CN111425820A - Wavelength conversion unit and laser lighting module - Google Patents

Abstract

The invention discloses a wavelength conversion unit and a laser lighting module, wherein the wavelength conversion unit comprises a fluorescent powder sheet and a heat-conducting substrate which are sequentially arranged, the fluorescent powder sheet comprises a first surface corresponding to the heat-conducting substrate and a second surface far away from the heat-conducting substrate, the first surface is a smooth surface, the second surface is a rough surface, and a diffuse reflection material capable of reflecting exciting light is coated on the rough surface. Establish the smooth surface with the first surface, establish the rough surface with the second surface, and scribble the diffuse reflection material who establishes the reflection exciting light on the rough surface, can go back some incident exciting light reflection, only allow some exciting light to get into phosphor powder in-sheet conversion for receiving the laser, through the area size and the thickness of control diffuse reflection material cover second surface, come the proportion of the exciting light of control reflection back, thereby can the volume of accurate control reflected exciting light mix and form white light, improve the illuminating effect.

Description

Wavelength conversion unit and laser lighting module

Technical Field

The invention relates to the technical field of illumination, in particular to a wavelength conversion unit and a laser illumination module.

Background

The laser is used for exciting the remote fluorescent powder to generate white light, a light source with ultrahigh brightness can be obtained, and the laser is widely applied to the special illumination fields of projection display, automobile headlamps and the like. In the reflection type excitation structure, laser light is incident on the fluorescence conversion material, and excited light emitted from the fluorescence conversion material and reflected excited light (unconverted excited light) are mixed to form white light.

In order to obtain ideal white light, the excitation light is reflected in a certain proportion, and the energy ratio of the excitation light to the stimulated light is usually more than 20%. However, since the absorption rate of the fluorescence conversion material for the excitation light is very high, the excited light incident on the fluorescence conversion material is substantially completely absorbed and hardly reflected back. To increase the reflected excitation light, it is common practice to add scattering particles inside the fluorescent conversion material to ensure that a certain amount of excitation light is reflected back.

The addition of scattering particles can then affect the properties of the fluorescence conversion material, for example, reducing the thermal conductivity, or reducing the conversion efficiency.

Further, the yellow light output from the fluorescent conversion material is generally distributed like a lambertian distribution in the spatial light intensity distribution, and in order to obtain spatially uniform white light, it is required that the reflected excitation light also have the same light intensity distribution, thereby increasing technical difficulty.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a wavelength conversion unit and a laser lighting module which can improve the lighting effect.

In order to solve the technical problems, the technical scheme of the invention is as follows:

the utility model provides a wavelength conversion unit, is including the phosphor powder piece and the heat conduction base plate that set gradually, the phosphor powder piece include with the first surface that the heat conduction base plate corresponds with keep away from the second surface of heat conduction base plate, the first surface is the smooth surface, and the second surface is the rough surface, scribble the diffuse reflection material of the exciting light of reflexibility on the rough surface.

Furthermore, a texture structure is arranged on the second surface.

Further, the texture structure comprises a plurality of grooves, and the depth of each groove is 30-50 um.

Further, the diffuse reflective material does not completely cover the second surface.

Further, the diffuse reflection material includes scattering particles and a bonding material bonding the scattering particles.

Further, the scattering particles are aluminum oxide, titanium oxide, zirconium oxide or barium sulfate, and the bonding material is silica gel, glue or glass matrix.

Furthermore, a reflecting film is plated on one surface of the heat-conducting substrate corresponding to the fluorescent powder sheet.

Furthermore, a reflecting film is plated on one surface of the fluorescent powder sheet corresponding to the heat conducting substrate

Furthermore, white wall glue is coated on the side surface of the fluorescent powder sheet different from the first surface and the second surface.

The invention also provides a laser lighting module which comprises a laser light source and the wavelength conversion unit, wherein the laser light source emits exciting light and projects the exciting light onto the second surface of the fluorescent powder sheet.

The wavelength conversion unit comprises a fluorescent powder sheet and a heat conduction substrate which are sequentially arranged, wherein the fluorescent powder sheet comprises a first surface corresponding to the heat conduction substrate and a second surface far away from the heat conduction substrate, the first surface is a smooth surface, the second surface is a rough surface, and a diffuse reflection material capable of reflecting exciting light is coated on the rough surface. Establish the smooth surface with the first surface, establish the rough surface with the second surface, and scribble the diffuse reflection material who establishes the reflection exciting light on the rough surface, can go back some incident exciting light reflection, only allow some exciting light to get into phosphor powder in-sheet conversion for receiving the laser, through the area size and the thickness of control diffuse reflection material cover second surface, come the proportion of the exciting light of control reflection back, thereby can the volume of accurate control reflected exciting light mix and form white light, improve the illuminating effect.

Drawings

FIG. 1 is a schematic structural diagram of a wavelength conversion unit according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an embodiment of a laser lighting module according to the present invention.

Shown in the figure: 10. a phosphor sheet; 110. a first surface; 120. a second surface; 20. a heat conductive substrate; 30. a diffuse reflective material; 40. a trench; 50. white wall glue; 60. a laser light source.

Detailed Description

The invention is described in detail below with reference to the attached drawing figures:

as shown in fig. 1, the present invention provides a wavelength conversion unit, which includes a phosphor sheet 10 and a heat conductive substrate 20, which are sequentially disposed, wherein the phosphor sheet 10 includes a first surface 110 corresponding to the heat conductive substrate 20 and a second surface 120 far away from the heat conductive substrate 20, the first surface 110 is a smooth surface, the second surface 120 is a rough surface, and the rough surface is coated with a diffuse reflection material 30 capable of reflecting excitation light. Specifically, the phosphor sheet 10 may be a phosphor sheet or a phosphor glass sheet, wherein the phosphor sheet has a better heat resistance and can avoid being burned easily due to an excessively high temperature, the phosphor sheet 10 has two main optical surfaces, namely a first surface 110 corresponding to the heat-conducting substrate 20 and a second surface 120 far away from the heat-conducting substrate 20, wherein the first surface 110 is a smooth surface and can improve the total internal reflection rate, so that light is emitted from the second surface 120, the second surface 120 is a rough surface, which can reduce the total internal reflection rate of the excited light, so that the excited light is emitted from the second surface 120 and can improve the light extraction rate, the rough surface is coated with a diffuse reflection material 30 capable of reflecting the excited light, so that a part of the incident excited light can be reflected back, only a part of the excited light is allowed to enter the phosphor sheet 10 and is converted into the excited light, and the diffuse reflection material 30 may not completely cover the second surface 120, the proportion of the reflected excitation light is controlled by controlling the area and thickness of the diffuse reflection material 30 covering the second surface 120, so that the amount of the reflected excitation light can be accurately controlled to mix to form white light, and the illumination effect is improved. In this embodiment, the excitation light is blue light, and the phosphor in the phosphor sheet 10 is yellow phosphor, but the excitation light may also be yellow light, and the phosphor in the phosphor sheet 10 is red phosphor. The heat conducting substrate 20 is preferably a substrate with high heat conductivity and high reflectivity, and a metal substrate, such as a high-reflection metal plate, e.g., an aluminum plate, a copper plate, etc., may be used.

In order to improve the reflectivity of the laser, a reflective film (not shown in the figure) is plated on one surface of the heat conducting substrate 20 corresponding to the phosphor sheet 10, and certainly, a reflective film may be plated on the first surface 110 of the phosphor sheet 10 corresponding to the heat conducting substrate 20, where the reflective film is a metallic silver film or a dielectric film, and is most commonly a silver-plated aluminum plate, so as to reflect the light transmitted from the interior of the phosphor sheet 10 to the first surface 110 and finally exit from the second surface 120, thereby improving the light-emitting efficiency.

Preferably, the diffuse reflective material 30 does not completely cover the second surface 120. Specifically, the diffuse reflection material 30 may completely cover the second surface 120, or may not completely cover the second surface 120, and only covers a partial area. A part of the incident blue light can be reflected back by the diffuse reflection material 30, and only a part of the blue light is allowed to enter the phosphor sheet 10, and the blue light entering the phosphor sheet is converted into yellow light by the phosphor material and then emitted. The basic features of the diffuse reflective material 30 are: no or very little absorption of light, some backscattering of light, ease of coating operation and precise control of the amount. The proportion of the blue light reflected back is controlled by controlling the thickness of the diffuse reflection material 30 or the size of the area covering the phosphor sheet 10, so that the amount of the reflected blue light can be accurately controlled to mix to form white light. Preferably, the diffuse reflection material 30 includes scattering particles and a bonding material for bonding the scattering particles, the scattering particles may be white granular particles such as alumina, titania, zirconia, barium sulfate, etc., and the bonding material may be silica gel, transparent glue, glass matrix, etc.

Preferably, the texture structure is arranged on the second surface 120, the second surface 120 can be better roughened through the texture structure, and the second surface 120 is roughened, so that the total internal reflection of light on the second surface 120 can be reduced, the light extraction efficiency is improved, more received laser light is output from the roughened surface, and the light extraction rate and the illumination brightness are improved. Preferably, the texture structure includes a plurality of grooves 40, the depth of the grooves 40 is 30-50um, the groove pattern can be formed by laser etching, and the diffuse reflection material 30 is coated in the grooves 40, the second surface 120 can be roughened on the one hand by processing the grooves 40, and on the other hand, the amount of the diffuse reflection material 30 can be controlled by controlling the depth of the grooves, so that the reflected excitation light can be accurately controlled, and the illumination effect can be ensured. It should be noted that the thickness of the phosphor sheet 10 is usually less than 0.2mm, and if the grooves are deep enough, they can also penetrate the entire phosphor sheet 10 from top to bottom, and at this time, the phosphor sheet 10 becomes discontinuous small blocks, and the diffuse reflection material 30 is filled in the gaps.

Referring to fig. 1, the phosphor sheet 10 includes white wall glue 50 on the side different from the first surface 110 and the second surface 120. Specifically, the white wall glue 50 may be formed by mixing silica gel and white oxide particles, and surrounds the periphery of the phosphor sheet 10, so as to reflect the light output from the four sides of the phosphor sheet 10 back into the phosphor sheet 10, and finally exit from the second surface 120 of the phosphor sheet.

As shown in fig. 1, the present invention further provides a laser lighting module, which includes a laser light source 60 and the wavelength conversion unit, where the laser light source 60 emits an excitation light and projects the excitation light onto the second surface 120 of the phosphor sheet 10, the laser light source 60 may be a blue laser diode to emit a blue excitation light, at this time, the phosphor in the phosphor sheet 10 is yellow phosphor, the laser light source 60 may also be a yellow laser diode to emit yellow excitation light, and at this time, the phosphor in the phosphor sheet 10 is red phosphor.

The invention provides a wavelength conversion unit, which comprises a fluorescent powder sheet 10 and a heat conduction substrate 20 which are sequentially arranged, wherein the fluorescent powder sheet 10 comprises a first surface 110 corresponding to the heat conduction substrate 20 and a second surface 120 far away from the heat conduction substrate 20, the first surface 110 is a smooth surface, the second surface 120 is a rough surface, and a diffuse reflection material 30 capable of reflecting exciting light is coated on the rough surface. The phosphor sheet 10 has two major optical surfaces, namely a first surface 110 corresponding to the heat conducting substrate 20 and a second surface 120 far away from the heat conducting substrate 20, wherein the first surface 110 is a smooth surface and can improve the total internal reflection rate to enable light to be emitted from the second surface 120, the second surface 120 is a rough surface and can reduce the total internal reflection rate of the excited light, the excited light is emitted from the second surface 120 and can improve the light emitting rate, a diffuse reflection material 30 capable of reflecting the excited light is coated on the rough surface and can reflect a part of the incident excited light back, and only a part of the excited light is allowed to enter the phosphor sheet 10 and is converted into the excited light, the diffuse reflection material 30 can not completely cover the second surface 120, the proportion of the reflected excited light is controlled by controlling the size and the thickness of the diffuse reflection material 30 covering the second surface 120, so that the amount of the reflected excited light can be accurately controlled to mix to form white light, the lighting effect is improved.

Although the embodiments of the present invention have been described in the specification, these embodiments are merely provided as a hint, and should not limit the scope of the present invention. Various omissions, substitutions, and changes may be made without departing from the spirit of the invention and are intended to be within the scope of the invention.

Claims (10)

1. The wavelength conversion unit is characterized by comprising a fluorescent powder sheet and a heat conduction substrate which are sequentially arranged, wherein the fluorescent powder sheet comprises a first surface corresponding to the heat conduction substrate and a second surface far away from the heat conduction substrate, the first surface is a smooth surface, the second surface is a rough surface, and a diffuse reflection material capable of reflecting exciting light is coated on the rough surface.

2. The wavelength conversion unit of claim 1, wherein the second surface is provided with a texture.

3. The wavelength conversion unit according to claim 2, wherein the textured structure comprises a number of grooves, the grooves having a depth of 30-50 um.

4. The wavelength conversion unit of claim 1, wherein the diffuse reflective material does not completely cover the second surface.

5. The wavelength conversion unit of claim 1, wherein the diffuse reflective material comprises scattering particles and a bonding material that bonds the scattering particles.

6. The wavelength conversion cell according to claim 5, wherein the scattering particles are aluminum oxide, titanium oxide, zirconium oxide, or barium sulfate, and the bonding material is a silica gel, glue, or glass matrix.

7. The wavelength conversion unit of claim 1, wherein a reflective film is plated on a surface of the heat-conducting substrate corresponding to the phosphor sheet.

8. The wavelength conversion unit of claim 1, wherein a reflective film is plated on a surface of the phosphor sheet corresponding to the thermally conductive substrate.

9. The wavelength conversion unit of claim 1, wherein a side of the phosphor patch opposite to the first and second surfaces is coated with white glue.

10. A laser lighting module, comprising a laser light source and the wavelength conversion unit as claimed in any one of claims 1 to 9, wherein the laser light source emits an excitation light and projects the excitation light onto the second surface of the phosphor sheet.

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