JP2014010918A - Luminaire and vehicle headlight - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the possibility of a laser beam leaking to outside.SOLUTION: A head lamp 1 includes: a light emission unit 14 that receives a laser beam to emit spontaneous emission light; a multi-core fiber 20 that guides the spontaneous emission light; a light projection unit 30 that projects the guided spontaneous emission light as illumination light to outside; and a laser beam cut filter 17 that prevents the multi-core fiber 20 from guiding a laser beam.

Description

  The present invention relates to an illumination device and a vehicle headlamp that generate illumination light by exciting phosphors with laser light.

  Patent Document 1 discloses an example of an illumination device that uses, as illumination light, fluorescence generated by irradiating a phosphor with laser light emitted from a laser light source. The vehicle headlamp described in Patent Document 1 includes a plurality of light source units that generate white light by irradiating a phosphor with laser light (ultraviolet light), and emits white light having a predetermined light distribution pattern. Irradiate forward.

JP 2005-150041 A (released on June 9, 2005)

  However, in the conventional vehicle headlamp described above, no consideration is given to how to deal with a vehicle headlamp that uses laser light as excitation light due to an accident or the like. Laser light is coherent and has a very small light emission point, which may adversely affect the eyes. Therefore, it is preferable to provide a configuration that reduces the possibility of laser light leaking to the outside due to damage to the vehicle headlamp. This can be said not only for vehicle headlamps but also for all lighting devices that use laser light as excitation light.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an illuminating device that can reduce the possibility of laser light leaking to the outside.

In order to solve the above-described problem, an illumination device according to the present invention
A light emitting unit that emits spontaneously emitted light in response to laser light emitted from a laser light source;
A light guide unit that guides spontaneously emitted light emitted from the light emitting unit from the incident end to the exit end;
A light projecting unit that projects spontaneously emitted light emitted from the exit end to the outside as illumination light; and
The light guide part includes a blocking part for preventing the laser light from being guided.

  According to said structure, the laser beam radiate | emitted from the laser light source is converted into spontaneous emission light by the light emission part, and is light-guided by the light guide part to a light projection part. Further, a blocking unit is provided to prevent the light guide unit from guiding the laser beam.

  Therefore, laser light that has not been converted into spontaneously emitted light from the laser light emitted from the laser light source can be prevented from being guided to the light projecting unit by the light guide unit. As a result, even if the light projecting portion is damaged due to an accident or the like, the possibility that the laser light leaks to the outside can be reduced.

  In addition, the blocking unit is a filter that blocks the laser beam, and is preferably disposed at or near the incident end.

  According to said structure, it can prevent that a laser beam injects from the said incident end part with the interruption | blocking part distribute | arranged to the incident end part or its vicinity.

  Moreover, it is preferable that the said illuminating device is further provided with the condensing part which condenses the spontaneous emission light which the said light emission part emitted on the said incident end part.

  With the above configuration, the efficiency when spontaneously emitted light is incident on the light guide unit can be increased.

  Moreover, it is preferable that the said interruption | blocking part is distribute | arranged on the optical path of the spontaneous emission light condensed by the said condensing part.

  With the above configuration, when the laser beam is included in the light condensed by the condensing unit, the laser beam can be blocked before the laser beam reaches the incident unit of the light guide unit.

  Moreover, it is preferable that the said light collection part is a reflective mirror.

  With the above configuration, spontaneous emission light can be collected more efficiently than when a lens is used as the light collecting unit.

The blocking unit is disposed between the light emitting unit and the light collecting unit,
The condensing part preferably condenses the light transmitted through the blocking part at the incident end.

  According to said structure, since the light which permeate | transmitted the interruption | blocking part is condensed by the incident part by the condensing part, it can prevent that a laser beam injects into an incident part.

  The oscillation wavelength of the laser light source is preferably 240 nm or more and 415 nm or less.

  By setting the wavelength of the laser light to 240 nm or more and 415 nm or less, it is possible to select the wavelength of the laser light and the type of phosphor contained in the light emitting portion without using the laser light itself as part of the illumination light. It becomes easy to generate fluorescence.

  Moreover, it is preferable that the said light guide part is an optical fiber.

  With the above configuration, the distance between the laser light source and the light projecting unit can be easily separated, and the positional relationship between the two can be easily set. The optical fiber may be a multi-core fiber or a bundle fiber.

  Moreover, the vehicle headlamp provided with the said illuminating device is also contained in the technical scope of this invention.

  The illumination device according to the present invention, as described above, receives a laser beam emitted from a laser light source and emits spontaneous emission light, and emits spontaneous emission light emitted from the light emission unit from an incident end to an emission end. A light guide unit that guides the laser light to the outside, a light projecting unit that projects spontaneously emitted light emitted from the output end as illumination light, and a shield that prevents the light guide unit from guiding laser light. It is the structure provided with a part.

  Therefore, even if the light projecting portion is damaged due to an accident or the like, the possibility that the laser light leaks to the outside can be reduced.

It is a figure which shows the structure of the headlamp which concerns on one Embodiment of this invention. (A) And (b) is a figure which shows the example of the incident end surface of the multi-core fiber with which the said headlamp is provided. It is a figure which shows an example of the arrangement | positioning position of the said headlamp. It is a figure which shows the modification of the said headlamp. It is a figure which shows another modification of the said headlamp. It is a figure which shows the structure of the headlamp which concerns on another embodiment of this invention. It is a figure which shows the structure of the headlamp which concerns on another embodiment of this invention. It is sectional drawing which shows the positional relationship of an optical fiber and a bundle fiber. It is sectional drawing which shows the example of a change of the light guide member applicable to the said headlamp. It is a figure which shows the structure of the headlamp which concerns on another embodiment of this invention. It is a figure which shows the structure of the headlamp which concerns on another embodiment of this invention.

  Here, a headlamp (vehicle headlamp) will be described as an example of the illumination device of the present invention. However, the lighting device of the present invention may be realized as a headlamp of a vehicle other than an automobile or a moving object (for example, a human, a ship, an aircraft, a submersible craft, a rocket), or may be realized as another lighting device. Also good. Examples of other lighting devices include a searchlight, a projector, a home lighting device, a commercial lighting device, and an outdoor lighting device.

  In the following description, the same parts and components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

Embodiment 1
One embodiment of the present invention will be described below with reference to FIGS. The headlamp 1 (illumination device, vehicle headlamp) of the present embodiment is an illumination device that forms a specific light projection pattern (desired light projection pattern).

<Configuration of headlamp 1>
FIG. 1 is a diagram showing the configuration of the headlamp 1. As shown in FIG. 1, the headlamp 1 includes a light source unit 10, a multi-core fiber 20 (light guide unit), a light projecting unit 30, and a lighting control unit 50.

(Light source unit 10)
The light source unit 10 generates light having a light intensity distribution corresponding to the light projecting pattern (referred to as a light beam for projecting light) and causes the light beam for projecting light to enter the incident end face 20 a of the multicore fiber 20. The light beam for projecting light is spontaneous emission light emitted from the light emitting unit 14 described later, and does not include laser light.

  As shown in FIG. 1, the light source unit 10 includes a laser element (laser light source) 11, a heat radiating unit 12, a rising mirror 13, a light emitting unit 14, a support unit 15, an elliptical mirror (condensing unit) 16, and a laser light cut filter. (Blocking part) 17 is provided.

(Laser element 11)
The laser element 11 is a light emitting element that functions as a laser light source that emits laser light as excitation light, and is, for example, a semiconductor laser. As shown in FIG. 1, the light source unit 10 is provided with a plurality of laser elements 11, and laser light is oscillated from each of the plurality of laser elements 11. The laser element 11 may have one light emitting point on one chip, or may have a plurality of light emitting points on one chip.

  By using laser light as the excitation light, it is possible to efficiently excite phosphors included in the light emitting unit 14 described later, and to emit light having a higher brightness than that of the conventional light source, and further, the light emitting unit 14 itself Can be reduced in diameter. Further, since the laser element 11 is a high-intensity light source, it is possible to efficiently narrow the irradiation area formed on the laser light irradiation surface 14a of the light emitting section 14, and as a result, it is possible to project light with a narrow light distribution angle. It becomes.

  The number and arrangement of the laser elements 11 are not particularly limited, and a preferable number of laser elements 11 may be used in a preferable arrangement in order to form a desired light projection pattern.

  The oscillation wavelength of the laser light of the laser element 11 is not less than 240 nm and not more than 415 nm, for example, 395 nm (blue-violet). For example, the laser element 11 is mounted on a metal package having a diameter of 5.6 mm, and oscillates laser light having a wavelength of 395 nm with an output of 2 W.

  By making the wavelength of the laser light 240 nm or more and 415 nm or less, white fluorescence can be generated by selecting the wavelength of the laser light and the type of phosphor without using the laser light itself as part of the illumination light. Becomes easier.

  In addition, FIG. 1 shows a configuration in which a plurality of laser elements 11 are evenly arranged on the heat radiating portion 12, but this is not limiting, and the interval between adjacent laser elements 11 may be arbitrarily defined. Good.

(Heat dissipation part 12)
The heat radiating unit 12 functions as a heat radiating mechanism that radiates heat from the laser element 11 by receiving heat generated by the laser element 11 from the laser element 11. For this reason, it is preferable to use a metal material (aluminum or the like) having a high thermal conductivity for the heat dissipation part 12.

  Since the light source unit 10 including the heat radiating unit 12 is formed separately from the light projecting unit 30, the light projecting unit 30 can be reduced in size.

(Rising mirror 13)
The rising mirror 13 reflects each of the laser beams emitted from the plurality of laser elements 11 and guides the laser beams to the light emitting unit 14, thereby corresponding to the light projection pattern on the laser light irradiation surface 14 a of the light emitting unit 14. It is an optical member that forms a laser light irradiation pattern (hereinafter simply referred to as an irradiation pattern) having a light intensity distribution. The laser light irradiation surface 14a is a surface that is mainly irradiated with laser light among the surfaces of the light emitting unit 14.

  Specifically, the rising mirror 13 is, for example, an off-axis mirror, and the plurality of rising mirrors 13 are arranged one-on-one so as to face the light emitting points of the plurality of laser elements 11. . Further, the rising mirror 13 is arranged so that the light emitting point of the laser element 11 is positioned at a substantially focal position of the rising mirror 13.

  The laser light emitted from each of the plurality of laser elements 11 is reflected by the rising mirror 13 to become substantially collimated light, and after the beam width is compressed in the vertical direction, the elliptical mirror 16 is illustrated. It is guided to the light emitting unit 14 through a window portion that is not present.

  The optical path of the laser light emitted from the laser element 11 can be controlled by adjusting the installation angle of the rising mirror 13 and the relative position with the laser element 11, so that a desired irradiation pattern is formed on the laser light irradiation surface 14a. Easy to do. For example, by using the rising mirror 13, the laser light emitted from the laser element 11 can be compressed in the vertical direction, and a horizontally long irradiation pattern can be formed on the laser light irradiation surface 14 a of the light emitting unit 14.

  It is more preferable to use an aspherical mirror that corrects the astigmatic difference of the laser element 11 and produces collimated light as the rising mirror 13. In that case, the collimating property can be further improved. Further, the rising mirror 13 is not limited to this, and may be realized by other parabolic mirrors.

  Although FIG. 1 shows a configuration including the rising mirror 13, the optical member for forming the laser light irradiation pattern is not limited to this, and the rising mirror can also be formed by using a collimating lens and a plane mirror. 13 can be realized. Further, when a collimating lens or a collimating mirror is provided inside the laser element 11 so that collimated light can be emitted from the laser element 11, the rising mirror 13 is changed to a plane mirror. Similar functions can be realized.

(Material of rising mirror 13)
The upright mirror 13 is made by coating AlN ceramic as a material with Al as a reflection film and aluminum oxide as an antioxidant film, but is not limited to this configuration.

For example, as materials, it is desirable to use materials such as BK7, glass such as quartz glass, polycarbonate, acrylic, FRP, SiC, Al ₂ O _{3 and the} like with a small coefficient of thermal expansion, but the final collimation accuracy is not much required. If not, a metal such as Al may be used.

The reflective film is preferably a metal such as Ag or Pt, but may be a reflective film having a multilayer structure such as a SiO ₂ / TiO ₂ multilayer film.

  Further, silicon oxide or the like may be used for the antioxidant film. Note that the antioxidant film is not necessarily coated.

  Further, the surface of the rising mirror 13 may be provided with an increased reflection film (an increased reflection structure such as an HR coat film). In this case, the reflection loss (mirror loss) of the laser beam by the rising mirror 13 can be reduced.

(Light Emitting Unit 14)
The light emitting unit 14 includes a phosphor (fluorescent material) that absorbs laser light and emits fluorescence, and emits spontaneous emission light (fluorescence) in response to the laser light oscillated from the laser element 11.

  For example, the light-emitting portion 14 is formed on a substrate made of a material in which phosphor particles are dispersed (sealing type), a material in which phosphor particles are solidified, or a material having high thermal conductivity. A phosphor containing a phosphor such as (thin film type) coated (deposited) with phosphor particles.

  By using the light emitting unit 14 including such a phosphor, it is possible to generate illumination light with high color rendering properties.

In the present embodiment, the light emitting portion 14 is a 2 mm × 1 mm rectangle, and the phosphor powder is applied to the inclined portion 15a of the support portion 15 with TiO ₂ as a binder so as to form a thin film with a thickness of 0.1 mm. It is formed by doing.

  The light emitting unit 14 is disposed near one of the two focal points (first focal point) of the elliptical mirror 16 by the support unit 15. For this reason, the light emitted from the light emitting unit 14 is reflected by the reflection curved surface of the elliptical mirror 16, so that the optical path is controlled.

  The light emitting part 14 is preferably sufficiently small. In this case, the light emitted from the light emitting unit 14 can be efficiently condensed on the other focal point (second focal point) of the elliptical mirror 16.

  Moreover, it is desirable that the light emitting unit 14 is larger than the laser light irradiation pattern.

(Inclined arrangement of the light emitting unit 14)
The light emitting part 14 is inclined and arranged on the inclined part 15a of the support part 15 so that the fluorescence emitted from the light emitting part 14 can be efficiently reflected by the elliptical mirror 16 and controlled. Yes. The inclined portion 15a is configured to be inclined by about 15 ° in the incident direction with reference to a plane perpendicular to the incident direction of the laser beam.

  The light emitted from the light emitting unit 14 has a substantially Lambertian light distribution. Therefore, when the light emitting unit 14 is arranged so that the laser light irradiation surface 14a of the light emitting unit 14 is perpendicular to the incident direction of the laser light, the region with the highest luminous intensity of the light emitted from the light emitting unit 14 is obtained. Since it is located at the window portion of the elliptical mirror 16, the light projecting efficiency is deteriorated.

  In consideration of the light projection efficiency, it is desirable that the laser light irradiation surface 14a of the light emitting unit 14 is inclined by about 15 °. However, if the light projection efficiency is not considered, the laser light irradiation surface 14a is The light emitting unit 14 may be arranged so as to be perpendicular to the incident direction.

  Further, when the laser beam is transmitted through the window portion of the elliptical mirror 16 and the light emitted from the light emitting unit 14 is reflected, the manufacturing cost increases, but the laser beam irradiation surface 14a has the laser beam. Even if the light-emitting portion 14 is formed so as to be perpendicular to the incident direction, the light projecting efficiency is improved.

(Type of phosphor)
In the present embodiment, BAM (BaMgAl ₁₀ O ₁₇ : Eu is used as the phosphor of the light emitting unit 14 so as to emit white spontaneous emission light (fluorescence) upon receiving laser light having a wavelength of 395 nm oscillated by the laser element 11. _{), BSON (Ba 3 Si 6} O 12 N 2: Eu), Eu-α (Ca-α-SiAlON: Eu) , etc., are used as a mixture of plural kinds of phosphors. However, the phosphor is not limited to these. For example, when the headlamp 1 is used for an automobile, the illumination light of the headlamp 1 has a chromaticity within a predetermined range defined by law. What is necessary is just to select suitably so that it may become white which has. In addition, for applications such as lighting, phosphors may be used alone or a plurality of types of phosphors may be appropriately mixed so that necessary chromaticity is obtained.

For example, other oxynitride phosphors (for example, sialon phosphors such as JEM (LaAl (SiAl) ₆ N ₉ O: Ce) and β-SiAlON), nitride phosphors (for example, CASN (CaAlSiN ₃ : Eu)) Phosphor, SCASN ((Sr, Ca) AlSiN ₃ : Eu) phosphor), Apatite ((Ca, Sr) ₅ (PO ₄ ) ₃ Cl: Eu) system, Silicate ((Ba, Sr, Mg) ₂ SiO ₄ : Eu, Mn) -based phosphor or III-V compound semiconductor nanoparticle phosphor (for example, indium phosphorus: InP).

(Sealed type)
The sealing material in the case where the light emitting unit 14 is a sealing type is, for example, a resin material such as a glass material (inorganic glass or organic-inorganic hybrid glass) or a silicone resin. Low melting glass may be used as the glass material. The sealing material is preferably highly transparent, and when the laser beam has a high output, a material having high heat resistance is preferable. The structure may be sealed with silicon oxide or titanium oxide by a sol-gel method.

  An antireflection structure for preventing reflection of laser light may be formed on the upper surface (laser light irradiation surface 14a) of the light emitting unit 14. In the case of the sealed type, it is particularly desirable to form an antireflection film because it is easy to control the shape of the upper surface of the light emitting portion 14.

(Thin film type)
When the light emitting portion 14 is a thin film type, Al, Cu, AlN ceramic, SiC ceramic, aluminum oxide, Si, or the like is used as the substrate. Note that Al, Ag, BaSO ₄ or the like may be inserted between the substrate and the phosphor for the purpose of improving optical characteristics. After applying or depositing phosphor particles on the substrate, each substrate is divided into a desired size. Then, it fixes to the support part 15 with a high heat conductive adhesive.

  When Al, Cu or the like is used for the substrate, TiN, Ti, TaN, Ta, or the like is coated as a barrier metal on the side where the phosphor particles are not deposited (the side facing the support portion 15). It is desirable. Furthermore, Pt or Au may be coated on the barrier metal.

  Although it is desirable to use eutectic solder such as SnAgCu and AuSn as the high thermal conductive adhesive, it is not limited.

(Supporting part 15)
The support portion 15 made of a metal having high thermal conductivity supports the light emitting portion 14 at the inclined portion 15a at one end thereof, and is connected to the elliptical mirror 16 so that the light emitting portion 14 is positioned at a substantially focal position of the elliptical mirror 16. Has been.

  Although Al is used as the material of the support portion 15 in the present embodiment, high thermal conductive ceramics such as AlN and SiC may be used.

  Moreover, in this Embodiment, the light emission part 14 is being fixed to the support part 15 by apply | coating a fluorescent substance using a titanium oxide as a binder. As this binder, silicon oxide or the like may be used.

  When the light emitting unit 14 is a thin film type, it is desirable to coat TiN, Ti, TaN, Ta, or the like as a barrier metal on the surface of the support unit 15 that faces the light emitting unit 14. Furthermore, Pt or Au may be coated on the barrier metal.

  Note that the other end of the support portion 15 may pass through the elliptical mirror 16 and be connected to a heat dissipation member (not shown) having high thermal conductivity. For this reason, the heat of the light emitting portion 14 that generates heat by the laser light propagates to the support portion 15 and the heat radiating member, and is efficiently radiated.

(Elliptical mirror 16)
The elliptical mirror 16 is a reflecting mirror that condenses spontaneously emitted light emitted from the light emitting unit 14 onto the incident end face 20 a of the multicore fiber 20. The elliptical mirror 16 has a part of a curved surface formed when the ellipse is rotated about the symmetry axis of the ellipse as the shape of the reflecting surface. The elliptical mirror 16 has a first focal point on the side on which the laser beam is incident, and the light emitting unit 14 is installed in the vicinity of the first focal point. In addition, the incident end face 20 a of the multicore fiber 20 is located near the second focal point of the elliptical mirror 16.

  With this configuration, the light emitted by the light emitting unit 14 is reflected by the elliptical mirror 16, collected near the second focal point of the elliptical mirror 16, and then guided to the lens 31 by the multicore fiber 20. In FIG. 1, an optical path of light emitted from the light emitting unit 14 is indicated by reference numeral 18.

  The laser light emitted from the laser element 11 passes through or passes through the window formed in the elliptical mirror 16 and is irradiated on the light emitting unit 14. This window part may be a through-hole, or may include a transparent member capable of transmitting laser light.

  Further, the reflecting mirror included in the light source unit 10 is not necessarily an elliptical mirror, and the light source unit 10 may include a hemispherical mirror.

(Material of elliptical mirror 16)
In this embodiment, the elliptical mirror 16 is made of FRP as a base material, coated with Al as a reflective film, and further coated with silicon oxide for the purpose of preventing oxidation of Al.

  However, the configuration of the elliptical mirror 16 is not limited to that described above, and any configuration having a light distribution control function may be used. For example, another resin such as acrylic or polycarbonate or a metal member such as Al may be used as the base material, and Ag or Pt may be used as the reflective film. As the antioxidant film, an aluminum oxide-based film or the like may be used, and a film having a function of increasing reflection as a multilayer film of silicon oxide and titanium oxide may be used.

(Laser light cut filter 17)
The laser light cut filter 17 functions as a blocking unit that prevents the multi-core fiber 20 from guiding the laser light. In the present embodiment, the laser light cut filter 17 can cut light having a wavelength of 400 nm or less and block laser light having a wavelength of 395 nm emitted from the laser element 11. The wavelength to be cut off can be adjusted as appropriate according to the type of the laser light cut filter 17.

  The laser light cut filter 17 blocks the opening of the elliptical mirror 16. The incident end face 20 a of the multi-core fiber 20 is disposed in the vicinity of the outside of the laser light cut filter 17, and the laser light cut filter 17 is disposed on the optical path of spontaneous emission light collected by the elliptical mirror 16. become. Therefore, it is possible to prevent the laser light that has not been converted into spontaneous emission light by the light emitting unit 14 from being emitted to the outside of the elliptical mirror 16, and in particular, the laser light is not included in the light condensed on the incident end face 20a. Can be.

(Multi-core fiber 20)
The multi-core fiber is an optical fiber in which a plurality of cores are formed in a common clad, and guides spontaneously emitted light emitted from the light emitting section 14 from the incident end face (incident part) 20a to the outgoing end face (outgoing end part) 20b. . The multi-core fiber 20 guides a light beam for projection having a specific light intensity distribution incident from the incident end face 20a while maintaining the light intensity distribution, and emits the light from the output end face 20b. In order to receive the light beam for projection generated by the light source unit 10, the multi-core fiber 20 is arranged so that the incident end face 20 a (incident pupil) of the multi-core fiber 20 coincides with the second focal point (exit pupil) of the elliptical mirror 16. .

  2A and 2B are diagrams illustrating an example of the incident end face 20a of the multicore fiber 20. FIG. As shown in FIG. 2, the multi-core fiber 20 includes a plurality of cores 20 c and is included in the clad 20 d so that the cores 20 c do not contact each other. And the coating | coated part 20e has covered the exterior of the clad 20d.

  The core 20c and the clad 20d are made of a material that transmits light, and the refractive index of the core 20c is higher than that of the clad 20d. By adopting such a configuration, light incident on one end face of the core 20c is guided to the other end face of the core 20c by substantially total reflection.

  Since the light propagating through the cores 20c propagates independently of each other (without interfering), the light beam for projection incident on the incident end face 20a has an emission end face without substantially impairing its light intensity distribution. The light is guided to 20b.

  FIG. 2A shows a filling form in which seven cores 20c having the same shape are closely packed in the clad 20d. However, the arrangement of the cores 20c is limited to such a filling form. is not. For example, as shown in FIG. 2B, the core 20c having a horizontally long shape may be filled, or the number of the cores 20c may be changed.

  In addition, as for the space | interval of each core 20c, as long as the light which propagates each core can propagate independently is desirable.

  Further, the shape and arrangement of the core may be designed according to the light projection pattern. In the case of FIG. 2B, the elliptical, large circular, and small circular light projection patterns corresponding to the core shape are used. The light is projected to a position according to the arrangement of. The shape of the core is not limited to a circle, but may be a quadrangle or a triangle.

(Light Projecting Unit 30)
The light projecting unit 30 projects the projected light bundle (spontaneously emitted light) emitted from the output end face 20b of the multi-core fiber 20 to the outside as illumination light. Since the light source unit 10 and the multi-core fiber 20 are designed so that the luminance invariant is substantially satisfied, the luminance of the light generated in the light source unit 10 is also maintained in the light projecting unit 30. The light projecting unit 30 includes a lens 31.

(Lens 31)
The lens 31 is an optical member that makes the light beam for projection emitted from the emission end face 20 b of the multi-core fiber 20 substantially parallel light and projects the parallel light to the front of the headlamp 1 as illumination light. The substantially parallel light does not need to be completely parallel light, and it is sufficient that the projection angle (vertical angle at which the luminous intensity becomes half value) is 20 ° or less. The diameter of the lens 31 is 90 mm, for example.

  Further, the emission end face 20b of the multi-core fiber 20 and the focal position of the lens 31 substantially coincide.

  In the light projecting unit 30, a reflecting mirror may be used instead of the lens 31. As this reflecting mirror, for example, an elliptical mirror, a parabolic mirror, a spherical mirror, and the like can be used, and the type of the reflecting mirror is not particularly limited.

(Lighting control unit 50)
The lighting control unit 50 is a control unit that changes the light intensity distribution of incident light incident on the incident end surface 20a of the multicore fiber 20. More specifically, the lighting control unit 50 performs output control (lighting and extinguishing) for each of the plurality of laser elements 11 and controls the position or angle of the rising mirror 13 to thereby control the laser of the light emitting unit 14. The irradiation pattern of the laser beam on the light irradiation surface 14a is formed and changed.

  For example, the lighting control unit 50 changes the light intensity distribution of the incident light incident on the emission end face 20 b of the multicore fiber 20 by changing the irradiation pattern of the laser light emitting unit 14.

  The lighting control unit 50 may be a central processing unit (CPU) that executes instructions of a control program, or may be a logic circuit that executes dedicated processing.

(Mechanism to change the projection pattern)
As described above, the irradiation pattern on the laser light irradiation surface 14a of the light emitting unit 14 has a light intensity distribution corresponding to the final projection pattern. Therefore, the projection pattern can be changed by changing the irradiation pattern. Therefore, an example of a mechanism for changing the irradiation pattern will be described below.

  Laser light emitted from the plurality of laser elements 11 is irradiated onto the laser light irradiation surface 14 a of the light emitting unit 14 by the corresponding rising mirror 13. At this time, the irradiation pattern can be changed by changing the inclination of the plurality of upright mirrors 13 and the relative position with the laser element 11.

  The irradiation pattern can also be changed by switching the laser elements 11 that oscillate laser light among the plurality of laser elements 11 (or controlling the output of each laser element 11). In this configuration, the plurality of laser elements 11 may be arranged so that laser beam spots can be formed in a matrix on the laser beam irradiation surface 14a. In this configuration, since it is not always necessary to adjust the tilt of the rising mirror 13, it is not always necessary to operate the rising mirror 13.

  A lens may be provided in place of the rising mirror 13. This lens is arranged one by one with respect to one laser element 11 so as to face the light emitting point of the laser element 11, and makes the laser light traveling with spreading substantially parallel light. By changing the position of the lens (for example, the distance between the laser element 11 and the lens), the optical path of the laser light emitted from the laser element 11 can be changed, and the irradiation pattern can be changed. .

  The mechanism for changing the irradiation pattern is not limited to that described above, and the laser light irradiation pattern on the laser light irradiation surface 14a may be changed by any mechanism.

  In addition, the change of an irradiation pattern means the change of the light intensity distribution of the laser beam irradiated to the laser beam irradiation surface 14a. Therefore, although the shape of the spot of the laser beam is constant, the irradiation pattern also changes when the light intensity distribution in the spot changes.

(Lighting pattern change style)
The irradiation pattern is changed through the lighting control unit 50. A plurality of light projection patterns (predetermined light projection patterns) are determined in advance as the light projection pattern of the headlamp 1, and the lighting control unit 50 can switch the plurality of predetermined light projection patterns using the above-described mechanism. Good. The plurality of predetermined light projection patterns are, for example, a light projection pattern that satisfies a light distribution characteristic standard of a high beam (traveling headlamp), a light projection pattern that satisfies a light distribution characteristic standard of a low beam (passing headlight), and evening The light distribution pattern for nighttime, the light distribution pattern for nighttime, the light distribution pattern for rainy weather, and the light distribution pattern for non-rainy weather.

  Such switching of the predetermined light projection pattern may be performed in accordance with an instruction from the user. Or the detector which detects the change of the environment around the headlamp 1 may be provided, and the lighting control part 50 may switch a predetermined light projection pattern based on the detection result of the said detector.

  The detector is, for example, an external light sensor that detects the brightness around the headlamp 1, and an evening light distribution pattern and a night light distribution pattern are obtained according to the brightness detected by the external light sensor. You may switch. The detector may be a detector other than an optical sensor such as a temperature sensor.

  Further, an object detection device that detects an object in front of (or around) a vehicle on which the headlamp 1 is mounted may be provided, and the light projection pattern may be arbitrarily changed based on the detection result of the object detection device.

  The object detection device, for example, analyzes an image taken by an imaging device (for example, a CCD (charge-coupled device) camera) mounted on a vehicle and detects an object in a light distribution possible area in the image. To do. When an object to be detected is detected, the headlamp 1 changes the light projection pattern based on the coordinates where the object is detected.

  Detected when the object detection device detects, for example, a person, animal, or other vehicle (automobile, motorcycle, or bicycle) that has jumped out ahead of the vehicle, and the object detection device detects these detection targets. The light projection pattern may be changed so that illumination light having a higher illuminance than other regions is applied to the object.

<Effect of headlamp 1>
As described above, in the headlamp 1, the light transmitted by the multi-core fiber 20 does not include laser light. Therefore, even if the light projecting unit 30 is damaged due to an accident or the like, the laser light leaks to the outside. This can be prevented.

  Further, by using the multi-core fiber 20, the distance between the light projecting unit 30 and the light source unit 10 can be increased, and the light source unit 10 can be disposed at a position where it is unlikely to be damaged by an external impact or the like. It becomes possible.

  FIGS. 3A to 3C are diagrams illustrating an example of an arrangement position of the headlamp 1. As shown in FIGS. 3A to 3C, since the light projecting unit 30 and the light source unit 10 are connected by the multi-core fiber 20, the installation position of the light source unit 10 is high. The light source unit 10 may be disposed under the driver's seat of the vehicle 500 (FIG. 3A), near the front wheel (FIG. 3B), or the head of the vehicle 500 (near the light projecting unit 30). Good.

  From the viewpoint of preventing laser light from leaking when the vehicle 500 is damaged due to a collision or the like, it is desirable to install it at a portion far from the vehicle body surface as shown in FIGS. 3 (a) and 3 (b). From the viewpoint of heat dissipation, it is desirable to install the light source 10 at a location close to the bottom surface of the vehicle 500, as shown in FIGS. 3 (a) and 3 (c).

  Further, in the headlamp 1, the light beam for projection having a specific light intensity distribution generated by the light source unit 10 is guided to the light projecting unit 30 by the multi-core fiber 20 while maintaining the light intensity distribution, Flood light outside.

  Therefore, the headlamp 1 can be made smaller than the conventional configuration in which a plurality of light source units are provided to realize a specific light distribution pattern. Moreover, the light projection pattern can be changed by changing the laser light irradiation pattern on the laser light irradiation surface 14 a of the light emitting unit 14. In addition, although the system which can change a light projection pattern was demonstrated using the single light guide part (multi-core fiber), in the case of the system which does not need to change a light projection pattern, it replaces with a multi-core fiber. A single-core multimode fiber may be used. In that case, needless to say, a light projection pattern changing mechanism is not required. The headlamp 1 can project a high luminous flux as compared with the second embodiment described later.

(Modification 1)
In the above-described embodiment, the configuration in which the lens 31 is used as the light projecting unit in the light projecting unit 30 has been described. However, a reflecting mirror (reflector) may be used as the light projecting unit.

  FIG. 4 is a diagram for explaining a headlamp 1 </ b> A that is a modification of the headlamp 1. As illustrated in FIG. 4, the headlamp 1 </ b> A includes a light projecting unit 30 </ b> A instead of the light projecting unit 30, unlike the headlamp 1 illustrated in FIG. 1.

  In the headlamp 1, the lens 31 is not necessarily used. As shown in FIG. 4, the headlamp 1 </ b> A includes an off-axis parabolic mirror 31 </ b> A in the light projecting unit 30 </ b> A instead of the lens 31 provided in the light projecting unit 30 of the headlamp 1.

(Off-axis parabolic mirror 31A)
The off-axis parabolic mirror 31A is an optical member that makes the light beam for projection emitted from the emission end face 20b of the multi-core fiber 20 substantially parallel light and projects the parallel light to the front of the headlamp 1A as illumination light. .

  Further, the emission end face 20b of the multi-core fiber 20 and the focal position of the off-axis parabolic mirror 31A substantially coincide with each other. The opening of the off-axis parabolic mirror 31 </ b> A is preferably the same as or wider than the numerical aperture (NA) of the emission end face 20 b of the multicore fiber 20.

  Moreover, although the example which uses an off-axis parabolic mirror as a reflecting mirror was demonstrated, an elliptical mirror, a parabolic mirror, a spherical mirror, etc. can also be used and the kind of reflecting mirror is not specifically limited.

(Modification 2)
Still another modification of the present invention will be described with reference to FIG. The headlamp 1B of this modification can be classified as a headlamp in which the light source section includes a light emitting section (phosphor) and the laser beam irradiation form is a scan type.

<Configuration of headlamp 1B>
FIG. 5 is a diagram showing the configuration of the headlamp 1B. Here, as compared with the headlamp 1 shown in FIG. 1, the headlamp 1 </ b> B includes a light source unit 310 instead of the light source unit 10 as shown in FIG. 5.

(Light source unit 310)
The light source unit 310 includes a light guide control unit 311, a MEMS (Micro Electro Mechanical System) mirror 312, and a MEMS mirror support unit 313 instead of the rising mirror 13 of the light source unit 10. Below, the structure of the light source part 310 is demonstrated by comparing with the light source part 10. FIG.

  First, the light source unit 10 includes a plurality of laser elements 11, and the lighting control unit 50 controls the lighting of the plurality of laser elements 11. Next, the rising mirror 13 reflects and guides the laser beams emitted from the plurality of laser elements 11 to the light emitting unit 14. Thus, the light source unit 10 forms an irradiation pattern having a light intensity distribution corresponding to the final light projection pattern on the laser light irradiation surface 14 a of the light emitting unit 14.

  On the other hand, unlike the light source unit 10, the light source unit 310 first guides the laser light emitted from the laser element 11 to the MEMS mirror 312. Next, the MEMS mirror 312 reflects the laser light guided from the light guide control unit 311 and guides it to the light emitting unit 14.

  Here, as will be described later, the MEMS mirror 312 can irradiate a laser beam to an arbitrary place on the laser beam irradiation surface 14 a of the light emitting unit 14. That is, since the laser beam irradiation form can be a scan type, the light source unit 310 does not necessarily require a plurality of laser elements 11 unlike the light source unit 10.

  That is, in the light source unit 310, the number of laser elements 11 can be reduced as compared with the light source unit 10 by adopting a scan type irradiation of the laser light to the light emitting unit 14.

(Light guide controller 311)
The light guide control unit 311 is a control unit for guiding the laser light emitted from the laser element 11 to the MEMS mirror 312. Here, the light guide controller 311 sets the energy intensity distribution of the laser light emitted from the laser element 11 to a top hat distribution. As the light guide control unit 311, for example, an optical rod, a multimode fiber, or the like can be used.

  In addition, the light guide control unit 311 may further include a lens.

(MEMS mirror 312)
The MEMS mirror 312 is a mirror that includes a micromirror that is a combination of a mechanical component and an electronic circuit to form a microcomponent. The MEMS mirror 312 reflects the laser beam emitted from the light guide control unit 311 and emits the laser beam from the light emitting unit 14. Irradiation is performed on the irradiation surface 14a.

  Here, in the MEMS mirror 312, the minute mirror is controlled by the MEMS mirror drive control unit 350. That is, the laser light emitted from the laser element 11 is controlled by the light guide control of the laser light to the MEMS mirror 312 by the light guide control unit 311 and the drive control of the micro mirror of the MEMS mirror 312 by the MEMS mirror drive control unit 350. It is possible to irradiate an arbitrary place on the laser light irradiation surface 14 a of the light emitting unit 14. Thereby, the irradiation position of the laser beam to the incident end face 20a of the multi-core fiber 20 can be changed and scanned (scanned).

  That is, since the laser beam irradiation form can be a scan type, the light source unit 310 does not necessarily need to use a plurality of laser elements 11 unlike the light source unit 10 by using the MEMS mirror 312 or the like. Moreover, the irradiation pattern of the laser beam formed on the laser beam irradiation surface 14a of the light emitting unit 14 can be easily changed by changing the position or angle of the micro mirror of the MEMS mirror 312 using software.

  The mirror surface of the micro mirror of the MEMS mirror 312 may be coated with Al coating or the like.

(Control of MEMS mirror 312)
The micro mirror of the MEMS mirror 312 is, for example, an in-plane direction in which the MEMS mirror 312 is installed, and changes an angle in the X axis direction perpendicular to the gravity direction and / or the Y direction perpendicular to the direction, The irradiation pattern of the laser beam applied to the laser beam irradiation surface 14a of the light emitting unit 14 is changed by the change in the angle. That is, the minute mirror of the MEMS mirror 312 changes the irradiation position and spot size of the laser light irradiated to the light emitting unit 14.

  The MEMS mirror 312 is preferably set such that the drive range is wider in the Y-axis direction than in the X-axis direction. This is particularly effective when the light projection range of the headlamp 1B is horizontally long. On the other hand, when the light projection range of the headlamp 1B is vertically long, the MEMS mirror 312 is set so that the drive range is wider in the X-axis direction than in the Y-axis direction. It may be changed as appropriate.

  Further, in the case where the light projection pattern is formed by continuously scanning the laser beam and synchronizing the intensity of the laser beam with the scanning speed, it is desirable to use a resonant MEMS mirror that can increase the scanning speed. .

  For example, when scanning at a vertical scanning speed of 60 Hz and synchronizing the intensity of the laser light with the scanning speed, the light emitting unit 14 is used to form a light emission pattern that is a light projection pattern of a passing lamp. It is desirable to use a resonance type.

  On the other hand, when this system is used in a usage such as changing the light projection position of a spotlight, if you continue to illuminate an object (for example, a deer that is a risk factor), it is better to illuminate the object continuously. It is desirable to use a non-resonant type MEMS mirror (if the output of the laser beam is the same), since the illuminance at the object becomes high.

(MEMS mirror support 313)
The MEMS mirror support portion 313 is a member for supporting the MEMS mirror 312. Here, the MEMS mirror support unit 313 moves the MEMS mirror 312 at a predetermined position so that the MEMS mirror 312 can reflect the laser light emitted from the laser element 11 via the light guide control unit 311 toward the light emitting unit 14. Or the angle is fixed.

(MEMS mirror drive controller 350)
The MEMS mirror drive control unit 350 is a control unit for controlling the position or angle of a micromirror included in the MEMS mirror 312. More specifically, the MEMS mirror drive control unit 350 controls the position or angle of the minute mirror of the MEMS mirror 312 to form and change the laser light irradiation pattern on the laser light irradiation surface 14a of the light emitting unit 14. .

  For example, the MEMS mirror drive control unit 350 changes the light intensity distribution of the incident light incident on the emission end face 20 b of the multicore fiber 20 by changing the irradiation pattern of the laser light emitting unit 14.

  The MEMS mirror drive control unit 350 may be a CPU that executes an instruction of a control program, or may be a logic circuit that executes a dedicated process.

<Effect of headlamp 1B>
As described above, the headlamp 300 can reduce the number of the laser elements 11 by using the light guide control unit 311 and the MEMS mirror 312 to scan the light emitting unit 14 with laser light. . Moreover, the irradiation pattern of the laser beam formed on the laser beam irradiation surface 14a of the light emitting unit 14 can be easily changed by changing the position or angle of the micro mirror of the MEMS mirror 312 using software.

  In this embodiment, a laser beam is scanned using a MEMS mirror or the like. However, the present invention is not limited to this configuration, and a solenoid actuator or the like may be used.

[Embodiment 2]
The following will describe another embodiment of the present invention with reference to FIG. In addition, about the member similar to Embodiment 1, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  FIG. 6 is a diagram illustrating a configuration of a headlamp (lighting device, vehicle headlamp) 100 according to the present embodiment. As shown in FIG. 6, the headlamp 100 includes only one pair of the laser element 11 and the rising mirror 13 in the light source unit 101, and a multimode fiber (light guide unit) 21 instead of the multicore fiber 20. I have. Spontaneous emission light generated by the light source unit 101 is incident from the incident end 21a of the multimode fiber 21, and the spontaneous emission light is emitted from the emission end 21b.

  The multimode fiber 21 is an optical fiber having a plurality of modes of light propagating in the optical fiber, and has a two-layer structure in which the core of the core is covered with a clad having a refractive index lower than that of the core. The core is mainly composed of, for example, quartz glass (silicon oxide) that has almost no absorption loss of laser light, and the cladding is composed mainly of, for example, quartz glass or a synthetic resin material having a refractive index lower than that of the core. To do.

  Spontaneously emitted light is incident from an incident end 21a, which is one end of the multimode fiber 21, and the incident spontaneously emitted light advances while being reflected inside the core of the multimode fiber 21, and at the other end. The light exits from a certain exit end 21b.

  The diameter of the lens 31 provided in the headlamp 100 is, for example, 20 mm.

  In the headlamp 100 as well, the light transmitted by the multimode fiber 21 does not include laser light. Therefore, even when the light projecting unit 30 is damaged due to an accident or the like, the laser light can be prevented from leaking to the outside.

[Embodiment 3]
The following will describe another embodiment of the present invention with reference to FIGS. In addition, about the member similar to Embodiment 1-2, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  FIG. 7 is a diagram illustrating a configuration of a headlamp (lighting device, vehicle headlamp) 200 according to the present embodiment. As shown in FIG. 7, the headlamp 200 includes a light source unit 110 and a bundle fiber (light guide unit) 22, unlike the headlamp 1.

  The light source unit 110 includes a plurality of laser elements 11, a collimating lens 111, an optical fiber 112, a heat sink 113, a heat radiation fin 114, a light emitting unit 14, a laser light cut filter 17, and a fixing member 115.

  Laser light emitted from the laser element 11 is coupled and propagated to the optical fiber 112 by the coupling lens 111 and is irradiated to the light emitting unit 14.

  Further, a heat sink 113 is connected to the laser element 11 so that heat generated by the emission of the laser light is released through the heat sink 113. Further, the heat sink 113 is connected to the heat radiating fins 114. The heat sink 113 receives the heat generated by the laser element 11 and releases it to the outside through the radiation fins 114.

  It is preferable to use a material having high thermal conductivity such as metal (for example, aluminum) for the heat sink 113 and the heat radiation fin 114.

  The laser beam guided by the optical fiber 112 is applied to the light emitting unit 14. The spontaneously emitted light generated by the light emitting unit 14 is transmitted through the laser light cut filter 17, is then incident from the incident end 22 a of the bundle fiber 22, and is emitted from the output end 22 b. The bundle fiber 22 has a configuration in which a plurality of optical fibers 22c (see FIG. 8) are bundled.

  The relative positions of the light emitting unit 14, the laser light cut filter 17, the emission end of the optical fiber 112 and the incident end 22 a of the bundle fiber 22 are fixed by a fixing member 115. The laser light cut filter 17 is in contact with the incident end 22 a of the bundle fiber 22.

  The laser light that has not been converted into spontaneous emission light by the light emitting unit 14 is blocked by the laser light cut filter 17 and therefore does not enter the bundle fiber 22.

(Positional relationship between the optical fiber 112 and the bundle fiber 22)
FIG. 8 is a cross-sectional view showing the positional relationship between the optical fiber 112 and the bundle fiber 22. As shown in FIG. 8, it is preferable that the number and position of the emission end portions of the optical fiber 112 and the number and position of the incident end portions 22a of the optical fiber (core) 22c included in the bundle fiber 22 substantially coincide with each other. However, it is not always necessary that they coincide with each other, and the spontaneous emission light emitted from the light emitting unit 14 may be incident on the incident end 22a of the bundle fiber 22 efficiently.

  FIG. 9 is a cross-sectional view showing a modification example of the light guide member applicable to the headlamp 200. As shown in FIG. 9, the headlamp 200 may use an optical fiber 23 including a core 23 c having a diameter equal to or larger than that of the bundle fiber 22 instead of the bundle fiber 22. That is, any type of fiber may be used as long as it can efficiently guide spontaneously emitted light emitted from the light emitting unit 14.

[Embodiment 4]
The following will describe another embodiment of the present invention with reference to FIG. In addition, about the member similar to Embodiment 1-3, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  FIG. 10 is a diagram illustrating a configuration of a headlamp (lighting device, vehicle headlamp) 210 according to the present embodiment. As shown in FIG. 10, a headlamp 210 is a modified example of the above-described headlamp 200, and the light source unit 110 is provided with a lens (light condensing unit) 116. The lens 116 is an optical member that condenses the light emitted from the light emitting unit 14 onto the incident end 22 a of the bundle fiber 22, and couples the light emitting unit 14 and the bundle fiber 22. The laser light cut filter 17 is disposed between the light emitting unit 14 and the lens 116.

  By using the lens 116, the spontaneous emission light emitted from the light emitting unit 14 can be efficiently incident on the bundle fiber 22.

[Embodiment 5]
The following will describe another embodiment of the present invention with reference to FIG. In addition, about the member similar to Embodiment 1-4, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  FIG. 11 is a diagram illustrating a configuration of a headlamp (lighting device, vehicle headlamp) 220 according to the present embodiment. As shown in FIG. 11, the headlamp 220 is a modification of the above-described headlamp 200, and a condensing mirror (condensing unit, reflecting mirror) that couples the light emitting unit 14 and the bundle fiber 22 to the light source unit 120. 121 is provided.

  The condensing mirror 121 is, for example, an elliptical mirror, and the light emitting unit 14 is disposed at the first focal point thereof. The light emitted from the light emitting unit 14 is reflected by the condensing mirror 121 and collected at the second focal point. The incident end 22 a of the bundle fiber 22 is disposed at the second focal point, and the incident end 22 a is in contact with the laser light cut filter 17.

  The light reflected by the condensing mirror 121 passes through the laser light cut filter 17 and enters the incident end 22a. That is, the laser light cut filter 17 is arranged on the optical path of spontaneous emission light collected by the condensing mirror 121.

  Thus, by using the condensing mirror 121, the spontaneous emission light emitted from the light emitting unit 14 can be efficiently incident on the bundle fiber 22.

[Additional Notes]
The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  INDUSTRIAL APPLICABILITY The present invention can be suitably applied to an illumination device that uses spontaneous emission light converted from laser light as illumination light, particularly a headlamp for a vehicle.

1 Headlamp (lighting device, vehicle headlamp)
1A Headlamp (lighting device, vehicle headlamp)
1B Headlamp (lighting device, vehicle headlamp)
10 Light Source 11 Laser Element (Laser Light Source)
14 Light emitting part 17 Laser light cut filter (blocking part)
20 Multi-core fiber (light guide)
20a Incident end face (incident end part)
20b Output end face (output end)
21 Multimode fiber (light guide)
21a Incident end 21b Outgoing end 22 Bundle fiber (light guide)
22a Incident end portion 22b Emission end portion 22c Optical fiber 30 Light projecting portion 31 Lens 100 Headlamp (lighting device, vehicle headlamp)
120 Light Source 121 Condenser Mirror (Condenser, Reflector)
200 Headlamp (lighting device, vehicle headlamp)
210 Headlamp (lighting device, vehicle headlamp)
220 Headlamp (lighting device, vehicle headlamp)
310 Light source

Claims (9)

A light emitting unit that emits spontaneously emitted light in response to laser light emitted from a laser light source;
A light guide unit that guides spontaneously emitted light emitted from the light emitting unit from the incident end to the exit end;
A light projecting unit that projects spontaneously emitted light emitted from the exit end to the outside as illumination light; and
An illumination device comprising: a light blocking unit that prevents the light guide unit from guiding laser light.   The illumination device according to claim 1, wherein the blocking unit is a filter that blocks the laser light, and is disposed at or near the incident end.   The illumination device according to claim 1, further comprising a condensing unit that condenses spontaneous emission light emitted from the light emitting unit at the incident end.   The lighting device according to claim 3, wherein the blocking unit is arranged on an optical path of spontaneous emission light collected by the light collecting unit.   The illumination device according to claim 4, wherein the light collecting unit is a reflecting mirror. The blocking unit is disposed between the light emitting unit and the light collecting unit,
The illuminating device according to claim 3, wherein the condensing unit condenses light transmitted through the blocking unit on the incident end.   The illuminating device according to claim 1, wherein an oscillation wavelength of the laser light source is 240 nm or more and 415 nm or less.   The lighting device according to claim 1, wherein the light guide unit is an optical fiber.   A vehicle headlamp comprising the illumination device according to claim 1.

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