JP2012074273A - Light source device and lighting system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress a temperature rise of a phosphor layer due to heat generation of the phosphor and prevent a decrease in fluorescence intensity even when a phosphor dispersed in a transparent medium such as a silicone resin is used for the phosphor layer. To do.
SOLUTION: A solid-state light source 5 that emits light of a predetermined wavelength in a wavelength region from ultraviolet light to green light, and fluorescence that is excited by excitation light from the solid-state light source 5 and has a longer wavelength than the emission wavelength of the solid-state light source 5. The phosphor layer 2 is a material in which a phosphor is dispersed in a transparent medium such as silicone resin, and the blending ratio of the phosphor to the transparent medium in the phosphor layer 2 is as follows. The weight ratio is in the range of 80 wt% to 82 wt%, and the thickness of the phosphor layer 2 is in the range of 75 μm to 100 μm.
[Selection] Figure 1

Description

  The present invention relates to a light source device and an illumination device.

  Conventionally, for example, Patent Document 1 proposes a light source that excites a phosphor with a semiconductor laser and uses the fluorescence, and a projector using the light source.

JP 2010-086815 A

  By the way, even when a phosphor having an external quantum efficiency of 80% or more is excited at a low energy density, if the heat conduction of the phosphor layer is poor when the phosphor layer is continuously excited at a high density energy, the phosphor generates heat. It is known that the phosphor accumulated in the phosphor layer lowers the quantum efficiency of the phosphor, further generates heat, and due to its vicious cycle, the brightness is lowered by temperature quenching.

  Specifically, a phosphor layer in which a phosphor is dispersed in a silicone resin is generally used for the phosphor layer. Here, the thermal conductivity of the phosphor (for example, YAG crystal) is 11.7 W / m · K, whereas the thermal conductivity of a general silicone resin is 0.1 to 0.4 W / m · K. Therefore, the greater the compounding ratio of the silicone resin component having low thermal conductivity, the greater the decrease in fluorescence intensity due to the heat generated by the phosphor.

  In the present invention, even when a phosphor dispersed in a transparent medium such as a silicone resin is used for the phosphor layer, the temperature rise of the phosphor layer due to the heat generation of the phosphor is suppressed, and the fluorescence intensity is reduced. An object of the present invention is to provide a light source device and a lighting device that can be prevented.

  In order to achieve the above object, the invention described in claim 1 is excited by a solid-state light source that emits light of a predetermined wavelength in a wavelength region from ultraviolet light to green light, and excitation light from the solid-state light source. A phosphor layer that emits fluorescence having a longer wavelength than the emission wavelength of the solid-state light source, wherein the phosphor layer is a phosphor dispersed in a transparent medium, and the phosphor layer in the phosphor layer The compounding ratio with respect to the transparent medium is in the range of 80 wt% to 82 wt% in weight ratio, and the thickness of the phosphor layer is in the range of 75 μm to 100 μm.

The invention according to claim 2 is the light source device according to claim 1, wherein the phosphor layer has a thermal diffusivity of 0.26 (× 10 ⁻⁶ m ² S ⁻¹ ) or more. It is said.

  The invention described in claim 3 is an illumination device using the light source device according to claim 1 or claim 2.

  According to the first to third aspects of the present invention, the solid light source that emits light having a predetermined wavelength in the wavelength region from ultraviolet light to green light, and the solid light that is excited by the excitation light from the solid light source. A phosphor layer that emits fluorescence having a wavelength longer than the emission wavelength of the light source, and the phosphor layer is a phosphor in which a phosphor is dispersed in a transparent medium, and the phosphor transparent medium in the phosphor layer The mixing ratio with respect to the weight ratio is in the range of 80 wt% to 82 wt%, and the thickness of the phosphor layer is in the range of 75 μm to 100 μm. Therefore, the phosphor is dispersed in a transparent medium such as a silicone resin. Even when used in the phosphor layer, the temperature rise of the phosphor layer due to the heat generation of the phosphor can be suppressed, and a decrease in fluorescence intensity can be prevented.

It is a figure which shows the structural example of the light source device of this invention, and an illuminating device. It is a figure which shows a fluorescence intensity measurement system. Fluorescence intensity (mW) with respect to phosphor layer thickness (μm) and phosphor layer surface temperature (° C.) when the phosphor layer concentration is 75 wt%, 78 wt%, 80 wt%, and 82 wt%, respectively. It is a figure which shows the measurement result. It is the figure which showed the measurement result of the fluorescence intensity (mW) with respect to the thickness (micrometer) of the fluorescent substance layer in FIG. 3 in the graph. It is the figure which showed the measurement result of the surface temperature (degreeC) of the fluorescent substance layer with respect to the thickness (micrometer) of the fluorescent substance layer in FIG. It is a figure which shows the measurement result of the thermal diffusivity of the fluorescent substance layer 2 in heating temperature 150 degreeC. It is a figure which shows the other structural example of the light source device of this invention, and an illuminating device. It is a figure which shows the other structural example of the light source device of this invention, and an illuminating device. It is a figure which shows the other structural example of the light source device of this invention, and an illuminating device. It is a figure which shows the other structural example of the light source device of this invention, and an illuminating device. It is a figure which shows the other structural example of the light source device of this invention, and an illuminating device. It is a figure which shows the other structural example of the light source device of this invention, and an illuminating device.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram illustrating a configuration example of a light source device and a lighting device according to the present invention. In the configuration example of FIG. 1, the light source device includes a solid-state light source 5 that emits light of a predetermined wavelength in a wavelength region from ultraviolet light to green light, and a phosphor portion 12 on which excitation light from the solid-state light source 5 is incident. And.

  Here, a light emitting diode or a laser diode (semiconductor laser) having a light emission wavelength from ultraviolet light to green light can be used as the solid light source 5. For example, a laser diode that emits blue light of about 460 nm using a GaN-based material can be used.

  In addition, the phosphor portion 12 is excited by excitation light from the solid light source 5 and the phosphor layer 2 that emits fluorescence having a longer wavelength than the emission wavelength of the solid light source 5 and the excitation light of the phosphor layer 2 enter. And a substrate 6 provided on the side opposite to the side surface.

  In the configuration example of FIG. 1, the phosphor layer 2 is provided on the substrate 6 (for example, a recess of the substrate 6). Further, at least the surface of the substrate 6 on the phosphor layer 2 side is a reflecting surface that reflects the excitation light from the solid light source 5 and the fluorescence from the phosphor layer 2. That is, in the configuration example of FIG. 1, light such as fluorescence is reflected using reflection by a reflection surface provided on the opposite side of the surface of the phosphor layer 2 from the surface on which excitation light from the solid light source 5 is incident. An extraction method (hereinafter referred to as a reflection method) is employed.

Moreover, as a fluorescent substance used for the fluorescent substance layer 2, what absorbs the light of a blue light region from ultraviolet light and emits light with a longer wavelength than excitation light can be used. For example, for red, CaAlSiN ₃ : Eu ²⁺ , (Ca, Sr) AlSiN ₃ : Eu ²⁺ , Ca ₂ Si ₅ N ₈ : Eu ²⁺ , (Ca, Sr) ₂ Si ₅ N ₈ : Eu ²⁺ , KSiF ₆ : Mn ⁴⁺ , KTiF ₆ : Mn ⁴⁺ can be used, and for yellow, Y ₃ Al ₅ O ₁₂ : Ce ³⁺ , (Sr, Ba) ₂ SiO ₄ : Eu ²⁺ , Ca _x (Si, Al) ₁₂ (O , N) ₁₆ : Eu ²⁺ can be used. For green, Lu ₃ Al ₅ O ₁₂ : Ce ³⁺ , Y ₃ (Ga, Al) ₅ O ₁₂ : Ce ³⁺ , Ca ₃ Sc ₂ Si ₃ O ₁₂ : ^{_{ce 3+, CaSc 2 O 4:}} Eu 2+, (Ba, Sr) 2 SiO 4: Eu 2+, Ba 3 Si 6 O 12 N 2: Eu 2+, (Si, Al) 6 (O, N) 8: E ^{_{2+, (Y, Lu) 3}} Al 5 O 12: it can be used ^{Ce 3+} and the like. Here, Y ₃ Al ₅ O ₁₂ : Ce ³⁺ , Lu ₃ Al ₅ O ₁₂ : Ce ³⁺ , Y ₃ (Al, Ga) ₅ O ₁₂ can absorb only the light in the blue light region and emit excitation light. : Ce ³⁺ , (Y, Lu) ₃ Al ₅ O ₁₂ : Ce ^{3+ and the} like can be used.

  The phosphor layer 2 can include at least one phosphor that is excited by excitation light from the solid light source 5 and emits fluorescence having a longer wavelength than the emission wavelength of the solid light source 5. Specifically, when the solid light source 5 emits blue light, for example, the phosphor layer 2 includes at least one kind of phosphor among phosphors such as green, red, and yellow. be able to. When the solid light source 5 emits blue light, for example, when the phosphor layer 2 contains, for example, green and red phosphors (the green and red phosphors are dispersed uniformly, for example) When they are mixed), when the phosphor layer 2 is irradiated with blue light from the solid light source 5, illumination light such as white can be obtained as reflected light. In addition, when the solid light source 5 emits blue light, for example, when the phosphor layer 2 includes only a yellow phosphor, for example, the phosphor layer 2 is irradiated with blue light from the solid light source 5. When it does, illumination light, such as yellow or white, can be obtained as reflected light. In addition, when the solid light source 5 emits blue light, for example, when the phosphor layer 2 includes only a green phosphor, for example, the phosphor layer 2 is irradiated with blue light from the solid light source 5. When it does, illumination light, such as green or turquoise, can be obtained as reflected light.

  In the present invention, the phosphor layer 2 is made of a phosphor dispersed in a transparent medium such as a silicone resin. That is, as the phosphor layer 2, a material in which the above-described phosphor powder is dispersed in a resin or glass can be used, or a glass in which a light emission center is doped in glass or a ceramic phosphor can be used. However, since the cost of the material is high and the processability is low, it is industrially advantageous to use a product obtained by dispersing and applying a phosphor in a transparent resin having high heat resistance such as silicone resin. . Therefore, in the present invention, it is assumed that the phosphor layer 2 is a phosphor layer in which a phosphor is dispersed in a transparent medium such as a silicone resin.

  Further, the substrate 6 is a reflection surface for light (light emission (fluorescence) from the phosphor layer 2 excited by excitation light from the solid light source 5 and light from the solid light source 5 not absorbed by the phosphor layer 2). , The role of dissipating the heat dissipated from the phosphor layer 2 to the outside, and the role of the support substrate of the phosphor layer 2. For this reason, high light reflection characteristics, heat transfer characteristics, and workability are required. The substrate 6 can be a metal substrate, oxide ceramics such as alumina, or non-oxide ceramics such as aluminum nitride, but a metal substrate having particularly high light reflection characteristics, heat transfer characteristics, and workability is used. Is desirable.

  By the way, when the phosphor is excited with high density energy, part of the absorbed energy is converted into heat. The above-described phosphor used for the phosphor layer 2 has an external quantum efficiency of 80% or more when excited at a low energy density, generates little heat, and does not rapidly decrease in fluorescence intensity. In this case, when the heat conduction of the phosphor layer 2 is poor, the heat generation of the phosphor is accumulated to reduce the quantum efficiency of the phosphor, further causing heat generation, and the fluorescence intensity is decreased. Therefore, in order to prevent a decrease in fluorescence intensity, it is necessary to increase the thermal conductivity of the phosphor layer 2 (thermal conduction of the entire phosphor layer 2).

  When using a phosphor layer 2 in which a phosphor is dispersed in a transparent medium such as a silicone resin, the thermal conductivity of the phosphor layer 2 depends on the blending ratio of the phosphor to the transparent medium and the phosphor layer 2. Determined by thickness. That is, the thermal conductivity of the phosphor is 9 to 14 (W / m · K), whereas the thermal conductivity of the silicone resin is 0.1 to 0.4 (W / m · K), about two digits. When these are mixed and used, the fluorescence intensity greatly varies depending on the phosphor concentration (the blending ratio of the phosphor to the silicone resin) and the thickness of the phosphor layer 2.

  That is, the smaller the blending ratio of the silicone resin component having a low thermal conductivity (the greater the blending ratio of the phosphor), the higher the thermal conductivity and thermal diffusivity of the phosphor layer 2. It is considered that a decrease in fluorescence intensity can be prevented.

  The inventor of the present application uses the phosphor layer (mixing ratio of the phosphor to the silicone resin) in the light source device having the configuration shown in FIG. Further, the influence of the thickness of the phosphor layer 2 on the fluorescence intensity, the surface temperature of the phosphor layer 2, and the thermal diffusivity of the phosphor layer 2 was examined by measurement using the fluorescence intensity measurement system of FIG. .

  In the fluorescence intensity measurement system of FIG. 2, the produced phosphor layer 2 (phosphor portion 12) is fixed, and a blue semiconductor whose main wavelength is 460 nm at a position on a straight line perpendicular to the surface of the phosphor layer 2. A laser 5 is disposed, and between the phosphor layer 2 and the blue semiconductor laser 5, a lens 25 that collects excitation light from the blue semiconductor laser 5 on the surface of the phosphor layer 2, and fluorescence from the phosphor layer 2. And the intensity of the reflected light from the dichroic mirror 26 (that is, fluorescence from the phosphor layer 2) is measured by a power meter 27.

In this measurement by the inventors of the present application, Y ₃ (Al, Ga) ₅ O ₁₂ : Ce ³⁺ was used as the phosphor of the phosphor layer 2. The spot diameter of the excitation light from the blue semiconductor laser 5 on the phosphor layer 2 was φ200 μm, and the excitation energy was 768 mW. Moreover, the temperature of the surface of the fluorescent substance layer 2 at the time of fluorescent substance layer 2 light emission was measured with the infrared camera (ThermaCAM SC640 of FLIR SYSTEMS).

  FIG. 3 shows the thickness of the phosphor layer 2 when the phosphor concentration of the phosphor layer 2 (mixing ratio of the phosphor to the silicone resin) is 75 wt%, 78 wt%, 80 wt%, and 82 wt%, respectively. The measurement results of the fluorescence intensity (mW) with respect to the thickness (μm) and the surface temperature (° C.) of the phosphor layer 2 are shown. FIG. 4 is a graph showing the measurement result of the fluorescence intensity (mW) with respect to the thickness (μm) of the phosphor layer 2 in FIG. FIG. 5 is a graph showing measurement results of the surface temperature (° C.) of the phosphor layer 2 with respect to the thickness (μm) of the phosphor layer 2 in FIG.

  3, 4, and 5, when the thickness of the phosphor layer 2 becomes 100 μm or more in high-density energy excitation 768 mW, the surface temperature of the phosphor layer 2 rapidly increases and the fluorescence intensity decreases. I understand. The degree of change is more gradual when the phosphor concentration of the phosphor layer 2 is higher. Next, paying attention to the case where the thickness of the phosphor layer 2 is 100 μm or less, when the phosphor concentration of the phosphor layer 2 is high (when the phosphor concentration is 80 wt% or more), the fluorescence intensity is strong and the fluorescence There was a tendency for the body layer surface temperature to decrease. Note that it is difficult to form a phosphor layer having a phosphor concentration of 82 wt% or more. Therefore, the practical upper limit of the phosphor concentration is 82 wt%. In addition, it is difficult to manufacture the phosphor layer 2 having a thickness of 75 μm or less. Even if the phosphor layer 2 can be manufactured, the amount of the phosphor in the thickness direction is reduced because the thickness is small, and the fluorescence intensity is weak. turn into.

  From this, the phosphor concentration of the phosphor layer 2 (the blending ratio of the phosphor to the transparent medium such as silicone resin) is in the range of 80 wt% to 82 wt%, and the thickness of the phosphor layer 2 is 75 μm to The range of 100 μm is preferable, and it has been found that this is the optimum condition for the phosphor concentration and thickness of the phosphor layer 2. This optimum condition was confirmed to be the same even when the phosphor material of the phosphor layer 2 was changed.

Further, the inventor of the present application provides the thermal diffusivity (thermal conductivity) of the phosphor layer 2 due to the difference in the phosphor concentration of the phosphor layer 2 (mixing ratio of the phosphor to the silicone resin) and the thickness of the phosphor layer 2. Was measured with a periodic heating method thermal diffusivity measuring apparatus (FTC-1) manufactured by ULVAC. FIG. 6 shows the measurement result of the thermal diffusivity of the phosphor layer 2 when the heating temperature is 150 ° C. From the results of FIG. 6, the thermal diffusivity of the phosphor layer 2 depends on the phosphor concentration of the phosphor layer 2 (mixing ratio of the phosphor to the silicone resin) when the thickness of the phosphor layer 2 is 100 μm or more. Was found to be strong. Moreover, when the thermal diffusivity of the phosphor layer 2 is set to a value of 0.26 (× 10 ⁻⁶ m ² S ⁻¹ ) or more, there is no significant difference in the fluorescence intensity and the surface temperature of the phosphor layer 2. Has been found by the inventors of the present application.

From this, it is preferable that the phosphor layer 2 has a thermal diffusivity of 0.26 (× 10 ⁻⁶ m ² S ⁻¹ ) or more.

From the above, the optimum condition of the phosphor concentration of the phosphor layer 2 in the case of high-density energy excitation is such that the blending ratio of the phosphor to the silicone resin is in the range of 80 wt% to 82 wt%. The optimum condition for the thickness of the layer 2 is in the range of 75 μm to 100 μm, and the thermal diffusivity of the phosphor layer 2 at that time is preferably 0.26 (× 10 ⁻⁶ m ² S ⁻¹ ) or more.

  In the configuration example of FIG. 1, the excitation light from the solid light source 5 is directly incident on the phosphor layer 2, but reflection means (between the solid light source 5 and the phosphor layer 2, as shown in FIG. 7. For example, by providing the mirror 16 and controlling the direction (angle) of the reflecting means 16, the incident position of the excitation light from the solid light source 5 on the phosphor layer 2 can be precisely controlled.

  When the phosphor layer 2 is used in a fixed state as shown in FIGS. 1 and 7, the phosphor layer 2 is bonded onto the substrate 6 having high cooling efficiency, and the heat generated from the phosphor layer 2 is transferred to the substrate 6. By radiating heat from the back surface of the phosphor layer, it is possible to prevent a decrease in fluorescence intensity due to heat generation of the phosphor layer 2. For this reason, it is desirable to use a metal substrate with high cooling efficiency as the substrate 6. As the metal, simple substances such as Al, Cu, Ti, Si, Ag, Au, Ni, Mo, W, Fe, Pd, and alloys containing them can be used. Further, the surface of the substrate 6 may be coated for the purpose of preventing reflection and corrosion. Further, the phosphor layer 2, that is, the phosphor generates heat when the excitation light is converted into fluorescence, and the phosphor has a characteristic of temperature quenching in which the conversion efficiency from the excitation light to the fluorescence decreases as the ambient temperature rises. Yes. Therefore, in order to prevent a decrease in the conversion efficiency to fluorescence, it is necessary to more actively cool the phosphor layer 2, that is, the phosphor. For this reason, a cooling mechanism is preferably provided on the back surface of the phosphor layer 2. Specifically, as the cooling mechanism, as shown in FIGS. 8 and 9, heat radiation fins 10 may be provided on the back surface of the substrate 6, air cooling may be performed using a fan or the like, or a thermoelectric device such as a Peltier element may be used. You may cool using an element. As described above, the cooling mechanism is provided to improve the heat dissipation of the substrate 6, and the heat generation from the phosphor layer 2 is radiated from the back surface, thereby preventing the conversion efficiency of the phosphor layer 2 from being lowered. That is, high luminance can be achieved.

  1, 7, 8, and 9, the phosphor layer 2 is fixed. However, the phosphor layer 2 can be configured to be movable. For example, as shown in FIG. 10 and FIG. 11 (FIG. 10 and FIG. 11 are diagrams corresponding to FIG. 1 and FIG. 7, respectively, and the same reference numerals are given to the same portions as FIG. 1 and FIG. The description may be omitted), and the phosphor layer 2 may be configured as a reflection type fluorescent rotator 1 that is rotated around a rotation axis X (rotated by a rotational drive source such as a motor). That is, the reflection type fluorescent rotator 1 can be realized by connecting the phosphor layer 2 and the substrate 6 joined to a rotational drive source such as a motor. Further, in the reflection type fluorescent rotating body 1, the substrate 6 and the junction between the phosphor layer 2 and the substrate 6 function as a reflection surface of excitation light and fluorescence. In addition, the shape of the board | substrate 6 can consider disk shape, a square shape, etc. In addition, in order to ensure the stability of rotation, it is possible to cut out a part of the disk or to have a shape with a weight on the contrary.

  In this way, the phosphor layer 2 is rotated around the rotation axis X (rotated by a motor or the like) as the reflection-type fluorescence rotator 1, that is, the phosphor layer 2 is rotated with respect to the solid light source 5. As a result, it is possible to disperse the places where the excitation light from the solid-state light source 5 hits, and to suppress the heat generation in the light irradiation section (using this fluorescent rotating body 1 can suppress the heat generation of the phosphor in the first place). This makes it possible to further increase the brightness.

  In the examples of FIGS. 10 and 11, only one type of phosphor layer is used as the phosphor layer 2 of the reflection type fluorescent rotator 1. For example, as shown in FIG. Layers (two types of phosphor layers 2a and 2b in the example of FIG. 12) can also be used. That is, when only one type of phosphor layer is used as the phosphor layer 2 as in the examples of FIGS. 10 and 11, a long wavelength phosphor and a short wavelength phosphor are included in the one type of phosphor layer. When used in combination, the long wavelength phosphor reabsorbs the light emitted from the short wavelength phosphor, which may reduce the conversion efficiency. In contrast, when two types of phosphor layers 2a and 2b are used as in the example of FIG. 12, the phosphor layer 2a is made of a long wavelength phosphor, and the phosphor layer 2b is made of a short wavelength phosphor. By arranging the long-wavelength phosphor and the short-wavelength phosphor in separate areas, the long-wavelength phosphor is prevented from reabsorbing the light emitted from the short-wavelength phosphor, and the conversion efficiency is improved. The decrease can be suppressed.

  In each of the above-described examples, the light source device and the optical system (lens system) 20 are combined (by emitting light from the light source device through the optical system (lens system) 20 as illumination light). A lighting device can be configured.

  Moreover, in the light source device and the illuminating device of each example described above, a light reflective material is used for the substrate 6, and the surface of the phosphor layer 2 opposite to the surface on which the excitation light from the solid light source 5 is incident. Although the light source device and the illumination device of a method (reflection method) for extracting light such as fluorescence using reflection by a reflection surface provided on the light source have been described, the present invention can be applied to the surface of the phosphor layer 2 from the solid light source 5. The present invention can be similarly applied to a light source device and an illuminating device that take out light such as fluorescent light that is transmitted from a surface provided on the side opposite to the surface on which excitation light is incident (transmission method).

  The present invention can be used for an automobile lighting device, a projector, general lighting, and the like.

DESCRIPTION OF SYMBOLS 1 Fluorescent rotating body 2 Fluorescent substance layer 5 Solid light source 6 Substrate 16 Reflecting means 20 Optical system (lens system)

Claims (3)

A solid-state light source that emits light of a predetermined wavelength in a wavelength region from ultraviolet light to green light, and a phosphor that emits fluorescence having a wavelength longer than the emission wavelength of the solid-state light source when excited by excitation light from the solid-state light source The phosphor layer is obtained by dispersing the phosphor in a transparent medium, and the blending ratio of the phosphor to the transparent medium in the phosphor layer is in the range of 80 wt% to 82 wt% in weight ratio. The phosphor layer has a thickness in the range of 75 μm to 100 μm. 2. The light source device according to claim 1, wherein the phosphor layer has a thermal diffusivity of 0.26 (× 10 ⁻⁶ m ² S ⁻¹ ) or more. An illumination device using the light source device according to claim 1.

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