JP6517285B2 - Optical system - Google Patents

Description

  The present invention relates to an optical system that causes light emitted from a plurality of light sources to be incident on a light guide member.

Generally, in processing applications using laser light (welding, cutting, etc.), or in laser lighting applications where fluorescent materials are excited using blue or ultraviolet laser light, it is necessary to obtain high-power laser light. is there. In addition, an optical fiber is often used as an optical member for guiding laser light. The optical fiber is flexible and has a high degree of freedom with regard to the arrangement of the exit.

  Conventionally, as means for obtaining a high-power laser beam, laser beams emitted from a plurality of semiconductor lasers are condensed by a lens system and converged at one position, and the incident end face of the optical fiber is positioned at the convergence position. There is known a multiplexing optical system in which an optical fiber is provided and a plurality of laser beams are combined into one.

  In the semiconductor laser module described in Patent Document 1, a plurality of semiconductor laser arrays are arranged in a step-like manner, and laser light from each semiconductor laser array is optically coupled to an optical fiber array using a condensing lens.

  In the multiplexing optical system described in Patent Document 2, laser beams emitted from a plurality of semiconductor lasers are collimated by a plurality of collimator lenses, respectively, and then incident on an optical fiber using a cylindrical lens and an anamorphic lens. ing.

JP, 2011-243717, A (December 1, 2011 release) Japanese Patent Application Publication No. 2007-163947 (published on June 28, 2007)

However, in order to obtain a large output laser beam, it is preferable to efficiently cause the light from as many semiconductor lasers as possible to be incident on one optical fiber. The maximum number N of semiconductor lasers that can be optically coupled to an optical fiber is θ, the core diameter is D, the wavelength of the semiconductor laser to be coupled is λ, and the beam quality value is M ² . It is determined by the ratio between the BPP (Beam Parameter Products, M ² · λ / π) of the semiconductor laser and the acceptance characteristic value (D · θ) of the optical fiber. The maximum number N of semiconductor lasers is represented by the following equation (1).

N = (π · γ · D · θ) / (λ · M ² ) (1)
Here, γ indicates the filling rate of the laser light, and indicates how dense the bundled collimated light beams are. It can be understood from the equation (1) that the characteristic values (D, θ, M ² ) of the optical fiber and the semiconductor laser are changed in order to efficiently couple as many semiconductor lasers as possible to one optical fiber. If this can not be done, it is only necessary to increase the filling factor γ of the laser beam.

  In the invention of Patent Document 1, since the positions of the light emitting points of the plurality of semiconductor lasers can be brought closer by arranging the plurality of semiconductor lasers in a step-like manner, γ is increased. However, each semiconductor laser device needs a certain size due to the size of the package itself and the heat sink, and a plurality of laser beams can not be brought closer than a certain level. Therefore, even if the semiconductor lasers are arranged stepwise as in the invention of Patent Document 1, there is a limit to the improvement of γ.

  In the invention of Patent Document 2, γ is determined by the interval at which a plurality of semiconductor laser devices are arranged, and γ can not be increased. In particular, considering heat generation from each of the plurality of semiconductor laser devices, it is not preferable to place the plurality of semiconductor laser devices extremely close to each other, which also causes γ not to be large.

  Further, the conventional technology as described above is configured to make the output light of a plurality of semiconductor lasers into a substantially wide parallel light with a filling factor γ and condense it with a large lens. However, the number of semiconductor lasers that can be arranged is also limited from the viewpoint of aberration in the condenser lens, and the width of substantially wide parallel light composed of a plurality of laser beams is extremely large. I can not do it. Therefore, there is a problem that the upper limit of the maximum output that can be obtained from the optical fiber output end is low.

  An object of the present invention is to reduce the restriction on the number of light sources that can be disposed with respect to one light guiding member, and as a result, to increase the output of light obtained from the light emitting end of the light guiding member.

In order to solve the above-mentioned subject, an optical system concerning one mode of the present invention is:
An optical system for condensing light onto a light guiding member, comprising: a first reflection mirror and a condensing lens, wherein the first reflection mirror is a laser having a relative angle emitted from a plurality of light sources The laser beam is guided to the condenser lens by changing the traveling direction of light, and the condenser lens condenses the laser beam whose traveling direction has been changed by the first reflection mirror, and the light guide is conducted. The laser light from the plurality of light sources is further provided with a plurality of second reflection mirrors that are incident on the member and guide the laser light to the first reflection mirror by reflecting the laser light emitted from the plurality of light sources. light Ru is emitted in the same direction as the optical axis of the condensing lens.

  According to one aspect of the present invention, the restriction on the number of light sources that can be disposed for one light guide member is reduced, and as a result, the output of light obtained from the output end of the light guide member is increased. Can provide an optical system capable of

It is a figure showing an example of the optical system concerning the embodiment of the present invention. It is a figure which shows an example of the optical system which concerns on other embodiment of this invention. It is a figure which shows the modification of the optical system which concerns on the said other embodiment. It is a figure which shows an example of the optical system which concerns on another embodiment of this invention. It is a figure which shows an example of the optical system which concerns on another embodiment of this invention. It is a figure which shows the light source unit used with the optical system which concerns on another embodiment of this invention. It is a figure which shows the manufacturing process of the said light source unit.

Embodiment 1
An embodiment of the present invention is described below with reference to FIG.

  The optical system according to the present embodiment changes the traveling direction of light emitted from a plurality of light sources, guides the light to a condensing lens, condenses the light by the condensing lens, and enters the light guiding member It is This reduces the restriction on the number of light sources that can be disposed with respect to one light guide member, and provides an optical system capable of enhancing the light output that can be obtained from the output end of the light guide member. It is a thing.

  An optical fiber can be mentioned as an example of a light guide member which makes light distribution controlled by the optical system of the present invention enter. The utility value of the optical system of the present invention is enhanced when light is incident on a light guide member having a relatively small cross-sectional area at the light incident end like an optical fiber. However, the light guide member is not limited to the optical fiber, and may be another type of light guide member such as a rod-shaped light guide member.

  Further, the type of light whose light distribution is controlled by the optical system of the present invention (in other words, light emitted from the light guide member) is not particularly limited. For example, the light may be visible light used as illumination light, or laser light used as light for processing such as cutting and welding. In other words, the type of the light source for emitting the light is not particularly limited, and the light source may be a semiconductor laser device or a light emitting diode (LED).

  In the present embodiment, an optical system 100 for condensing laser light (excitation light) on the optical fiber 9 as the light guide member will be described. The optical system 100 constitutes a part of an illumination device, and laser light collected by the optical system 100 is guided through an optical fiber 9 described later, and is a light source for an illumination light or an image display device such as a projector. It is used as For example, illumination light from the tip of the optical fiber 9 can be used as a minute illumination light source used for an endoscope or the like.

  FIG. 1 is a schematic view showing an example of the configuration of the optical system 100, and FIG. 1 (a) is a view from the y-axis direction, and FIG. 1 (b) is from the z-axis direction. It is a figure when it sees.

(Schematic Configuration of Optical System 100)
As shown in FIG. 1A, the optical system 100 includes a light emitting device (light source) 1, a reflecting mirror (first optical member) 3, a condensing lens (second optical member) 4 and a collimating lens 8. There is. The optical system 100 causes a plurality of light beams emitted from the plurality of light emitting devices 1 to be incident on an optical fiber (light guide member) 9 via the reflection mirror 3 and the condenser lens 4. Specifically, the optical system 100 causes the reflection mirror 3 to reflect the laser beam from the semiconductor laser 2 included in the light emitting device 1, and causes the incident light 9 a of the optical fiber 9 to be condensed through the condensing lens 4.

  Hereinafter, configurations of respective members provided in the optical system 100 will be described.

(Light-emitting device 1)
The light emitting device 1 is a device that emits laser light toward the reflection mirror 3. As shown in (a) of FIG. 1, the light emitting device 1 includes a semiconductor laser (light source) 2 and a heat radiating portion 5.

(Semiconductor laser 2)
The semiconductor laser 2 is a light source for emitting excitation light. As shown in FIG. 1B, in the present embodiment, three semiconductor lasers 2a to 2c that oscillate in red, blue and green are used as the semiconductor laser 2. By causing the three color laser beams to efficiently enter one optical fiber 9, it is possible to obtain a white laser beam uniformly mixed at the emitting end 9b of the optical fiber 9. The number of semiconductor lasers 2 may be appropriately determined according to the output of the desired excitation light.

(The heat release unit 5)
The heat radiating portion 5 includes a heat sink 6 and a heat radiating fin 7. The heat radiating portion 5 radiates the heat generated by the semiconductor laser 2 to the outside. As a result, even when high-power excitation light is obtained, the heat generated by each of the semiconductor lasers 2 can be properly dissipated, so that the decrease in the life and emission efficiency of the semiconductor laser 2 can be suppressed. Can.

  The heat sink 6 is a heat conducting member for radiating the heat generated by the semiconductor laser 2 to the outside of the light emitting device 1. The heat sink 6 is provided between the semiconductor laser 2 and the radiation fin 7, and transfers the heat received from the junction surface with the semiconductor laser 2 to the radiation fin 7.

  The radiation fins 7 receive the heat generated by the semiconductor laser 2 from the heat sink 6 and radiate the heat to the atmosphere.

  The heat sink 6 and the heat radiation fins 7 are made of a material having high thermal conductivity, and for example, it is preferable to be made of a metal (for example, Al) having high thermal conductivity.

(Arrangement of the semiconductor laser 2)
As described above, the optical system 100 includes the three semiconductor lasers 2a to 2c. The semiconductor lasers 2a to 2c are arranged such that the optical paths of the laser beams emitted from the semiconductor lasers 2a to 2c form an angle with the optical axis of the condenser lens 4 (the + Z axis direction in FIG. 1). ing.

  The optical axis of the focusing lens 4 is a straight line passing through the center of the focusing lens 4 and perpendicular to the surface of the focusing lens 4. In other words, the optical axis of the focusing lens 4 is a straight line passing the center of the focusing lens 4 and the focal point.

  As described above, the semiconductor lasers 2a to 2c are disposed so as to irradiate the reflecting mirror 3 with a plurality of light having a relative angle, instead of making the light parallel to each other incident on the reflecting mirror 3. . That is, the semiconductor lasers 2a to 2c are not disposed on a virtual plane parallel to the XY coordinate plane in FIG. 1, but are three-dimensionally disposed in a three-dimensional space that can be expressed by the XYZ coordinates. It is done.

  Therefore, the degree of freedom of the arrangement of the semiconductor lasers 2a to 2c is high, and the semiconductor lasers 2 can be arranged separately. As a result, the interference of heat generation can be reduced, and many semiconductor lasers 2 can be disposed for one optical fiber 9. In addition, the number of light emitting devices 1 (semiconductor lasers 2) and the arrangement method thereof are not limited to those shown in FIG.

(Reflecting mirror 3)
The reflection mirror 3 is disposed on the optical axis of the condenser lens 4 and reflects a plurality of reflection surfaces 3a to 3r that reflect the laser beams (laser beams emitted from different directions) emitted from the light emitting devices 1a to 1c. has c. The laser beams from the light emitting devices 1a to 1c are reflected by the reflecting surfaces 3a to 3c, respectively, and are guided to the focusing lens 4 by changing their traveling directions. The optical path of the light reflected by the reflection mirror 3 is parallel to the + Z axis and the optical axis of the condenser lens 4.

  The reflection mirror 3 is a triangular weight, and three triangular side surfaces of the triangular weight are reflection surfaces 3a to 3c for reflecting the respective laser beams. Although these reflective surfaces 3a-c are coated with aluminum, for example, the formation method of reflective surfaces 3a-c is not limited to this. For example, mirrors using total reflection on the glass surface may be used as the reflection surfaces 3a to 3c, and the reflection mirror 3 may be an optical member that can change the traveling direction of the laser beam.

(Condenser 4)
The condenser lens 4 is an optical member that condenses the light whose traveling direction has been changed by the reflection mirror 3. The three laser beams reflected by the reflection mirror 3 are incident on the condensing lens 4 and condensed on the incident end 9 a of the optical fiber 9.

  When a spherical plano-convex lens is used as the condenser lens 4, it is possible to condense light with a small aberration. In this case, the curved surface side of the spherical plano-convex lens is disposed on the parallel light side, and the flat surface side is disposed on the condensing side. The condensing lens 4 is not limited to a spherical plano-convex lens, and a lens with a preferable design may be used as appropriate.

(Collimator lens 8)
The collimator lens 8 is an optical member that performs optical adjustment so that laser light is in parallel by using refraction. That is, the laser light emitted from the light emitting device 1 is converted into parallel light by the collimator lens 8 and is emitted to the reflection mirror 3. As the collimating lens 8, a lens with an optimum design may be used as appropriate. The collimating lens 8 need not necessarily be provided.

(Optical fiber 9)
The optical fiber 9 is a light guiding member for guiding the light condensed by the condensing lens 4 and includes an incident end 9 a and an emission end 9 b. The optical fiber 9 may be appropriately designed in an optimal design. As the optical fiber 9, for example, a quartz fiber with a core diameter of 100 μm can be used.

<Effect of Optical System 100>
As described above, in the optical system 100, as the laser beams emitted from the three semiconductor lasers 2a to 2c are reflected by the reflection mirror 3, the traveling direction of the laser beams is changed, and the laser beams are guided to the condenser lens 4. .

  Therefore, the number and arrangement of the semiconductor lasers 2 can be made as desired by appropriately setting the number and arrangement of the reflection surfaces of the reflection mirror 3.

  As a result, the light emitting devices 1 can be arranged three-dimensionally, and the limitation caused by the size of the package of the individual semiconductor lasers 2 and the size of the heat sink 6 is reduced, and the optical paths of a plurality of laser beams can be brought close It becomes. Therefore, γ in the above equation (1) can be made as close to 1 as possible. Therefore, many semiconductor lasers 2 can be disposed (N can be increased).

  In addition, since a plurality of collimated laser beams are in close proximity, the aberration at the condenser lens 4 is small, and the laser beams can be efficiently incident on the optical fiber 9.

Second Embodiment
Another embodiment of the present invention is described below with reference to FIG. In addition, about the member which has the same function as the member demonstrated in the said embodiment for convenience of explanation, the same code | symbol is appended and the description is abbreviate | omitted.

  Hereinafter, in the present embodiment, collimated light emitted from four different directions is guided to the condensing lens 4 by changing the traveling direction of the light by reflection, and the light is condensed by the condensing lens 4, and the rod The optical system 110 that can be made incident on the lens 27 will be described.

  FIG. 2 shows an example of the configuration of the optical system 110. FIG. 2 (a) is a view of the optical system 110 as viewed from the y-axis direction, and FIG. 2 (b) is an optical system 110. Is viewed from the z-axis direction.

(Outline configuration of optical system)
First, the schematic configuration of the optical system 110 will be described based on FIG.

  The optical system 110 includes a light emitting device (light source) 11, a reflection mirror (first optical member) 13, a collimator lens 8 and a condenser lens 4 as shown in FIG. 2A.

  The optical system 110 is an optical system that causes the light emitted from the light emitting device 11 to be reflected by the reflection mirror 13 and causes the light to enter the optical fiber 9 via the condenser lens 4. Specifically, the optical system 110 collimates the laser light emitted from the semiconductor laser 12 in the light emitting device 11 through the collimator lens 8. Then, the traveling direction of the parallel light is changed by the reflection mirror 13 and guided to the condensing lens 4, and the parallel light is condensed on the input end of the optical fiber 9 by the condensing lens 4.

  The optical system 110 constitutes a part of the illumination device, and the laser light collected by the optical system 110 is irradiated to the phosphor light emitting unit 10 through the optical fiber 9. The phosphor light emitting unit 10 emits fluorescence by receiving laser light, and this fluorescence is used as illumination light.

  Hereinafter, configurations of respective members provided in the optical system 110 will be described.

(Light-emitting device 11)
A light emitting device 11 shown in (a) of FIG. 2 includes a semiconductor laser 12 and a heat radiating portion 5. The semiconductor laser 12 uses a high-power laser with a wavelength of 405 nm mounted in a 5.6 mm パ ッ ケ ー ジ package.

  As shown in FIG. 2B, the optical system 110 uses four semiconductor lasers 12 (semiconductor lasers 12a to 12d). In FIG. 2A, the semiconductor lasers 2b and 2c are omitted.

  The laser beams from the four semiconductor lasers 12 a to 12 d are emitted from mutually different directions (+ X, −X, + Y, −Y directions), and the traveling direction of the laser beams is the condensing lens 4 by the reflection mirror 13. It is bent in the direction of the optical axis (+ Z direction).

  Thus, the light emitting devices 11 are three-dimensionally arranged in the same manner as the light emitting devices 1. In addition, the arrangement method of the light-emitting device 11 is not limited to this.

(Reflecting mirror 13)
The reflection mirror 13 is an optical member that changes the traveling direction of the light emitted from the semiconductor laser 12. The reflection mirror 13 has a quadrangular pyramid shape, and the four side faces of the triangle of the quadrangular pyramid are reflection surfaces 13a to 13d for reflecting the respective laser beams. Although the reflective surfaces 13a to 13d are coated with aluminum, the method of forming the reflective surfaces 13a to 13d is not limited to this. For example, a mirror or the like using total reflection on a glass surface may be used, and the reflection mirror 13 may be an optical member that can change the traveling direction of the laser beam.

(Phosphor emitting part 10)
The fluorescent substance light emission part 10 is what sealed the fluorescent substance which shows fluorescence by receiving a laser beam by a sealing material, or what hardened the fluorescent substance. As the above-mentioned fluorescent substance, for example, an oxynitride-based phosphor (for example, a sialon phosphor) or a III-V compound semiconductor nanoparticle phosphor can be used. These fluorescent materials have high heat resistance to high power (and / or light density) laser light, and are suitable for a laser illumination light source. However, the said fluorescent substance is not limited to the above-mentioned thing, Other fluorescent substances, such as a nitride fluorescent substance, may be sufficient.

<Effect of Optical System 110>
In the optical system 110 of the present embodiment, four semiconductor lasers 2 emitting laser light of the same wavelength are optically coupled to one optical fiber 9, and each semiconductor laser 2 oscillates at an output of 1 W. In this case, an output of 3.8 W can be obtained at the output end 9 b of the optical fiber 9.

  Therefore, high-output laser light can be emitted to the phosphor light emitting unit 10, and a high-intensity lighting device can be realized.

  Thus, in the optical system 110, only the laser beam emitted from the single semiconductor laser 2 is synthesized by combining a plurality of laser beams having substantially the same peak wavelength (the peak wavelength is within the predetermined error range). A laser beam with a larger radiant flux can be obtained than when using

  An optical system that generates light of a desired color by mixing a plurality of lights having completely different wavelengths has conventionally been present. The present invention is not intended to produce light of a desired color, but to enhance the luminous flux of the light. In this respect, the present invention is essentially different from conventional optical systems.

(Modification of optical system 110)
FIG. 3 is a view showing an optical system 120 which is a modified example of the optical system 110. As shown in FIG. Unlike the optical system 110 that reflects light emitted from four different directions, as shown in FIG. 3, the optical system 120 is configured to include eight semiconductor lasers 11 and an octagonal reflecting mirror 14. There is. That is, the optical system 110 is configured to reflect light emitted from eight different directions.

  In the case of the configuration of the optical system 120, it is natural that the emission energy from the optical fiber 9 can be increased by an amount corresponding to the increase in the number of semiconductor lasers 11 used, but unlike the conventional optical system, the semiconductor laser 11 The present invention is characterized in that the coupling efficiency to the optical fiber 9 is not reduced even if the number of the optical fibers increases. That is, when one semiconductor laser 11 is added, the amount of increase of the emission energy can be increased as compared with the conventional optical system.

Third Embodiment
Yet another embodiment of the present invention will be described below with reference to FIG. In addition, about the member which has the same function as the member demonstrated in the said embodiment for convenience of explanation, the same code | symbol is appended and the description is abbreviate | omitted.

  Hereinafter, in the present embodiment, the traveling direction of light is changed by two-step reflection, and the light will be described in the optical system 130. The number of reflections is not limited to this.

  FIG. 4 shows an example of the configuration of the optical system 130, and FIG. 4 (a) is a view when the optical system 130 is viewed from the y-axis direction, and FIG. 4 (b) is a light emitting device 21 is a diagram when viewing 21 from the z-axis direction.

(Schematic Configuration of Optical System 130)
First, the schematic configuration of the optical system 130 will be described based on FIG.

  The optical system 130 includes a light emitting device (light source) 21, a reflection mirror (third optical member) 23, a reflection mirror (first optical member) 24, a collimator lens 8, and a condenser lens, as shown in FIG. It has four.

  The optical system 130 is an optical system that causes the reflection mirror 23 and the reflection mirror 24 to reflect the laser light emitted from the light emitting device 21 and causes the light to enter the rod lens 27 via the condenser lens 4. Specifically, the optical system 130 converts the laser light emitted from each of the semiconductor lasers 22a and 22b mounted in the light emitting device 21 into parallel light through the collimator lens 8, and the traveling direction of the parallel light with the reflection mirror 23 To the reflection mirror 24. Then, the light reflected by the reflection mirror 23 is reflected again by the reflection mirror 24, and the light is condensed by the condensing lens 4 on the incident end 27 a of the rod lens 27.

  Hereinafter, configurations of respective members provided in the optical system 130 will be described.

(Light-emitting device 21)
A light emitting device 21 shown in (a) of FIG. 4 includes a semiconductor laser (light source) 22 and a heat radiating portion 25.

  The light emitting device 21 includes six semiconductor lasers 22 on the surface of a heat sink (base material) 26, as shown in FIG. 4B. As the semiconductor laser 22, a high-power laser with a wavelength of 450 nm mounted in a 5.6 mm mm package is used.

  The six semiconductor lasers 22 are disposed on the surface of the heat sink 26 which is a common base material. Specifically, the six semiconductor lasers 22 are arranged on a virtual plane parallel to the XY plane in (a) and (b) of FIG. 4.

  The type of light source provided in the light emitting device 21 is not limited to the semiconductor laser. Further, the number of light sources is not limited to six.

  As shown in (a) of FIG. 4, the laser beam from the semiconductor laser 22 is emitted in the same direction as the optical axis (+ Z direction) of the condensing lens 4. The emitted laser light is reflected by the reflection mirror 23 and the reflection mirror 24, whereby the traveling direction of the laser light is bent in the direction (+ Z direction) of the optical axis of the condensing lens 4.

  The heat radiating portion 25 includes a heat sink 26 and a heat radiating fin 7. As shown in FIG. 4B, the heat sink 26 is circular, and six semiconductor lasers 22 are arranged in a circle. With this configuration, it is sufficient to provide one common heat sink 26 for the plurality of semiconductor lasers 22, and the alignment of the semiconductor lasers 22 can be facilitated.

  The shape of the heat sink 26 and the arrangement method of the semiconductor lasers 22 are not limited to those shown in FIG. 4 and may be any shape.

(Reflecting mirror 23)
As shown in (a) of FIG. 4, the reflection mirror 23 is an optical member that reflects the light from the plurality of light emitting devices 21 toward the reflection mirror 24. The plurality of reflection mirrors 23 are disposed at positions corresponding to the plurality of semiconductor lasers 22 disposed on the surface of the heat sink 26. Since six semiconductor lasers 22 are arranged, six reflection mirrors 23 are also arranged.

  As these reflecting mirrors 23, for example, in addition to a mirror using a metal reflecting surface having high reflectance such as aluminum or a vapor deposition surface, a mirror formed of a dielectric multilayer film, or total reflection at a glass / air interface is used. A mirror can be used. However, the reflection mirror 23 is not limited to these mirrors. The number of reflection mirrors 23 may be set according to the number of semiconductor lasers 22 and is not limited to six.

(Reflecting mirror 24)
The reflection mirror 24 is a hexagonal mass, and the side faces of six triangles of the hexagonal mass function as reflection surfaces for reflecting the laser light reflected by the reflection mirror 23 respectively.

  The reflecting mirror 24 does not have to be a hexagonal mass, and may be six mirrors. However, by using a polygonal pyramid such as a hexagonal pyramid as the reflection mirror 24, it is not necessary to individually adjust the angle of each mirror individually, and the number of steps required for alignment and the cost can be reduced.

(Rod lens 27)
The rod lens 27 is a light guiding member which guides the light incident from the incident end 27 a and emits the light from the emitting end 27 b. For example, a quartz rod with an outer diameter of 1 mm can be used as the rod lens 27 used in the present embodiment. However, a prismatic rod may be used as the rod lens 27, and the shape, size, and material of the rod lens 27 are not particularly limited.

<Effect of Optical System 130>
In the optical system 130 of the present embodiment, in order to arrange the semiconductor laser 2 in a plane on the surface of the heat sink 26, the mounting accuracy of the semiconductor laser 2 can be enhanced.

  Furthermore, since the intervals of the plurality of collimated laser beams can be made sufficiently close in front of the condensing lens 4, the aberration at the condensing lens 4 is small, and the laser beams are efficiently incident on the rod lens 27. I can do it.

Embodiment 4
Still another embodiment of the present invention will be described below with reference to FIGS. In addition, about the member which has the same function as the member demonstrated in the said embodiment for convenience of explanation, the same code | symbol is appended and the description is abbreviate | omitted.

  Hereinafter, in the present embodiment, an optical system 200 in which a semiconductor laser and a reflection mirror are mounted on the same base material will be described.

(Outline configuration of optical system)
First, a schematic configuration of the optical system 200 will be described based on FIG. FIG. 5 is a schematic view showing an example of the configuration of the optical system 200. As shown in FIG.

  The optical system 200 includes a light source unit 201 and a condenser lens 4. The optical system 200 is an optical system that causes the light emitted from the light source unit 201 to enter the optical fiber 9 via the condenser lens 4. Specifically, the optical system 200 collimates the laser light emitted from the plurality of light emitting devices 31 mounted in the light source unit 201 through the collimator lens 8. Then, the traveling direction of the parallel light is changed by the reflection mirror (first optical member) 34, and the laser light is guided from the window 51 to the condensing lens 4 provided outside the light source unit 201. The collimated light is condensed on the incident end 9 a of the optical fiber 9.

  Hereinafter, configurations of respective members provided in the optical system 200 will be described.

(Light source unit 201)
The light source unit 201 is a device for emitting light toward the condensing lens 4, and the light emitting device 31 including the light source and the reflection mirror 34 are mounted on the same base material.

  FIG. 6 shows an example of the configuration of the light source unit 201 included in the optical system 200. (A) of FIG. 6 is a top view of the light source unit 201, and (b) of FIG. 6 is a cross-sectional view of the light source unit 201 in the cross section of A-A 'shown in (a) of FIG. FIG. 7A is a perspective view of the light emitting device 31, and FIG. 7B is a plan view of the light source unit 201. As shown in FIG.

  As shown in FIG. 6, the light source unit 201 includes a light emitting device 31, a collimating lens 8, a reflecting mirror 34, a copper block (base material) 41, a stem 42, lead terminals 43, wires 44 and a package 50.

(Light-emitting device 31)
The light emitting device 31 is a device that emits light to the reflecting mirror 34. As shown in (a) of FIG. 7, the light emitting device 31 includes a semiconductor laser 32 and a submount 33. As shown in (b) of FIG. 7, twelve light emitting devices 31 are arranged in a circle on the surface of the copper block 41.

(Semiconductor laser 32)
The semiconductor laser 32 is a light source for emitting excitation light. As the semiconductor laser 32, twelve LD chips are used. The laser beam emitted from the semiconductor laser 32 is irradiated to the reflection mirror 34 through the collimator lens 8. The number, type, and arrangement method of the light emitting devices 31 (semiconductor lasers 32) are not limited to those described above.

  The semiconductor laser 32 is connected to the lead terminal 43 via the wire 44 and receives power from the external power supply via the lead terminal 43.

(Submount 33)
The submount 33 fixes the semiconductor laser 32 and transfers the heat emitted from the semiconductor laser 32 to the copper block 41. The submount 33 is made of a material having high thermal conductivity, and is preferably made of, for example, a metal having high thermal conductivity (e.g., Al).

(Reflecting mirror 34)
The reflection mirror 34 is an optical member that changes the traveling direction of the laser light emitted from the light emitting device 31 to a predetermined direction, and is disposed on the surface of the copper block 41. That is, the light emitting device 31 and the reflection mirror 34 are disposed on the copper block 41 which is a common base material.

  The reflection mirror 34 has a shape of a dodecahedron, and 12 side faces of a triangle possessed by the dodecahedron are reflection surfaces for the respective laser beams. The reflective surface is coated with aluminum, but the method of forming the reflective surface is not limited to this. For example, a mirror or the like using total reflection on the glass surface may be used, and the reflection mirror 34 may be an optical member that can change the traveling direction of the laser beam.

(Copper block 41)
The copper block 41 is a heat sink that receives the heat emitted from the semiconductor laser 32 via the submount 33 and releases the heat to the atmosphere. Although copper is used as a material of such a heat sink in the present embodiment, metals other than copper may be used, and for example, a metal having a high thermal conductivity (for example, Al) may be used. .

(Stem 42)
The stem 42 is a member for fixing the copper block 41.

(Package 50)
The package 50 is a member that protects the light source unit 201, and includes a window 51 and a cap 52. The window 51 is a member for guiding the light whose traveling direction has been changed by the reflection mirror 34 to the condensing lens 4. The window 51 is, for example, a glass plate, but may be a transparent member through which light can pass.

(Manufacturing process)
The manufacturing process of the light source unit 201 will be described. FIG. 7 is a view showing a part of the manufacturing process of the light source unit 201. As shown in FIG. 7A is a perspective view of the light emitting device 31, FIG. 7B is a plan view of the light source unit 201, FIG. 7C is a cross sectional view of the light source unit 201 before the package 50 is attached, FIG. 4D is a cross-sectional view of the light source unit 201 after the package 50 is attached.

  First, as shown in FIG. 7A, the semiconductor laser 32 is fixed on the submount 33 using solder to form the light emitting device 31.

  Then, as shown in (b) of FIG. 7, first, the reflection mirror 34 is attached to the center of the copper block 41. Next, twelve collimating lenses 8 are mounted around the reflecting mirror 34 in a circle. Furthermore, twelve light emitting devices 31 are mounted in a circle around the collimating lens 8.

  Next, as shown in (c) of FIG. 7, wires 44 are stretched between the semiconductor lasers 32 and the lead terminals 43 and between the copper block 41 and the submount 33.

  Thereafter, as shown in FIG. 7D, the package 50 is fixed on the stem 42, and the light source unit 201 is completed.

<Effect of Optical System 200>
In the optical system 200 of the present embodiment, twelve semiconductor lasers 32 and reflection mirrors 34 are fixed to a copper block 41 which is a common substrate. Therefore, when constructing the optical system 200, it is not necessary to adjust the relative positional relationship between the plurality of semiconductor lasers 32 and the reflection mirror 34, and a large output lighting device can be easily realized.

  Further, since the members from the semiconductor laser 32 to the reflection mirror 34 can be mounted in one package, the size of the entire optical system 200 can be reduced.

  Furthermore, since the distances between the plurality of collimated laser beams can be sufficiently close in front of the focusing lens 4, the aberration in the focusing lens 4 located immediately in front of the optical fiber 9 can be reduced, and the laser light can be efficiently transmitted. It can be incident on the fiber 9. Therefore, a high-intensity lighting device can be realized.

[Summary]
The optical system according to aspect 1 of the present invention is
An optical system for condensing light onto a light guide member,
A first optical member (reflection mirror 3, reflection mirror 13, reflection mirror 24 and reflection mirror 34), and a second optical member (condensing lens 4),
The first optical member changes the traveling direction of the light emitted from the plurality of light sources (the semiconductor laser 2, the semiconductor laser 12, the semiconductor laser 22, and the semiconductor laser 32) to change the light to the second optical member. The second optical member condenses the light whose traveling direction has been changed by the first optical member, and causes the light to be incident on the light guide member.

  According to said structure, the advancing direction of the light radiate | emitted from several light sources is first changed by the 1st optical member. Thereby, the light is directed to the second optical member. The second optical member condenses the light whose traveling direction has been changed, and causes the light to be incident on the light guide member.

  Therefore, even when the area of the light incident surface of the light guide member is small, the light emitted from the plurality of light sources can be incident on the light incident surface. Moreover, since the advancing direction of light can be changed by the 1st optical member, the freedom degree of arrangement | positioning of several light sources can be raised. As a result, it is possible to use more light sources than ever before, and in a simple way it is possible to make the light guiding member stronger than before.

  In the optical system according to aspect 2 of the present invention, in the above aspect 1, preferably, the first optical member has a plurality of reflecting surfaces that respectively reflect light emitted from different directions.

  According to the above configuration, the number and arrangement of the plurality of light sources can be made as desired by setting the number and the angle of the reflecting surface of the first optical member.

In the optical system according to aspect 3 of the present invention, in the above aspect 1 or 2,
The plurality of light sources are disposed on a common substrate,
It is preferable to further include a plurality of third optical members (reflection mirrors 23) for guiding the light to the first optical member by reflecting the light emitted from the plurality of light sources.

  According to the above configuration, a plurality of light sources can be disposed on a common base material, and the structure for dissipating the light sources can be simplified.

Furthermore, in the optical system according to aspect 4 of the present invention, in the above aspect 1 or 2,
Further comprising the plurality of light sources
The plurality of light sources and the first optical member are preferably disposed on a common base material.

  According to the above configuration, the plurality of light sources and the first optical member can be disposed on a common base material, and the relative positional relationship between the light source and the first optical member can be fixed and the heat source is dissipated The structure can be simple.

Furthermore, in the optical system according to aspect 5 of the present invention, in any of the above aspects 1 to 4,
It is preferable to further include a collimator lens (8) for converting light emitted from the light source into parallel light.

  According to the above configuration, light having high directivity can be generated, and the accuracy of light distribution control can be enhanced.

  The present invention can be used as an optical system that combines light used in various light emitting devices or lighting devices.

2 Semiconductor laser (light source)
3 Reflecting mirror (first optical member)
4 Condenser lens (2nd optical member)
8 Collimator lens 12 Semiconductor laser (light source)
13 Reflection mirror (first optical member)
22 Semiconductor laser (light source)
23 Reflection mirror (third optical member)
24 Reflecting mirror (first optical member)
32 Semiconductor laser (light source)
34 Reflection mirror (first optical member)
41 Copper block (base material)
26 Heat sink (base material)
100 optical system 110 optical system 120 optical system 130 optical system 200 optical system

Claims (9)

An optical system for condensing light onto a light guide member,
A first reflecting mirror,
Equipped with a condenser lens,
The first reflection mirror guides the laser beam to the focusing lens by changing the traveling direction of the laser beam emitted from a plurality of light sources and having a relative angle ,
The condensing lens condenses the laser light whose traveling direction has been changed by the first reflection mirror, and causes the laser light to be incident on the light guiding member,
It further comprises a plurality of second reflection mirrors for guiding the laser light to the first reflection mirror by reflecting the laser light emitted from the plurality of light sources ,
Laser light from the plurality of the light sources, an optical system according to claim Rukoto emitted in the same direction as the optical axis of the condensing lens.   The plurality of light sources are arranged on a virtual plane, the laser beams emitted from the plurality of light sources are parallel, and the intervals of the parallel laser beams whose traveling direction is changed by the first reflecting mirror are the plurality The optical system according to claim 1, characterized in that it is narrower than the interval of parallel laser beams emitted from the light source of (1).   The optical system according to claim 1 or 2, wherein the first reflection mirror and the second reflection mirror are mirrors using total reflection at an interface of glass and air.   The optical system according to any one of claims 1 to 3, further comprising a collimator lens that converts laser light emitted from the light source into parallel light.   The optical system according to claim 1, wherein the first reflection mirror is the same number of mirrors as the plurality of light sources. The direction of the optical axis of the focusing lens is the Z direction, an arbitrary direction perpendicular to the Z direction is the X direction, the direction perpendicular to the Z direction and the X direction is the Y direction, the X direction and the Y When the plane containing the direction is the XY plane,
The plurality of laser beams incident on the first reflection mirror are incident on the first reflection mirror on virtual planes parallel to the XY plane and in directions different from each other. The optical system according to 1.   The optical system according to claim 1, wherein the first reflection mirror has a plurality of reflection surfaces.   The optical system according to claim 1, wherein the first reflection mirror has the same number of reflection surfaces as the plurality of light sources.   The optical system according to claim 1, wherein the plurality of light sources are arranged in a circle around an optical axis of the condenser lens.

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