JP2007095647A - Lighting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting device capable of constructing a desired light distribution pattern without deteriorating utilization efficiency of light, with a simple structure. <P>SOLUTION: The lighting device 1 constitutes a final light distribution pattern as a whole of illumination light by combining respective irradiation regions A1-A3 by respective fly-eye lenses 16-28 of three kinds. Then, by constructing a desired light distribution pattern without using a reflector or the like in this manner, a simple structure is realized and, in particular, the dimensions in optical axial direction of the lighting device 1 can be shortened drastically. Furthermore, since energy loss due to reflection is not brought about, effective utilization of light emitted from each LED 12 is realized. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an illumination device that illuminates a preset irradiation region with a predetermined light distribution.

  Generally, a light emitting diode (LED) has an advantage of low power consumption and long life. Therefore, in recent years, with higher output of LEDs, it is expected that LEDs are applied as light sources even in lighting devices that require a large amount of light, such as in-vehicle headlights and fog lamps.

By the way, the headlight, the fog lamp, and the like have the light distribution pattern of the emitted light defined by the standard, and in order to realize the light distribution pattern according to the standard, it is common to use a reflector. For example, Patent Document 1 finally uses a plurality of combinations of an LED array in which LEDs are arranged in a row and a reflective surface that reflects light emitted from the LED array and generates a predetermined light distribution pattern. A technique for constructing a comprehensive light distribution pattern is disclosed.
JP 2004-342574 A

  However, in spite of the advantage that the LED can be handled as a point light source, the reflection of the light from the light source by the reflector as in the technique disclosed in Patent Document 1 described above is the use of light. It is not preferable from the viewpoint of efficiency. In addition, when a reflector is used, the structure is complicated, and there is a limit in realizing downsizing in the optical axis direction.

  An object of the present invention is to provide an illuminating device capable of configuring a desired light distribution pattern with a simple configuration without reducing the light use efficiency.

  The present invention includes a light source and a plurality of fly-eye lenses of at least two or more types in which a plurality of lens portions having the same shape are arranged to emit light emitted from the light source and overlap each other in a specific irradiation region. , And at least some of the irradiation regions of the fly-eye lenses are made to coincide with each other.

  According to the illumination device of the present invention, it is possible to configure a desired light distribution pattern with a simple configuration without reducing the light use efficiency.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 5 relate to a first embodiment of the present invention, FIG. 1 is an exploded perspective view of the illumination device, FIG. 2 is a plan view of the illumination device viewed from the emission side, and FIG. 3 is II of FIG. FIG. 4 is a cross-sectional view, FIG. 4 is an explanatory diagram showing the relationship between the light distribution standard of fog lamps used in the current light distribution test for automobile lamps, and the irradiation area of each fly-eye lens when this standard is used, and FIG. It is a top view which shows the modification of an illuminating device.

  1-3, the code | symbol 1 shows an illuminating device and shows a vehicle-mounted fog lamp in this embodiment. The illuminating device 1 includes, for example, a light source unit 10 using a plurality of (for example, seven) surface-mounted light emitting diodes (LEDs) 12 each having a single-projection lens fixed on the emission surface 12a, and the light source unit 10 And a lens optical system unit 20 mounted on the head.

  The light source unit 10 has an LED substrate 11. The LED substrate 11 is formed of, for example, a substantially disk-shaped substrate, holds each LED 12 by soldering or the like, and further electrically connects each held LED 12 to a power supply circuit (not shown). Here, in the present embodiment, the LEDs 12 are arranged on the LED substrate 11 at equal intervals. Specifically, each LED 12 has, for example, one LED 12 arranged at the center of the LED substrate 11 and other LEDs 12 arranged concentrically at equal intervals. Moreover, in order to improve the light emission efficiency of each LED12, the radiation fin 13 is adhering to the back surface of the LED board 11 (refer FIG. 3).

  The lens optical system unit 20 includes a lens housing 21, a collimation lens holding plate 22 that holds a plurality of (for example, seven) collimation lenses 23 on the lens housing 21, and a plurality of types (for example, three types). A fly-eye lens holding plate 25 that holds (for example, seven) fly-eye lenses (first to third fly-eye lenses 26 to 28 described later) in the lens housing 21;

  In the present embodiment, the lens housing 21 is configured by a substantially cylindrical member that is open at both ends. A step portion 21a is formed on the inner periphery of the lens housing 21, and the step portion 21a sets the inner diameter on the base side of the lens housing 21 to be larger than the inner diameter on the distal end side (see FIG. 3). Here, the inner diameter of the base side of the lens housing 21 is set to substantially match the outer diameter of the LED substrate 11.

  The collimation lens holding plate 22 is configured by a substantially disk-shaped member whose outer diameter substantially matches the inner diameter of the base side of the lens housing 21. In the collimation lens holding plate 22, lens holding holes 22 a penetrating in the optical axis direction are opened at positions facing the respective LEDs 12 on the LED substrate 11. The collimation lens holding plate 22 constitutes a collimation lens unit by fitting and holding each collimation lens 23 in each lens holding hole 22a.

  As shown in FIG. 3, the collimation lens holding plate 22 holding each collimation lens 23 is inserted into the lens housing 21 from the base side, and is positioned in the lens housing 21 by contact with the stepped portion 21a. Is done. Further, in the lens housing 21, a ring-shaped spacer 24 is disposed on the base side of the collimation lens holding plate 22, and the collimation lens is held when the lens optical system unit 20 is crowned on the light source unit 10. The plate 22 faces the LED substrate 11 with the spacer 24 interposed therebetween. Then, when the optical axis distance between each LED 12 and each collimation lens 23 is regulated to an appropriate value by the spacer 24, each collimation lens 23 converts incident light from the corresponding LED 12 into substantially parallel light. Exit.

  The fly-eye lens holding plate 25 is configured by a substantially disk-shaped member that is provided at the tip of the lens housing 21. In the fly-eye lens holding plate 25, lens holding holes 25a penetrating in the optical axis direction are opened at positions facing the collimation lenses 23 on the collimation lens holding plate 22, respectively. The fly-eye lens holding plate 25 constitutes a fly-eye lens unit by fitting and holding the first to third fly-eye lenses 26 to 28 in the lens holding holes 25a.

  More specifically, in the present embodiment, the fly eye lens holding plate 25 holds one first fly eye lens 26 by each lens holding hole 25a and two second eye lenses. The fly eye lens 27 is held, and four third fly eye lenses 28 are held.

  The first fly-eye lens 26 has, for example, the same shape provided with an incident surface projecting downward and an exit surface projecting upward on a substantially disc-shaped lens substrate 26a fitted and held in the lens holding hole 25a. Is a lens member integrally formed in a matrix. Then, the first fly-eye lens 26 irradiates a specific irradiation area A1 (see FIG. 4) with uniform illuminance by superimposing light incident on the lens portions 26b from the collimation lens 23 to each other.

  The second fly-eye lens 27 has, for example, the same shape provided with an incident surface projecting downward and an exit surface projecting upward on a substantially disc-shaped lens substrate 27a fitted and held in the lens holding hole 25a. Is a lens member in which a plurality of lens portions 27b are integrally formed in a matrix. Then, the second fly-eye lens 27 irradiates a specific irradiation area A2 (see FIG. 4) with uniform illuminance by superimposing light incident on the lens portions 27b from the collimation lens 23 to each other.

  The third fly-eye lens 28 has, for example, the same shape including an incident surface projecting downward and an exit surface projecting upward on a substantially disc-shaped lens substrate 28a fitted and held in the lens holding hole 25a. Is a lens member integrally formed in a matrix. Then, the third fly-eye lens 28 irradiates a specific irradiation area A3 (see FIG. 4) with uniform illuminance by superimposing light incident on the lens portions 28b from the collimation lens 23 to each other.

  By the way, when using the illuminating device 1 as a fog lamp, as shown in FIG. 4, it is requested | required that the maximum luminous intensity in the front position C1 of the illuminating device 1 is 10000 cd or less in the point of irradiation distance 10m. In addition, at the left and right positions of C1, the luminous intensity at the position C2 is required to be 1000 cd or more, the luminous intensity at the position C3 is 750 cd or more, and the luminous intensity at the position C4 is required to be 300 cd or more. Furthermore, in a region above horizontal, the luminous intensity at the position C5 is required to be 650 cd or less, and the luminous intensity at the position C6 is required to be 300 cd or less.

  For this reason, in this embodiment, the aspect ratio when the lens portions 26b of the first fly-eye lens 26 are viewed in plan is set to, for example, 2.2: 2.28. Then, by setting the curvature and apex distance of the entrance surface and the exit surface of each lens unit 26b to appropriate values using experiments, simulations, etc., as the irradiation region A1 of the first fly-eye lens 26, for example, As shown in FIG. 4, a rectangular region of about −6.5 ° to 6.5 ° in the width direction and about −10 ° to −1 ° in the height direction, that is, a region including the points C1 and C2 is defined. Has been.

  In addition, the aspect ratio when the lens portions 27b of the second fly-eye lens 27 are viewed in plan is set to, for example, 1.9: 4.36. Then, by setting the curvature and apex distance of the entrance surface and the exit surface of each lens unit 27b to appropriate values using experiments, simulations, and the like, as the irradiation region A2 of the second fly-eye lens 27, for example, As shown in FIG. 4, a rectangular region of about −15 ° to 15 ° in the width direction and about −10 ° to −1 ° in the height direction, that is, a region including the points C1, C2, and C3 is defined. Yes. Here, in the present embodiment, each second fly-eye lens 27 is set so that the center of the irradiation area A1 and the center of the irradiation area A2 coincide with each other by adjusting the optical axis thereof. Further, the irradiation area A2 is set so as to encompass the entire area of the irradiation area A1.

  In addition, the aspect ratio when the lens portions 28b of the third fly's eye lens 28 are viewed in plan is set to 1.5: 4.52, for example. Then, by setting the curvature and apex distance of the entrance surface and the exit surface of each lens unit 28b to appropriate values using experiments, simulations, etc., as an irradiation region A3 of the third fly-eye lens 28, for example, As shown in FIG. 4, a rectangular region of about −22 ° to 22 ° in the width direction and about −10 ° to −1 ° in the height direction, that is, a region including the points C1, C2, C3, and C4 is defined. Has been. Here, in the present embodiment, each third fly-eye lens 28 is set so that the centers of the irradiation areas A1 and A2 and the center of the irradiation area A3 coincide with each other by adjusting the optical axis thereof. Furthermore, the irradiation area A3 is set so as to encompass the entire area of the irradiation areas A1 and A2.

  With these settings, in the illumination device 1 of the present embodiment, the luminous intensity of the area where the irradiation areas A1 to A3 are superimposed is the highest, and then the luminous intensity of the area where the irradiation areas A2 and A3 are superimposed is high, and the irradiation area A3 alone A light distribution pattern in which the luminous intensity of the region is the lowest is realized. And it becomes possible to satisfy the light distribution standard requested | required of a fog lamp by adjusting the output of each LED12 to an appropriate value.

  According to such embodiment, the final light distribution pattern of the illumination light as the whole lighting apparatus 1 is comprised by combining each irradiation area | region A1-A3 by each of the three types of fly-eye lenses 26-28. Accordingly, a desired light distribution pattern can be configured with a simple configuration without reducing the light use efficiency.

  That is, the structure can be simplified by configuring a desired light distribution pattern without using a reflector or the like in combination with the irradiation areas A1 to A3 formed by the various fly-eye lenses 26 to 28. The dimension of the illuminating device 1 in the optical axis direction can be dramatically shortened. Furthermore, since energy loss due to reflection does not occur, the light emitted from each LED 12 can be used effectively.

  Here, in the above-described first embodiment, the arrangement and the like of the fly-eye lenses 26 to 28 can be arbitrarily set. For example, by forming the LED substrate 11, the collimation lens holding plate 22, and the fly-eye lens holding plate 25 in a strip shape, it is possible to configure a slender lighting device 1 as shown in FIG. 5. . That is, if the relative relationship between the irradiation areas A1 to A3 of the fly-eye lenses 26 to 28 can be appropriately maintained, the arrangement of the fly-eye lenses 26 to 28 is not limited, and the light distribution pattern is defined using a reflector or the like. Compared to a lighting device or the like, the degree of freedom in design can be dramatically improved. Furthermore, the ratio of the fly-eye lenses 26 to 28 can also be changed as appropriate according to the application, for example, instead of the third fly-eye lens 28 as shown in FIG. It is also possible to arrange many eye lenses 27.

  Next, FIGS. 6 and 7 relate to a second embodiment of the present invention, FIG. 6 is a cross-sectional view of a main part of the lighting device, and FIG. 7 is an exploded perspective view of the lighting device. In addition, this embodiment can be applied suitably especially to a small illuminating device.

  6 and 7, reference numeral 51 denotes an illuminating device. The illuminating device 51 has a light source unit 60 that uses, for example, a surface-mounted light emitting diode (LED) 62 in which a single-projection lens is fixed on an emission plane 62a as a light source. And a lens optical system unit 70 mounted on the light source unit 60.

  The light source unit 60 has an LED substrate 61. The LED substrate 61 holds the LED 62 by soldering or the like at a substantially central portion thereof, and further electrically connects the held LED 62 to a power supply circuit (not shown). Here, in order to improve the light emission efficiency of the LED 62, the radiation fin 63 is fixed to the back surface of the LED substrate 61.

  The lens optical system unit 70 includes a lens housing 71, a collimation lens 72 accommodated and held in the lens housing 71, and a fly-eye lens unit 73.

  As shown in FIG. 7, in the present embodiment, the lens housing 71 has a substantially rectangular tube shape, and an LED insertion port 80 is opened at one end in the optical axis direction. Further, at the other end of the lens casing 71 in the optical axis direction, an illumination light exit port 81 is opened at a position facing the LED insertion port 80. As shown in FIG. 6, when the lens casing 71 is crowned on the light source unit 60, the LED 62 is exposed to the inside through the LED insertion port 80, and the emission plane 62 a of the LED 62 is opposed to the emission port 81.

  The lens housing 71 has a lens insertion opening 83 opened on one side, and collimation lens holding grooves facing each other in order from the LED insertion opening 80 side on the inner surface of each side wall adjacent to the lens insertion opening 83. 85 and a fly-eye lens holding groove 86.

  The collimation lens 72 is, for example, a lens member in which a lens portion 72b is integrally formed on the exit side of a substantially rectangular planar lens substrate 72a inserted and held in the collimation lens holding groove 85. The collimation lens 72 converts the light incident from the LED 62 into substantially parallel light by the lens portion 72b and emits the light.

  In the fly-eye lens unit 73, a first fly-eye lens 75 and a second fly-eye lens 76 are integrally formed on a substantially rectangular lens substrate 73a that is inserted and held in the fly-eye lens holding groove 86. It is a lens unit. Here, in the present embodiment, the first fly-eye lens 75 is formed at a substantially central portion on the lens substrate 73 a, and the second fly-eye lens 76 is formed around the first fly-eye lens 75. Has been.

  That is, in the substantially central portion on the lens substrate 73a, a plurality of lens portions 75a having the same shape including an incident surface projecting downward and an exit surface projecting upward are arranged in a matrix. One fly-eye lens 75 is formed. On the lens substrate 73a, a plurality of lens portions 76a having the same shape and having an incident surface projecting downward and an exit surface projecting upward are arranged at positions surrounding the first fly-eye lens 75. Thus, the second fly-eye lens 76 is configured.

  Here, also in the fly eye lens unit 73 of the present embodiment, at least of the irradiation region of the first fly eye lens 75 and the irradiation region of the second fly eye lens 76, as in the first embodiment described above. Some are set to match each other. In the present embodiment, it is possible to appropriately adjust the luminous intensity and the like of each irradiation region according to the quantity ratio, the area ratio, etc. of the lens portions 75a and 76a constituting each fly-eye lens 75 and 76.

  Here, reference numeral 95 in FIG. 7 denotes a side plate. The side plate 95 is configured such that the collimation lens 72 and the fly-eye lens unit 73 are accommodated in the lens casing 71 and then adhered to the lens casing 71 by, for example, an adhesive tape. The lens insertion opening 83 is closed.

  According to such an embodiment, in addition to the effects obtained in the above-described embodiments, illumination light having a desired light distribution pattern can be realized by a single light source, and the fly lenses 75 and 76 are integrally formed. As a result, the structure can be simplified.

  Next, FIGS. 8 and 9 relate to a third embodiment of the present invention, FIG. 8 is a plan view of the main part of the illumination device as seen from the emission side, and FIG. 9 is essential along line II-II in FIG. It is sectional drawing which shows a part. In the present embodiment, the configuration of each fly-eye lens is mainly different from the first embodiment described above. In addition, about the structure similar to the above-mentioned 1st Embodiment, a same sign is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 8, in the present embodiment, the fly eye lens holding plate 25 holds a fourth fly eye lens 126 instead of the first fly eye lens 26, and the second fly eye lens 27 holds the second fly eye lens 27. Instead, a fifth fly-eye lens 127 is held, and a sixth fly-eye lens 128 is held instead of the third fly-eye lens 28.

  The fourth fly-eye lens 126 is a lens member in which lens portions 126b made of Fresnel lenses are integrally formed in a matrix on a substantially disk-shaped lens substrate 126a fitted and held in the lens holding hole 25a. . The fourth fly-eye lens 126 can be made thinner and lighter by configuring each lens portion 126b with a Fresnel lens, and is similar to the fly-eye lens 26 shown in the first embodiment described above. To achieve the optical characteristics of

  The fifth fly-eye lens 127 is a lens member in which a lens portion 127b made of a Fresnel lens is integrally formed in a matrix on a substantially disc-shaped lens substrate 127a fitted and held in the lens holding hole 25a. . The fifth fly's eye lens 127 is made thinner and lighter by configuring each lens portion 127b with a Fresnel lens, and is similar to the fly eye lens 27 described in the first embodiment. To achieve the optical characteristics of

  The sixth fly-eye lens 128 is a lens member in which lens portions 128b made of Fresnel lenses are integrally formed in a matrix on a substantially disk-shaped lens substrate 128a fitted and held in the lens holding hole 25a. . The sixth fly's eye lens 128 can be made thinner and lighter by configuring each lens portion 128b with a Fresnel lens, and is similar to the first embodiment pupil-eye fly eye lens 28 described above. Realize optical properties.

  In such an embodiment, by appropriately setting specifications such as the number of divisions and the curvature of the lens curved surface when the lens curved surfaces of the various lens portions 126b to 128b are discontinuously divided stepwise, the same optical Even when members are used, the thicknesses (vertical gap distances) of the various fly-eye lenses 126 to 128 can be matched with each other. Then, by matching the thicknesses of the various fly-eye lenses 126 to 128 in this way, the holding structure when holding the fly-eye lenses 126 to 128 in the lens holding holes 25a can be unified. Productivity etc. can be improved.

  In the present embodiment, an example in which each lens portion of all fly-eye lenses is configured by a Fresnel lens has been described, but the present invention is not limited to this, and for example, a reduction in thickness and weight can be achieved. Each lens unit may be composed of a Fresnel lens only for the type of fly eye lens that is particularly required.

  In the fly-eye lens unit 73 described in the second embodiment, the lens portions 75a and 76a can be configured with Fresnel lenses. In this case, in particular, if the various lens portions are formed to have the same thickness, the thickness of the entire fly-eye lens unit 73 becomes substantially uniform. For example, when the fly-eye lens unit 73 is injection-molded, injection molding is performed. Temperature management and the like when filling the mold with a resin material or the like is facilitated, and productivity and yield are improved.

  In each of the above-described embodiments, it goes without saying that the type and quantity of the fly-eye lens may be changed as appropriate according to the required light distribution pattern and the like.

An exploded perspective view of a lighting device according to the first embodiment of the present invention. Plan view of the illumination device as seen from the exit side II sectional view of FIG. Explanatory drawing which shows the relationship between the light distribution standard of the fog lamp used for the test of the light distribution of the current automotive lamps, and the irradiation area of each fly eye lens when this standard is used The top view which shows the modification of an illuminating device Sectional drawing of the principal part of an illuminating device in connection with the 2nd Embodiment of this invention. Exploded perspective view of lighting device The top view which looked at the principal part of the illuminating device from the radiation | emission side in connection with the 3rd Embodiment of this invention. Same as above, a cross-sectional view showing the main part along the line II-II in FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Illuminating device, 10 ... Light source unit, 11 ... LED board, 12 ... Light emitting diode (light source), 20 ... Lens optical system unit, 26 ... 1st fly eye lens, 26a ... Lens board | substrate, 26b ... Lens part, 27 2nd fly eye lens, 27a ... lens substrate, 27b ... lens portion, 28 ... 3rd fly eye lens, 28a ... lens substrate, 28b ... lens portion, A1-A3 ... 1st-3rd irradiation area, DESCRIPTION OF SYMBOLS 51 ... Illuminating device, 60 ... Light source unit, 61 ... LED board, 62 ... Light emitting diode (light source), 70 ... Lens optical system unit, 73 ... Fly eye lens unit, 73a ... Lens substrate, 75 ... 1st fly eye lens 75a ... lens part, 76 ... second fly eye lens, 76a ... lens part

Claims (4)

A light source;
A plurality of fly-eye lenses of at least two or more types in which a plurality of lens portions having the same shape are arranged to be emitted and emitted from the light source so as to be superimposed on a specific irradiation region, and
An illuminating device characterized in that at least a part of an irradiation area of each fly-eye lens is made to coincide with each other.   2. The illumination device according to claim 1, wherein each of the fly-eye lenses is integrally formed on a single lens substrate.   3. The illumination device according to claim 1, wherein each lens portion of at least one type of fly-eye lens among the fly-eye lenses is configured by a Fresnel lens.   4. The illumination device according to claim 3, wherein the thicknesses of the different types of fly-eye lenses are made to coincide with each other by setting the specifications of each lens unit composed of a Fresnel lens.

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