 20 is emitted, The laser beam 10 can be incident on the inside of the plate-shaped light conversion member 120 through a certain region if the reflection layer 122 is also formed on the surface (for example, the surface excluding the light extracting structure) The mixed light 20 is guided to an area (for example, a light extracting structure) in which the mixed light 20 is emitted by reflecting the mixed light 20 to the reflection layer 122, All of the mixed light 20 can be emitted and a light source close to the point light source can be formed by limiting the exit area of the mixed light 20. [ The area where the mixed light 20 is emitted is restricted to the focus of the photopaper 130 so that all of the mixed light 20 passes through the focus of the photopaper 130 and the focus of the photopaper 130 is shifted All of the mixed light 20 can be converted into the parallel light by causing all of the mixed light 20 to be reflected to the photoreceptor 130. That is, the plate-shaped light conversion member 120 has an entire surface on its side surface; And a reflection layer 122 formed on the surfaces of the upper surface and the lower surface except for the incident area where the laser light 10 is incident and the exit area of the mixed light 20 located at the focal point of the aperture 130 And the mixed light 20 may be reflected from the reflection layer 122 to the inside of the plate-shaped light conversion member 120 and emitted to the emission region. The reflective layer 122 may be a metal reflective layer that is made of metal and forms a mirror surface, and may be a distributed Bragg reflector that forms alternating layers of oxide layers having different refractive indices (e.g., SiO ₂ and TiO ₂ ) Reflecting (DBR) layer. Here, the DBR layer is formed by repeatedly laminating a high refractive index layer and a low refractive index layer, and adjusting the optical thickness of these layers to maximize the reflectivity for light of a specific wavelength.

The plate-shaped light conversion member 120 may be formed on at least a side surface and may include a high-refractive index layer 122 having a higher refractive index than the plate-shaped light conversion member 120. The high refractive index layer 122 may be a layer made of a material different from the material of the plate-shaped light-converting member 120, and may be a layer that includes a certain amount of particles in the material of the plate- It is possible. The reason why the high refractive index layer 122 is formed is that when the refractive index of the high refractive index layer 122 is larger than the refractive index of the plate-shaped light conversion member 120, This is because an effect similar to that of the reflective layer 122 can be obtained because the amount of internal reflected light is increased. The high refractive index layer 122 also functions to induce the exit of the mixed light 20 and to limit the exit area of the mixed light 20 and the material of the high refractive index layer 122 is a material that is a function of the plate- And the like.

FIG. 4 is a cross-sectional view showing a laser light incidence method of a laser illumination apparatus according to an embodiment of the present invention. FIG. 4 (a) shows a reflection type incidence method and FIG. 4 (b) shows a penetration type incidence method.

4, the laser diode 110 may be located outside the photoreceptor 130, and the laser illuminator may reflect the laser light 10 to form the laser light 10 And a reflecting member 150 for reflecting the incident light. Here, the laser light 10 may be incident on the upper surface or the lower surface of the plate-shaped light conversion member 120, and the reflection member 150 may include a mirror or a metal plate. A plurality of laser diodes 110 may be arranged in a circular shape along the outer circumference of the photopaper 130 and may be arranged such that the laser light 10 incident on the plate- Position and angle of incidence can be adjusted. This method is advantageous in that it is easy to increase the number of laser diodes 110 to increase the output of the lighting device and to increase the number of laser diodes 110 in order to reduce the reflectance of the laser light 10 on the surface of the plate- The incident position and the incident angle can be easily adjusted. The upper surface (or the lower surface) from which the mixed light 20 is emitted may be directed toward the front of the laser illuminator or may be directed toward the rear lens barrel 130, Irrespective of the direction, it is sufficient that the mixed light 20 passes through the focal point of the photocollimator 130 so that the parallel light can be directed forward of the laser illuminator. A light transmitting portion may be formed on the side surface of the photoreceptor 130 so that the laser light 10 is incident on the plate-shaped light converting member 120 through the light transmitting portion from the outside of the photoreceptor 130.

The laser diode 110 can penetrate the rear surface of the photopaper 130 and allow the laser light 10 to enter the plate-shaped light conversion member 120. Here, the laser diode 110 may pass through the rear surface of the photopaper 130 to emit the laser beam 10 into the plate-shaped light conversion member 120 in the photopaper 130, and the laser diode 110 May be positioned on the rear surface of the photoreceptor 130 and only the laser beam 10 may pass through the rear surface of the photoreceptor 130 and be incident on the phototransformation member 120 in a plate form. When laser light 10 passes through the rear surface of the photomask 130 and enters the plate-like light-converting member 120, the laser light 10 may be incident on the plate-shaped light-converting member 120 through the transmitting portion 160 or the light- .

The laser illumination device may further include a transfer unit 160 passing through the rear surface of the photoreceptor 130 and allowing the laser light 10 to be incident on the plate-shaped light conversion member 120. The transmitting unit 160 may be a pipe through which the laser light 10 is incident or may be a connecting means for connecting the laser diode 110 and the plate- It is enough to penetrate the rear surface of the photopaper 130 and enter the plate-shaped light conversion member 120. The laser diode 110 is positioned on the rear side of the photopaper 130 and the laser diode 10 is connected to the plate-like light conversion member 120. [ May be transmitted to the inside of the photopaper 130 through the transfer unit 160 and incident on the rear surface (that is, the rear surface) of the plate-shaped light conversion member 120. In this case, since the laser light 10 can be directly incident on the rear surface of the plate-shaped light-converting member 120 without passing through the air, the laser light 10 can be efficiently applied to the plate- Can enter. In addition, the mixing direction of the laser light 10 and the emitting direction of the mixed light 20 are the same, so that the mixed light 20 can be emitted effectively. The transfer unit 160 transmits the laser beam 10 by connecting the laser diode 110 and the plate-shaped light conversion member 120 through the rear surface of the photoreceptor 130. The transfer unit 160 may be a tube- A reflection surface may be formed on the inner surface so that the laser light 10 is not transmitted or absorbed, and a vacuum may be formed inside. The laser diode 110 may direct the laser beam 10 to the plate-shaped light conversion member 120 through a transmission unit 160 passing through the photodiode 130 from the side of the rear surface.

The laser light 10 can be emitted through an optical fiber. The laser light 10 generated in the laser diode 110 can be moved through an optical fiber (not shown). In this case, the laser light 10 can be moved by a desired distance, It is easy to adjust the incident angle and it is easy to form the shape of the lighting device because the optical fiber can be bent.

Hereinafter, a laser illumination apparatus according to another embodiment of the present invention will be described in detail. However, the elements overlapping with those previously described with respect to the laser illumination apparatus according to an embodiment of the present invention will be omitted.

According to another aspect of the present invention, there is provided a laser illuminator comprising: a laser diode emitting laser light; An optical distributing member for distributing the laser light in a second direction different from the first direction, the laser light being incident in a first direction; And a photomultiplier that reflects the laser light incident from the optical distributing member around the periphery of the optical distributing member, wherein the optical distributing member may be located at a focal point of the paraboloid.

The laser diode is a semiconductor device that emits a laser beam by an electrical signal. The laser diode emits light of a narrow wavelength band (that is, laser light) as compared with a light emitting diode, and emitted light has a linearity. In addition, since the laser diode amplifies light to emit laser light, the laser diode has a higher output than a light emitting diode, has a smaller size and consumes less power than a conventional laser. In addition, a laser diode which can operate at high speed and emits blue light or ultraviolet light has an advantage that there is no reduction in efficiency even at a high current. The laser light may emit visible light, ultraviolet light, infrared light, or the like.

The light distributor is capable of distributing the laser light in a first direction and in a second direction different from the first direction. Here, the term " distribution " means that light is incident and divided in various directions. The laser light may be incident on the inside of the optical distributing member and may be emitted and distributed, and reflected from the surface of the optical distributing member Lt; / RTI > The shape of the optical distribution member may be variously configured as spherical, hemispherical, diamond, cylindrical, or plate-like. The material of the optical distribution member may be a material that absorbs the laser light and reflects or transmits the laser light without reducing the energy of the laser light. The material may be a resin, a glass, a ceramic, Etc. may be used.

The parabolic reflector reflects the laser beam incident on the optical distributing member around the optical distributing member so that the laser beam does not spread and goes parallel to the front of the laser illuminating device. This parallel light is referred to as parallel light. The parallel light is concentrated and can be irradiated far. When the laser beam is incident on another material in the air, the laser beam is not spread but is scattered in an arbitrary direction. However, when the laser beam is scattered in one direction (that is, In front of the vehicle). The parabolic curved surface may be coated with a reflection coating on the inner surface, and may be a metal thin film coating such as aluminum or silver to improve reflection efficiency. It may also be a highly reflective coating, which may be a thin film coating of two or more metal materials mixed and may be variously made according to methods known in the art.

The light distribution member may be located at a focal point of the parabolic mirror. When the light distribution member is positioned at the focal point of the paraboloid, the light emitted from the light distribution member and incident on the inner surface of the paraboloid is incident on the inner surface of the paraboloid, The laser light can be reflected from the inner surface of the parabolic mirror and converted into parallel light. Accordingly, the laser light can be made parallel to the front of the laser illuminator without spreading, so that the shape of the point light source can be maintained.

The light distribution member may include a light extracting structure formed on at least a part of the surface. The light extracting structure causes the path of the emitted light to be refracted or light scattering to occur so that the light is effectively emitted from the optical distributing member. If the incident angle is greater than the critical angle, total reflection occurs. The critical angle is determined by the wavelength of light and the refractive index of the incident surface. The light extracting structure changes the incident angle of the laser light to change the refractive index of the incident surface. The shape of the light extracting structure may be a hemispherical shape, a pyramid shape, a cone shape, a wedge shape, a triangular shape, a quadrangular pyramid shape, or a shape extending in one direction. , And the shape of the light extracting structure may be different depending on the forming position.

The light extracting structure may be located at the focal point of the parabola. The light passing through the focus of the parabolic mirror in the photographic lens can be reflected from the inner surface of the parabolic mirror and move parallel to the axis of the parabolic mirror. When the light extracting structure is positioned at the focus of the parabolic mirror, And most of the laser light passes through the focal point of the parabolic mirror, so that ideal parallel light can be produced. Thus, the laser light does not spread beyond the position of the focus of the parabolic mirror at the other position of the optical distributor member, and the shape of the point light source can be maintained more.

The light distributing member may be formed in a plate shape, and the light extracting structure may be formed on at least one of the upper surface and the lower surface facing each other. The light distribution member may be formed in a plate shape. When the light distribution member is formed in a plate shape, the light extracting structure can be formed on at least one of the upper surface and the lower surface having a larger area than the other surfaces and the laser light is emitted at a higher rate. In this case, a large proportion of the laser light can be effectively emitted through the light extracting structure, and the light extracting structure can be positioned at the focus of the parabolic reflector to produce an ideal parallel light.

As described above, the laser illumination apparatus according to the present invention can provide a parallel light near a point light source by using a laser diode than a conventional illumination apparatus using a light emitting diode having a large light emitting diode, and a separate large and heavy optical system is required The size and weight of the lighting device can be reduced. The light extraction structure can be formed on the plate-shaped light conversion member to effectively emit the mixed light that was difficult to be emitted from the plate-like light conversion member due to the internal reflection. By reducing the reflectance of the laser light on the surface of the plate- So that the color conversion efficiency of the laser light can be increased. Further, the light extracting structure can be limited to a partial region of the light output surface, and parallel light closer to the point light source can be provided. On the other hand, if the plate-shaped light conversion member is located at the focal point of the paraboloid, good parallel light can be exhibited. Furthermore, when the light extraction structure of the plate-shaped light conversion member is positioned at the focal point of the paraboloid, it can exhibit the best parallel light. In addition, since the plate-shaped light conversion member is formed by mixing the phosphor powder and the ceramic powder, or the plate-shaped light conversion member as a whole is made of the single crystal fluorescent material, the plate-shaped light generated from the plate-like light conversion member using the conventional polymer binder It is possible to prevent deformation and deterioration of characteristics of the converting member due to heat. Further, a reflective layer may be formed on the surface of the plate-shaped light conversion member except for the light extraction structure, so that the mixed light can be effectively emitted to the light extraction structure.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Those skilled in the art will appreciate that various modifications and equivalent embodiments may be possible. Accordingly, the technical scope of the present invention should be defined by the following claims.

10: laser light 20: mixed light
110: laser diode 120: plate-shaped light conversion member
121: light extracting structure 122: reflective layer (or high refractive index layer)
130: Portion 140: Condenser lens
150: reflective member 160:
F: Focus of the parabola

Claims (8)

A laser diode emitting laser light;
A plate-like light converting member for emitting secondary light of a wavelength different from that of the laser light which is excited and emitted by a part of the incident laser light, and a mixed light of the remaining laser light; And
And a bubble mirror which surrounds the plate-like light-conversion member and reflects the mixed light incident from the plate-shaped light-conversion member,
The plate-shaped light conversion member is a plate-
An outer surface of the entire side surface thereof; And an incident area provided on a rear surface thereof and to which the laser light is incident and an outer surface of the front surface and the rear surface except for the exit area of the mixed light provided on the front surface facing the rear surface and located at the focal point of the parabolic surface And a reflective layer. The method according to claim 1,
Wherein the plate-like light converting member is made of a composite material of a phosphor powder and a ceramic powder which emit the secondary light. The method according to claim 1,
Wherein the plate-like light conversion member is a single crystal or sintered body made of a phosphor that emits the secondary light. The method according to claim 1,
Wherein the plate-shaped light conversion member includes a light extracting structure formed in at least a part of the outgoing area. The method of claim 4,
Wherein the light extracting structure is located at a focus of the parabolic mirror. The method according to claim 2 or 3,
Wherein the phosphor is at least one of a YAG-base phosphor, a TAG-base phosphor, a LuAG-base phosphor, a silicate-base phosphor, an orthosilicate-base phosphor, an aluminate-base phosphor, an oxide-base phosphor, a nitride-base phosphor, an oxynitride- Comprising a laser illumination device. The method according to claim 1,
Wherein the laser diode is located outside the parabolic mirror,
And a reflecting member which reflects the laser light to cause the laser light to be incident on the plate-like light converting member. The method according to claim 1,
Wherein the laser diode passes through the rear surface of the parabolic mirror and makes the laser light incident on the plate-shaped light conversion member.

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