JP5588217B2 - Lighting device - Google Patents

Description

  The present invention relates to a lighting device such as a desk lamp.

  Conventionally, lighting devices such as desk lamps are well known. In recent years, as this type of lighting device, there is one using a light emitting diode (hereinafter abbreviated as LED) as a light source (see, for example, Patent Document 1). Such lighting devices using LEDs tend to increase because they have the advantages of low power consumption and a small lighting device body.

JP 2008-123863 A

  Such an illuminating device is configured to irradiate the lower part of the illuminating device main body. Therefore, when using such a lighting device on a desk, it is necessary to arrange the lighting device main body directly above the work area of the user. In this way, there is a problem that the lighting device main body is in the way when it is directly above the work area. This problem is conspicuous in an illuminating device using an LED having a strong directivity of emitted light as a light source.

  In order to solve such a problem, it may be configured to irradiate downward at a predetermined angle toward the work area from a position away from the user. And in order to implement | achieve such light distribution, it is possible to use the light guide means 100 which has the reflective surface 101, as shown to Fig.18 (a). However, when such a light guide unit 100 is used, the light L reflected by the reflecting surface 101 is emitted from a narrow region of the emission unit 102, which causes a problem that the luminance becomes too high. If the brightness of the emitted light L is too high, the light L that is too strong may be reflected by the irradiation object (for example, a photograph), making it difficult to see the irradiation object. If the amount of light emitted from the light source 103 is reduced, the luminance can be reduced, but the illuminance is also reduced, so that the work area becomes dark. In order to solve these problems, as shown in FIG. 18B, it is conceivable to make the inclination angle of the reflection surface 201 of the light guide means 200 gentle. However, even if the angle of the reflecting surface 201 is made gentle in this way, the region where the light L is emitted in the emitting portion 202 cannot be expanded so much and the luminance cannot be lowered so much. Furthermore, another problem that the irradiation angle becomes too shallow occurs.

  An object of the present invention is to solve the above problems and to provide an illuminating device that can reduce luminance without reducing illuminance.

The illumination device according to claim 1 of the present invention includes a light source and light guide means for guiding light from the light source in a predetermined direction, and the light guide means guides light from the light source in a predetermined direction. In a lighting device configured to include a reflecting surface that reflects light and a light emitting portion that emits light reflected by the reflecting surface, the reflecting surface is divided along a direction from the anti-light emitting portion toward the light emitting portion. Formed by a plurality of reflective facets, and the stepped portions are formed by shifting the reflective facets in the optical axis direction of the light source so that the reflective facets on the emission part side are separated from the light source. parts by provided intermittently each of said reflective facets each other, the light guide means, of the light emitted from the light source, provided with a upper curved surface and lower curved surface to arrange the diffused light into parallel light, wherein An auxiliary reflector is provided on the upper part of the light guide means, and the lower surface of the auxiliary reflector is As a similar shape to the top surface of Kishirubeko means, in which the auxiliary reflector is configured to cover the upper curved surface and the reflection surface of the light guide means.

Furthermore, the lighting device according to claim 2 of the present invention is the lighting device according to claim 1, wherein the light guide means is made of a transparent material, and intersects the optical axis of the light source at the emission portion of the light guide means. In this direction, a plurality of convex portions or / and concave portions larger than the number of the light sources are formed side by side.

The illumination device according to claim 1 of the present invention is configured as described above, so that the light emitted from the light source is unified by the upper curved surface and the lower curved surface provided in the light guide means. After adjusting the diffused light of the part to parallel light, the light reflected by each of the reflection platelets can be allowed to pass through the emission part with an interval corresponding to the stepped part, respectively. The area | region where the light in the said emission part passes can be expanded. As described above, the area through which the light passes through the emission part is widened, and the amount of light passing through the emission part does not change, so that the luminance can be reduced without reducing the illuminance. And it can make it easy to see an irradiation target object by reducing a brightness | luminance, without reducing illuminance in this way. In addition, an auxiliary reflector is provided on the light guide means, and the auxiliary reflector is curved upwardly of the light guide means so that the lower surface of the auxiliary reflector has the same shape as the upper surface of the light guide means. By configuring so as to cover the surface and the reflection surface, even if light is emitted from a surface other than the emission surface, the light is reflected by the auxiliary reflector and returned into the light guide means. Therefore, the light returned to the light guide means can be favorably emitted from the emission surface without being finally emitted from a surface other than the emission surface.

Further, the light guide means is made of a transparent material, and a plurality of convex portions and / or concave portions that are larger than the number of the light sources in the direction intersecting the optical axis of the light sources are formed in the emission portion of the light guide means. Since the strong light exits can be dispersed in the direction intersecting the optical axis, the luminance can be further reduced without reducing the illuminance.

It is a perspective view of the illuminating device which shows 1st embodiment of this invention. FIG. FIG. It is the schematic of an optical system similarly. It is explanatory drawing of a light guide means equally. It is an enlarged view of the principal part of the light guide means. It is explanatory drawing which shows an optical path similarly. It is explanatory drawing of the light guide means of the illuminating device which shows 2nd embodiment of this invention. It is explanatory drawing which shows an optical path similarly. It is explanatory drawing of the light guide means of the illuminating device which shows 3rd embodiment of this invention. It is XX sectional drawing. It is explanatory drawing of the light guide means of the illuminating device which shows 4th embodiment of this invention. It is a YY sectional view. It is explanatory drawing of the light guide means of the illuminating device which shows 5th embodiment of this invention. FIG. It is the schematic of the optical system of the illuminating device which shows the 6th embodiment of this invention. It is explanatory drawing which shows an optical path similarly. It is explanatory drawing for the comparison with this invention.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 7. Reference numeral 1 denotes a table lamp as an example of a lighting device. The desk lamp 1 includes a base 2, a columnar part 3 fixed to the base 2, an arm part 4 provided movably with respect to the columnar part 3, and a movably provided with respect to the arm part 4. And a lamp 6 movably provided with respect to the neck 5. An operation unit 7 and a display unit 8 are provided on the front side of the columnar unit 3. The operation unit 7 includes a main switch 7A and adjustment switches 7B and 7C. The display unit 8 is provided with a plurality of display LEDs (not shown).

  The optical system of the lamp 6 will be described in detail. The lamp 6 has an illumination LED 9 as a light source. This LED 9 can be regarded as a planar light source having a small area. That is, the light L emitted from the LED 9 has a portion that becomes parallel light and a portion that becomes diffused light. Although not shown in FIGS. 4 and 7, the LEDs 9 are provided in a line on the metal substrate 10. Further, the metal substrate 10 is connected to the heat radiator 11. A light guide 12 is provided on the radiation side of the LED 9. The upper portion of the light guide 12 is covered with the auxiliary reflector 13. Furthermore, a later-described emission surface 18 of the light guide 12 is covered with a diffuser 14.

  The light guide 12 will be described in detail. The light guide 12 is formed of a transparent acrylic resin. The light guide 12 reflects the light L in a predetermined direction, the incident surface 15 facing the LED 9, the curved surface 16 that adjusts the diffused light into parallel light among the light L emitted from the LED 9, and the light L. And a light emitting surface 18 for emitting the light L reflected by the reflecting surface 17 to the outside of the light guide 12. The reflective surface 17 has a plurality of small reflective surfaces 19 that are divided vertically, that is, along the direction from the anti-emission surface 18 side to the emission surface 18 side. Further, these reflective facets 19 are provided intermittently by the stepped portion 20. The reflective small surface 19 is shifted in the direction of the optical axis A of the LED 9 by the step portion 20 so as to be farther from the LED 9 toward the emission surface 18 side. Therefore, the reflection surface 17 is formed in a stepped shape by the plurality of reflection small surfaces 19 and the step portions 20. Then, as shown in FIG. 7, each of the reflection facets 19 is formed in an inclined plane shape so as to reflect the light L arranged in parallel in a predetermined direction.

  The auxiliary reflector 13 is configured to cover the upper surface of the light guide 12, that is, the upper curved surface 16 </ b> A and the reflection surface 17 of the light guide 12. The auxiliary reflector 13 is formed of synthetic resin so that the lower surface thereof has the same shape as the upper surface of the light guide 12. A reflective layer (not shown) is formed on the lower surface of the auxiliary reflector 13 by plating or the like.

  The diffuser 14 is made of a transparent synthetic resin and has a rough surface. Accordingly, the light passing through the diffuser 14 can be scattered on a rough surface.

  Next, the operation of this embodiment will be described. The desk lamp 1 is connected in advance to an AC power source (not shown). When the user operates the main switch 7A, power is supplied to the LED 9 provided in the lamp 6, and the LED 9 is lit. Further, when the user operates the adjustment switches 7B and 7C, the power supplied to the LED 9 is adjusted in stages, and the brightness of the LED 9 changes. In addition, the light emission state of the LED 9 is displayed on the display unit 8 by the number of lighting LEDs for display. That is, when the LED 9 is emitting the strongest light, all the display LEDs are lit, and when the LED 9 is emitting the weakest light, only one display LED is lit.

  The heat generated by energizing the LED 9 moves to the heat radiator 11 through the metal substrate 10 and is released from the heat radiator 11.

  The light L emitted from the LED 9 enters the light guide 12 from the incident surface 15. And the part used as parallel light among the light L radiated | emitted from said LED9 is primarily reflected in the reflective surface 17 of the said light guide 12. As shown in FIG. In addition, the portion of the light L emitted from the LED 9 that becomes diffused light is primarily reflected on the curved surface 16 of the light guide 12 and arranged parallel to the optical axis A, and then the light guide 12. Second reflection is performed on the reflection surface 17 of the first. All of the light L reflected by the reflecting surface 17 is directed downward at a predetermined angle and is emitted from the light guide 12 at the emitting surface 18. In addition, as described above, each of the reflection facets 19 is intermittently provided by being shifted by the stepped portion 20 by the length of the stepped portion 20 in the optical axis A direction. The light L reflected at 19 is also intermittent (ie, striped) at intervals. For this reason, the passage region of the light L on the emission surface 18 is apparently widened. On the other hand, the total amount of light L passing through the emission surface 18 does not change. For this reason, the said desk lamp 1 can reduce a brightness | luminance, without reducing the illumination intensity of the light L radiated | emitted from the said LED9. Thus, by reducing the luminance without reducing the illuminance of the light L, the irradiation object in the work area irradiated by the desk lamp 1 does not cause intense reflection of the light L, and this irradiation object You can make things easier to see.

  In the light guide 12, there is a possibility that light L emitted from a surface other than the emission surface 18 may be generated after repeated reflection several times. However, even if the light L is emitted from a surface other than the emission surface 18 in this way, the light L is reflected by the auxiliary reflector 13 and returned into the light guide 12. The light L returned to the light guide 12 is finally emitted from the emission surface 18.

  Further, when the light L emitted from the emission surface 18 passes through the diffuser 14, it is scattered by minute unevenness formed on the surface of the diffuser 14. For this reason, the light L that is intermittent at intervals when passing through the emission surface 18 is also equalized by passing through the diffuser 14. Therefore, illuminance unevenness in the work area can be reduced.

  As described above, in the table lamp 1 as the illumination device of the present invention, the light guide 12 as the light guide means for guiding the light L from the LED 9 as the light source in a predetermined direction, the light L from the LED 9 is predetermined. And a light emitting surface 18 as a light emitting portion that emits the light L reflected by the light reflecting surface 17, and the light reflecting surface 17 is arranged in the vertical direction, that is, the anti-light emitting surface 18. A plurality of reflective small surfaces 19 are divided along the direction from the side toward the emission surface 18 side, and these reflection small surfaces 19 are separated from the LED 9 by the reflection small surface 19 on the emission surface 18 side. The light reflected by each of the reflection plates 19 is formed by shifting the LED 9 in the optical axis A direction to form stepped portions 20 and intermittently connecting the reflective small surfaces 19 to each other by the stepped portions 20. L are each said each Since the light passes through the emission surface 18 with an interval corresponding to the difference portion 20, the light L passage region on the emission surface 18 is apparently widened and the total amount of the light L passing through the emission surface 18 does not change. Therefore, the luminance can be lowered without lowering the illuminance of the light L, and the irradiation object in the work area can be easily seen.

  In the desk lamp 1 of the present invention, the light L emitted from the emission surface 18 passes through the light diffuser 14 as the light diffusion means, so that the intermittent light L reflected by the reflection plates 19 is obtained. Can be scattered to reduce illuminance unevenness in the work area, so that the irradiation object in the work area can be more easily seen.

  Next, a second embodiment of the present invention will be described with reference to FIGS. In addition, description is abbreviate | omitted about the part which is common in 1st embodiment mentioned above. This 2nd embodiment is a case where LED21 as a light source is regarded as a point light source.

  The light guide 22 of the present embodiment is formed of a transparent acrylic resin. The light guide 22 includes an incident surface 23 that faces the LED 21, a reflective surface 24 that directly reflects light L emitted from the LED 21 in a predetermined direction, and the reflective surface 24 reflects the light. And an emission surface 25 for emitting the light L out of the light guide 22. The reflective surface 24 has a plurality of small reflective surfaces 26 that are divided vertically, that is, along the direction from the anti-emission surface 25 side toward the emission surface 25 side. Further, these reflective facets 26 are provided intermittently by the stepped portion 27. The reflective small surface 26 is shifted in the direction of the optical axis A of the LED 21 by the stepped portion 27 so as to be farther from the LED 21 toward the emission surface 25 side. Accordingly, the reflection surface 24 is formed in a stepped shape by the plurality of reflection small surfaces 26 and the stepped portions 27. As shown in FIG. 9, each of the reflecting small surfaces 26 is a concave curved surface with respect to the LED 21 so as to reflect direct light in a predetermined direction out of the light L emitted from the LED 21. It is formed in a shape.

  The difference between the present embodiment and the first embodiment described above is that the light L diffusing from one point of the LED 21 is reflected in parallel by the reflecting surface 24 or the light L emitted from the LED 9 is parallel. This is a difference in whether the light is reflected in parallel by the reflecting surface 17 after the adjustment, and there is no great difference in other effects. Therefore, description of the operation of this embodiment is omitted.

  Next, a third embodiment of the present invention will be described with reference to FIGS. Note that description of parts common to the above-described embodiments is omitted. In this embodiment, as shown in FIG. 11, a plurality of LEDs 9 are provided, and these LEDs 9 are arranged in a line at equal intervals.

  The light guide 31 of this embodiment is formed of a transparent acrylic resin. The light guide 31 reflects the light L in a predetermined direction, an incident surface 32 facing the LED 9, a curved surface 33 that adjusts diffused light to parallel light out of the light L emitted from the LED 9. And a light emission surface 35 that emits the light L reflected by the reflection surface 34 to the outside of the light guide 31. The reflective surface 34 has a plurality of small reflective surfaces 36 that are divided vertically, that is, along the direction from the anti-emission surface 35 side to the emission surface 35 side. Further, these reflective facets 36 are provided intermittently by the stepped portion 37. The reflective small surface 36 is shifted in the direction of the optical axis A of the LED 9 by the stepped portion 37 so as to move away from the LED 9 toward the emission surface 35 side. Therefore, the reflection surface 34 is formed in a stepped shape by the plurality of reflection small surfaces 36 and stepped portions 37. Each of the reflection facets 36 is formed in an inclined planar shape so as to reflect the light L arranged in parallel in a predetermined direction.

  Note that a plurality of convex portions 38 are formed integrally with the light guide 31 on the emission surface 35 of the light guide 31. These convex portions 38 are formed long along the optical axis A of the LED 9 and are formed side by side in a direction orthogonal to the optical axis A. And the convex part 38 is formed more than the number of the said LED9.

  Next, the operation of this embodiment will be described. The light L emitted from the LED 9 enters the light guide 31 from the incident surface 32. And the part used as parallel light among the light L radiated | emitted from the said LED9 is primarily reflected in the reflective surface 34 of the said light guide 31. FIG. In addition, the portion of the light L emitted from the LED 9 that becomes diffused light is primarily reflected on the curved surface 33 of the light guide 31 and arranged parallel to the optical axis A, and then the light guide 31. The secondary reflection is performed on the reflection surface 34. The light L reflected by the reflecting surface 34 is all directed downward at a predetermined angle and is emitted from the light guide 31 at the emitting surface 35. Note that, as described above, each of the reflection facets 36 is intermittently provided by being shifted by the stepped portion 37 by the length of the stepped portion 37 in the optical axis A direction. The light L reflected at 36 is also intermittent (that is, striped) at intervals. For this reason, the passage region of the light L on the emission surface 35 is apparently widened. On the other hand, the total amount of light L passing through the emission surface 35 does not change. For this reason, the desk lamp of this embodiment can reduce a brightness | luminance, without reducing the illumination intensity of the light L radiated | emitted from the said LED9. Thus, by reducing the luminance without reducing the illuminance of the light L, the irradiation object in the work area irradiated by the desk lamp does not cause intense reflection of the light L, and this irradiation object Can be easily seen.

  As shown in FIG. 11, the light L reflected by the reflecting surface 34 is emitted after being refracted or reflected by the convex portions 38 when passing through the emitting surface 35. The light L is emitted from each of the convex portions 38. That is, the exit of the light L for one LED 9 is dispersed from one exit with high brightness to a plurality of exits with low brightness. Accordingly, the luminance can be further reduced without reducing the illuminance of the light L emitted from the LED 9, so that the irradiation object in the work area irradiated by the desk lamp can be further easily seen.

  Furthermore, the light L emitted from the emission surface 35 passes through the diffuser and is scattered by minute unevenness formed on the surface of the diffuser. For this reason, the light L that is intermittent and spaced in the direction of the optical axis A when passing through the emission surface 35 and that is speckled in the direction orthogonal to the optical axis A also passes through the light diffuser. It becomes. Therefore, illuminance unevenness in the work area can be reduced.

  As described above, in the table lamp as the lighting device of the present invention, the light guide 31 as the light guiding means for guiding the light L from the LED 9 as the light source in a predetermined direction causes the light L from the LED 9 to be in the predetermined direction. A reflection surface 34 that reflects in the direction, and an emission surface 35 as an emission part that emits the light L reflected by the reflection surface 34, and the reflection surface 34 is arranged vertically, that is, on the side opposite to the emission surface 35. Formed by a plurality of reflective facets 36 that are divided along the direction from the emitting face 35 toward the emitting face 35, and these reflecting facets 36 are separated from the LED 9 as far as the reflecting face 36 on the emitting face 35 side. The stepped portions 37 are formed by shifting in the direction of the optical axis A of the LED 9, and the respective reflective small surfaces 36 are made intermittent by these stepped portions 37. Each of the above steps Since the light passes through the emission surface 35 with an interval corresponding to the portion 37, the light L passage region on the emission surface 35 is apparently expanded and the total amount of light L passing through the emission surface 35 does not change. The luminance can be lowered without lowering the illuminance of the light L, and the irradiation object in the work area can be easily seen.

  In the desk lamp of the present invention, the light guide 31 is made of a transparent acrylic resin, and the emission surface 35 of the light guide 31 is arranged on the emission surface 35 of the LED 9 in a direction perpendicular to the optical axis A of the LED 9. By forming a plurality of protrusions 38 that are larger than the number of the protrusions 38 in a row, it is possible to disperse strong light exits in the direction orthogonal to the optical axis A, thereby further reducing the luminance without reducing the illuminance of the light L. The irradiation object in the work area can be further easily seen.

  Further, in the desk lamp of the present invention, the light L emitted from the emission surface 35 passes through a diffuser as a diffuser, and thereby scatters the intermittent light L reflected by the respective reflection plates 36. In addition, by dispersing the exit of the strong light in the direction orthogonal to the optical axis A by the convex portions 38, the light L having the spots is scattered to reduce the illuminance spots in the work area. Therefore, the irradiation object in the work area can be more easily seen.

  Next, a fourth embodiment of the present invention will be described with reference to FIGS. Note that description of parts common to the above-described embodiments is omitted. In the present embodiment, as shown in FIG. 13, a plurality of LEDs 9 are provided, and these LEDs 9 are arranged in a line at equal intervals.

  The light guide body 41 of this embodiment is formed of a transparent acrylic resin. The light guide 41 reflects the light L in a predetermined direction, the incident surface 42 facing the LED 9, the curved surface 43 that adjusts the diffused light to parallel light out of the light L emitted from the LED 9. And a light emitting surface 45 that emits the light L reflected by the reflecting surface 44 to the outside of the light guide 41. The reflective surface 44 has a plurality of reflective small surfaces 46 that are divided in the vertical direction, that is, along the direction from the anti-emission surface 45 side to the emission surface 45 side. Also, these reflective facets 46 are provided intermittently by stepped portions 47. The reflective small surface 46 is shifted in the direction of the optical axis A of the LED 9 by the stepped portion 47 so as to be farther from the LED 9 toward the emission surface 45 side. Accordingly, the reflection surface 44 is formed in a stepped shape by the plurality of reflection small surfaces 46 and the stepped portions 47. Each of the reflection facets 46 is formed in an inclined planar shape so as to reflect the light L arranged in parallel in a predetermined direction.

  A plurality of recesses 48 are formed integrally with the light guide 41 on the emission surface 45 of the light guide 41. These concave portions 48 are formed long along the optical axis A of the LED 9 and are formed side by side in a direction orthogonal to the optical axis A. And the said recessed part 48 is formed more than the number of said LED9.

  Next, the operation of this embodiment will be described. The light L emitted from the LED 9 enters the light guide 41 from the incident surface 42. Of the light L radiated from the LED 9, a portion that becomes parallel light is primarily reflected on the reflection surface 44 of the light guide 41. In addition, the portion of the light L emitted from the LED 9 that becomes diffused light is primarily reflected on the curved surface 43 of the light guide 41 and adjusted in parallel with the optical axis A, and then the light guide 41. The secondary reflection is performed on the reflection surface 44. The light L reflected by the reflecting surface 44 is all directed downward at a predetermined angle, and is emitted from the light guide 41 at the emitting surface 45. Note that, as described above, each of the reflection facets 46 is intermittently provided by being shifted by the stepped portion 47 by the length of the stepped portion 47 in the optical axis A direction. The light L reflected by 46 is also intermittent (ie, striped) at intervals. For this reason, the passage region of the light L on the emission surface 45 is apparently wide. On the other hand, the total amount of light L passing through the emission surface 45 does not change. For this reason, the desk lamp of this embodiment can reduce a brightness | luminance, without reducing the illumination intensity of the light L radiated | emitted from the said LED9. Thus, by reducing the luminance without reducing the illuminance of the light L, the irradiation object in the work area irradiated by the desk lamp does not cause intense reflection of the light L, and this irradiation object Can be easily seen.

  The light L reflected by the reflection surface 44 is emitted after being refracted or reflected between the concave portions 48 when passing through the emission surface 45, as shown in FIG. The light L is emitted between the concave portions 48, that is, from the relatively convex portions. That is, the exit of the light L for one LED 9 is dispersed from one exit with high brightness to a plurality of exits with low brightness. Accordingly, the luminance can be further reduced without reducing the illuminance of the light L emitted from the LED 9, so that the irradiation object in the work area irradiated by the desk lamp can be further easily seen.

  Furthermore, the light L emitted from the emission surface 45 passes through the diffuser and is scattered by minute unevenness formed on the surface of the diffuser. For this reason, the light L that is intermittent and spaced in the direction of the optical axis A when passing through the emission surface 45 also passes through the light diffuser. It becomes. Therefore, illuminance unevenness in the work area can be reduced.

  As described above, in the table lamp as the illumination device of the present invention, the light guide 41 as the light guide means for guiding the light L from the LED 9 as the light source in a predetermined direction, the light L from the LED 9 is the predetermined light. A reflection surface 44 that reflects in the direction, and an emission surface 45 as an emission part that emits the light L reflected by the reflection surface 44, and the reflection surface 44 is arranged vertically, that is, on the side opposite to the emission surface 45. Is formed by a plurality of reflective facets 46 that are divided along the direction from the emission face 45 toward the emission face 45, and the reflection facets 46 are separated from the LED 9 as much as the reflection facets 46 on the emission face 45 side. The stepped portion 47 is formed by shifting in the direction of the optical axis A of the LED 9, and the reflected small surfaces 46 are intermittently formed by the stepped portion 47, so that the light L reflected by the respective reflected small plates 46. Each of the above steps Since the light passes through the emission surface 45 with an interval corresponding to the portion 47, the light L passage region on the emission surface 45 is apparently expanded and the total amount of the light L passing through the emission surface 45 does not change. The luminance can be lowered without lowering the illuminance of the light L, and the irradiation object in the work area can be easily seen.

  In the desk lamp of the present invention, the light guide 41 is made of a transparent acrylic resin, and the emission surface 45 of the light guide 41 is arranged on the emission surface 45 of the LED 9 in a direction perpendicular to the optical axis A of the LED 9. By arranging a plurality of recesses 48 that are larger than the number of the recesses 48, it is possible to disperse strong light exits in a direction orthogonal to the optical axis A, thereby reducing the luminance without reducing the illuminance of the light L, It is possible to make the irradiation object in the work area easier to see.

  Furthermore, in the desk lamp of the present invention, the light L emitted from the emission surface 45 passes through a diffuser as a diffuser, and thereby scatters the intermittent light L reflected by each of the reflection plates 46. In addition, by dispersing the exit of the strong light in the direction orthogonal to the optical axis A by the concave portions 48, the light L with spots can be scattered to reduce the illuminance spots in the work area. Therefore, it is possible to make the irradiation object in the work area easier to see.

  Next, a fifth embodiment of the present invention will be described with reference to FIGS. Note that description of parts common to the above-described embodiments is omitted. In the present embodiment, as shown in FIG. 13, a plurality of LEDs 9 are provided, and these LEDs 9 are arranged in a line at equal intervals.

  The light guide 51 of this embodiment is formed of a transparent acrylic resin. The light guide 51 reflects the light L in a predetermined direction, the incident surface 52 facing the LED 9, the curved surface 53 that adjusts the diffused light to parallel light out of the light L emitted from the LED 9, and the light L. And a light emission surface 55 that emits the light L reflected by the reflection surface 54 to the outside of the light guide 51. The reflective surface 54 has a plurality of small reflective surfaces 56 that are divided in the vertical direction, that is, along the direction from the anti-emission surface 55 side to the emission surface 55 side. These reflective facets 56 are provided intermittently by the stepped portion 57. The reflective small surface 56 is shifted in the direction of the optical axis A of the LED 9 by the stepped portion 57 so as to be farther from the LED 9 toward the emission surface 55 side. Therefore, the reflection surface 54 is formed in a stepped shape by the plurality of reflection small surfaces 56 and the stepped portions 57. Each of the reflection facets 56 is formed in an inclined plane shape so as to reflect the light L arranged in parallel in a predetermined direction.

  A plurality of convex portions 58 and concave portions 59 are formed integrally with the light guide 51 on the emission surface 55 of the light guide 51. These convex portions 58 and concave portions 59 are each formed to be long along the optical axis A of the LED 9 and are alternately arranged in a direction orthogonal to the optical axis A. And the said convex part 58 and the recessed part 59 are formed more than the number of said LED9, respectively.

  Next, the operation of this embodiment will be described. The light L emitted from the LED 9 enters the light guide 51 from the incident surface 52. Of the light L radiated from the LED 9, a portion that becomes parallel light is primarily reflected on the reflection surface 54 of the light guide 51. The portion of the light L emitted from the LED 9 that becomes diffused light is primarily reflected on the curved surface 53 of the light guide 51 and adjusted in parallel with the optical axis A, and then the light guide 51. Secondary reflection is performed at the reflection surface 54 of the first. The light L reflected by the reflecting surface 54 is all directed downward at a predetermined angle and is emitted from the light guide 51 at the emitting surface 55. In addition, as described above, each of the reflection facets 56 is intermittently provided by being shifted by the stepped portion 57 by the length of the stepped portion 57 in the optical axis A direction. The light L reflected at 56 is also intermittent (ie, striped) at intervals. For this reason, the passage region of the light L on the emission surface 55 is apparently widened. On the other hand, the total amount of light L passing through the emission surface 55 is not changed. For this reason, the desk lamp of this embodiment can reduce a brightness | luminance, without reducing the illumination intensity of the light L radiated | emitted from the said LED9. Thus, by reducing the luminance without reducing the illuminance of the light L, the irradiation object in the work area irradiated by the desk lamp does not cause intense reflection of the light L, and this irradiation object Can be easily seen.

  As shown in FIG. 15, the light L reflected by the reflecting surface 54 is emitted after being refracted or reflected by the convex portions 58 when passing through the emitting surface 55. The light L is emitted from each of the convex portions 58. That is, the exit of the light L for one LED 9 is dispersed from one exit with high brightness to a plurality of exits with low brightness. Accordingly, the luminance can be further reduced without reducing the illuminance of the light L emitted from the LED 9, so that the irradiation object in the work area irradiated by the desk lamp can be further easily seen.

  Furthermore, the light L emitted from the emission surface 55 passes through the diffuser and is scattered by the minute unevenness formed on the surface of the diffuser. For this reason, the light L that is intermittent and spaced in the direction of the optical axis A when passing through the emission surface 55 and that is speckled in the direction orthogonal to the optical axis A also passes through the light diffuser. It becomes. Therefore, illuminance unevenness in the work area can be reduced.

  As described above, in the table lamp as the lighting device of the present invention, the light guide 51 as the light guiding means that guides the light L from the LED 9 as the light source in a predetermined direction, the light L from the LED 9 is the predetermined light. A reflection surface 54 that reflects in the direction, and an emission surface 55 as an emission part that emits the light L reflected by the reflection surface 54, and the reflection surface 54 is arranged vertically, that is, on the side opposite to the emission surface 55. Formed by a plurality of reflective facets 56 that are divided along the direction from the emission face 55 to the emission face 55 side, and the reflection facets 56 are separated from the LED 9 by the distance of the reflection facet 56 on the emission face 55 side. The stepped portions 57 are formed by shifting in the direction of the optical axis A of the LED 9, and the reflective small surfaces 56 are intermittently formed by these stepped portions 57, so that the light L reflected by the respective reflective plates 56. Each of the above steps Since the light passes through the emission surface 55 with an interval corresponding to the portion 57, the passage area of the light L on the emission surface 55 is apparently expanded and the total amount of the light L passing through the emission surface 55 does not change. The luminance can be lowered without lowering the illuminance of the light L, and the irradiation object in the work area can be easily seen.

  In the desk lamp of the present invention, the light guide 51 is made of a transparent acrylic resin, and the emission surface 55 of the light guide 51 is arranged on the emission surface 55 of the LED 9 in a direction perpendicular to the optical axis A of the LED 9. Since the plurality of convex portions 58 and concave portions 59 larger than the number are alternately arranged, strong light exits can be dispersed in the direction orthogonal to the optical axis A without reducing the illuminance of the light L. The luminance can be further reduced, and the irradiation object in the work area can be further easily seen.

  Further, in the desk lamp of the present invention, the light L emitted from the emission surface 55 passes through a diffuser as a diffuser, and thereby scatters the intermittent light L reflected by each reflection plate 56. In addition, by dispersing the exit of the strong light in the direction orthogonal to the optical axis A by the convex portions 58, the spotted light L can be scattered to reduce the illuminance spots in the work area. Therefore, the irradiation object in the work area can be more easily seen.

  Next, a sixth embodiment of the present invention will be described with reference to FIGS. Note that description of parts common to the above-described embodiments is omitted.

  The lamp of the present embodiment includes an illumination LED 9 as a light source. This LED 9 can be regarded as a planar light source having a small area. That is, the light L emitted from the LED 9 has a portion that becomes parallel light and a portion that becomes diffused light. Although omitted in FIGS. 16 and 17, the LEDs 9 are provided in a line on the metal substrate 10. Further, the metal substrate 10 is connected to the heat radiator 11. A light guiding means 61 is provided on the radiation side of the LED 9. In addition, a light outlet 65 described later of the light guide unit 61 is covered with the diffuser 14.

  The light guide means 61 will be described in detail. The light guide 61 is formed by an upper reflector 62 and a lower reflector 63. These reflectors 62 and 63 are formed of a synthetic resin, and a reflective layer (not shown) is formed on these surfaces by plating or the like. The light guiding means 61 includes a light entrance 64 provided between the rear ends of the reflectors 62 and 63 and an emission provided between the tips of the reflectors 62 and 63. And a light exit 65 as a part. The upper reflector 62 includes a curved surface 66 for adjusting upwardly diffusing light out of the light L emitted from the LED 9 to parallel light, and a reflecting surface 67 for reflecting the light L in a predetermined direction. Configured. In addition, the lower reflector 63 has a curved surface 68 that adjusts light diffusing downward from the light L emitted from the LED 9 to parallel light. The reflective surface 67 has a plurality of reflective small surfaces 69 that are divided in the vertical direction, that is, along the direction from the counter-light exit 65 side to the light exit 65 side. These reflective facets 69 are provided intermittently by the stepped portion 70. The reflective facet 69 is shifted in the direction of the optical axis A of the LED 9 by the stepped portion 70 so as to be farther from the LED 9 toward the light exit 65 side. Therefore, the reflection surface 67 is formed in a stepped shape by the plurality of reflection small surfaces 69 and the stepped portions 70. As shown in FIG. 17, each of the reflection facets 69 is formed in an inclined flat surface so as to reflect the light L arranged in parallel in a predetermined direction.

  The diffuser 14 is made of a transparent synthetic resin and has a rough surface. Accordingly, the light passing through the diffuser 14 can be scattered on a rough surface.

  Next, the operation of this embodiment will be described. The light L emitted from the LED 9 enters the light guiding means 61 from the light entrance 64. Of the light L radiated from the LED 9, a portion that becomes parallel light is primarily reflected on the reflection surface 67 of the upper reflector 62 of the light guide means 61. In addition, the light diffusing upward among the light L emitted from the LED 9 is primarily reflected on the curved surface 66 of the upper reflector 62 of the light guide means 61 and adjusted parallel to the optical axis A. Secondary reflection is performed on the reflection surface 67 of the upper reflector 62 of the light guide means 61. Further, among the light L radiated from the LED 9, the light diffusing downward is primarily reflected on the curved surface 68 of the lower reflector 63 of the light guide means 61 and adjusted in parallel with the optical axis A. Secondary reflection is performed on the reflection surface 67 of the upper reflector 62 of the light guide means 61. All of the light L reflected by the reflecting surface 67 is directed downward at a predetermined angle, and is emitted from the light guiding means 61 at the light exit 65. In addition, as described above, each of the reflection facets 69 is intermittently provided by being shifted by the length of each stepped portion 70 in the optical axis A direction by the stepped portion 70. The light L reflected at 69 is also intermittent (ie, striped) at intervals. For this reason, the passage region of the light L at the light outlet 65 is apparently widened. On the other hand, the total amount of light L that passes through the light outlet 65 does not change. For this reason, the said desk lamp can reduce a brightness | luminance, without reducing the illumination intensity of the light L radiated | emitted from the said LED9. Thus, by reducing the luminance without reducing the illuminance of the light L, the irradiation object in the work area irradiated by the desk lamp does not cause intense reflection of the light L, and this irradiation object Can be easily seen.

  Furthermore, when the light L emitted from the light exit 65 passes through the light diffuser 14, it is scattered by minute unevenness formed on the surface of the light diffuser 14. For this reason, the light L that is intermittent at intervals when passing through the light outlet 65 is also equalized by passing through the diffuser 14. Therefore, illuminance unevenness in the work area can be reduced.

  As described above, in the table lamp as the lighting device of the present invention, the light guide means 61 that guides the light L from the LED 9 as the light source in a predetermined direction reflects the light L from the LED 9 in the predetermined direction. And a light exit 65 as a light emitting portion that emits the light L reflected by the reflection surface 67. The reflection surface 67 is arranged vertically, that is, from the reflection light exit 65 side to the light exit 65 side. An optical axis A of the LED 9 is formed by a plurality of reflective facets 69 divided along the direction of travel, and these reflective facets 69 are separated from the LED 9 as far as the reflective facet 69 on the light exit 65 side. The stepped portions 70 are formed by shifting in the direction, and the respective reflective facets 69 are intermittently formed by these stepped portions 70, so that the lights L reflected by the respective reflective facets 69 are respectively separated from each other. It is for the step 70 Since the light exit 65 passes through the light exit 65 with a space therebetween, the light L passing area in the light exit 65 is apparently expanded and the total amount of the light L passing through the light exit 65 does not change. The luminance can be reduced without reducing the illuminance, and the irradiation object in the work area can be easily seen.

  In the desk lamp of the present invention, the light L emitted from the light exit 65 passes through the diffuser 14 serving as a diffuser, so that the intermittent light L reflected by the reflection plates 69 is received. Since it can be scattered to reduce the illuminance unevenness in the work area, the irradiation object in the work area can be made easier to see.

  In addition, this invention is not limited to the above embodiment, A various deformation | transformation implementation is possible within the range of the summary of invention. For example, in each of the embodiments described above, the optical axis refers to the optical axis of direct light from the light source (narrowly defined optical axis), but may be an optical axis bent in a reflected or refracted manner (widely defined optical axis). . Further, the above embodiments may be combined.

1 Desk lamp (lighting device)
9,21 Light emitting diode (light source)
12, 22, 31, 41, 51 Light guide (light guide means)
13 Auxiliary reflector 14 Diffuser (scattering means)
16, 33, 43, 53, 66, 68 Curved surface 17, 24, 34, 44, 54, 67 Reflecting surface 18, 25, 35, 45, 55 Emission surface (emission part)
19, 26, 36, 46, 56, 69 Reflection facet 20, 27, 37, 47, 57, 70 Stepped portion 38, 58 Convex portion 48, 59 Concave portion 61 Light guide means 65 Light exit (emission portion)
A Optical axis L Light

Claims (2)

A light source; and a light guide unit that guides light from the light source in a predetermined direction. The light guide unit reflects the light from the light source in a predetermined direction, and the light is reflected by the reflection surface. In a lighting device configured to include a light emitting unit that emits light
The reflection surface is formed by a plurality of reflection small surfaces divided along a direction from the anti-emission portion toward the emission portion, and these reflection small surfaces are separated from the light source as the reflection small surface on the emission portion side. to form a step portion is shifted in the optical axis direction of the light source, provided intermittently each of said reflective facets each other by the step portion, the light guide means, out of the light emitted from the light source, spreading In addition to having an upper curved surface and a lower curved surface for adjusting light into parallel light, an auxiliary reflector is provided above the light guide means, and the lower surface of the auxiliary reflector has the same shape as the upper surface of the light guide means As described above, the auxiliary reflector is configured to cover the upper curved surface and the reflecting surface of the light guide means . The light guide means is made of a transparent material, and a plurality of convex portions or / and concave portions larger than the number of the light sources are provided in the emitting portion of the light guide means in a direction intersecting the optical axis of the light sources. The lighting device according to claim 1, wherein the lighting device is formed side by side.

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