JP6128762B2 - Light source unit - Google Patents

Description

  The present invention relates to a light source unit using an LED (light emitting diode).

  Conventionally, light source units using LEDs (light emitting diodes) have been used in display devices such as signboards.

JP 2009-187904 A

A light source unit using an LED (light emitting diode) has a problem of low illuminance.
An object of the embodiment of the present invention is to improve the illuminance of the light source unit.

The light source unit according to the present invention is:
A box-shaped housing having a bottom surface portion that reflects light, a plurality of side surface portions that are provided opposite to each other and that reflect light, and an emission surface portion that emits light, and wherein the bottom surface portion and the emission surface portion are parallel to each other; ,
Attached to one side surface of the side surface portion and the other side surface portion provided opposite to each other, and irradiates light between the bottom surface portion and the emission surface portion in a predetermined light emitting direction. A light emitting diode (LED) module,
A slope reflector provided to be inclined from the other side surface portion of the LED module in the predetermined light emission direction to the bottom surface portion, and to reflect the light of the LED module to the emission surface portion;
The predetermined light emission direction of the LED module is parallel to the bottom surface portion and the emission surface portion,
The slope reflector reflects light to an end portion of the emission surface portion on the other side surface portion opposite to the one side surface portion to which the LED module is attached,
The surface of the bottom portion is covered with a flat bottom reflector,
An angle between the slope reflecting plate and the bottom portion is state, and are 3 times or more than 30 degrees,
When the length of the bottom surface portion in the predetermined light emitting direction is a full length X, and the length of the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the other side surface portion is a slope length S. 1/21 ≦ S / X ≦ 1/3 .

  Since the light source unit according to the present invention has the slope reflector, the illuminance of the light source unit is improved.

FIG. 3 shows a light source unit 50 according to the first embodiment. Explanatory drawing of the LED module 70 of Embodiment 1. FIG. FIG. 3 shows a configuration 1 of the first embodiment. FIG. 3 illustrates a configuration 11 and a configuration 12 according to the first embodiment. FIG. 3 illustrates each configuration of Embodiment 1; FIG. 3 illustrates each configuration of Embodiment 1; FIG. 6 shows measurement results of the light source unit 50 according to the first embodiment. FIG. 6 shows measurement results of the light source unit 50 according to the first embodiment. FIG. 6 shows measurement results of the light source unit 50 according to the first embodiment. FIG. 3 shows the principle of the first embodiment. FIG. 4 is a contour map of the illuminance of the exit surface portion of configurations 1 to 3 of the light source unit 50 according to the first embodiment. FIG. 7 is a contour map of illuminance on the exit surface portion of configurations 4 to 6 of the light source unit 50 according to the first embodiment. FIG. 10 is a contour map of the illuminance on the exit surface portion of configurations 7 to 9 of the light source unit 50 according to the first embodiment. FIG. 12 is a contour map of the illuminance of the exit surface portion of configurations 10 to 12 of the light source unit 50 of the first embodiment. FIG. 11 is a contour map of the illuminance of the exit surface portion of the configuration 13 of the light source unit 50 according to the first embodiment. FIG. 17 is a contour map of the illuminance of the exit surface portion of configurations 14 to 17 of the light source unit 50 of the first embodiment. The contour map of the illumination intensity of the output surface part of the structures 18-21 of the light source unit 50 of Embodiment 1. FIG. The contour map of the illumination intensity of the output surface part of the structures 22-23 of the light source unit 50 of Embodiment 1. FIG. The contour map of the illumination intensity of the output surface part of the structures 24-26 of the light source unit 50 of Embodiment 1. FIG. The figure which shows the measurement result of the structures 6-13 of the light source unit 50 of Embodiment 1. FIG. The figure which shows the measurement result of the structures 6-13 of the light source unit 50 of Embodiment 1. FIG. The figure which shows the measurement result of the structures 15-22 of the light source unit 50 of Embodiment 1. FIG. The figure which shows the measurement result of the structures 15-22 of the light source unit 50 of Embodiment 1. FIG. FIG. 3 is a diagram illustrating a preferred specification of the light source unit 50 according to the first embodiment. The figure which shows other embodiment.

  Embodiment 1 FIG.

FIG. 1 is a diagram illustrating a light source unit 50 according to the first embodiment.
The light source unit 50 is, for example, a signboard that emits light on one surface (upper surface in FIG. 1).
FIG. 1 shows a signboard with a star-shaped pattern in the center of the upper surface and a star-shaped pattern that shines at night.

<<< Explanation of Symbols in FIG. 1 >>>
The length of the casing 60 in the horizontal direction (the length of the bottom surface portion 51 in a predetermined light emission direction (the light emission direction of the LED module 70 indicated by a thin arrow)) is defined as a full length X.
Let Y be the depth of the casing 60 (depth of the bottom surface portion 51).
Let Z be the height of the housing 60 (height of the side surface).
The lateral direction of the housing 60 is referred to as the X direction.
The depth direction of the housing 60 is referred to as the Y direction.
The height direction of the housing 60 is referred to as the Z direction.

The length in the predetermined light emitting direction from the crossing position of the slope reflector 83 and the bottom surface portion 51 to the side surface portion 54 is defined as a slope length S. Similarly, the length in the predetermined light emitting direction from the crossing position of the slope reflector 84 and the bottom surface portion 51 to the side surface portion 52 is defined as a slope length S.
An angle formed by the slope reflector 83 and the bottom surface portion 51 is defined as an angle A.

<<< Structure of Light Source Unit 50 >>>
The bottom surface portion 51 has a box-shaped housing 60.
The housing 60 includes a bottom surface portion 51, four side surface portions, and an emission surface portion 56.
Since the exit surface portion 56 is made of a material that transmits light, the outline of the exit surface portion 56 and the star-shaped pattern are drawn with a two-dot chain line in FIG.
The casing 60 is a hexahedron (cube) in which the bottom surface 51 and the emission surface 56 are parallel.
The bottom surface portion 51 and the four side surface portions do not transmit light.
The four side parts are the side part 52, the side part 53, the side part 54, and the side part 55.
The side surface portion 52 and the side surface portion 54 are side surfaces facing each other, and two LED modules 70 are fixed in series.
The side surface portion 53 and the side surface portion 55 do not have the LED module 70.
The light source unit 50 has a left-right symmetrical structure in the lateral direction with the center C as the center.

On the surface of the bottom portion 51, there is a bottom reflector 81 that reflects light.
There are also bottom reflectors 81 that reflect light on the four side portions. The four side surfaces may not have a reflecting plate.
The emission surface portion 56 transmits light and emits light in the direction of the thick arrow (upward direction) in FIG.

  The LED module 70 is attached to the side surface portion 52 and the side surface portion 54 and irradiates light in a horizontal direction (predetermined light emission direction) indicated by a thin arrow. The optical axis (center of light flux) of the LED module 70 is parallel to the horizontal direction, and the LED module 70 irradiates light between the bottom surface portion 51 and the emission surface portion 56 toward the opposing side surface portions.

The slope reflector 83 is provided to be inclined from the side surface portion 54 to the bottom surface portion 51. The slope reflector 83 is in the light emitting direction (right direction) of the LED module 70 on the side surface 52.
The slope reflector 84 is provided to be inclined from the side surface portion 52 to the bottom surface portion 51. The slope reflector 84 is in the light emitting direction (left direction) of the LED module 70 on the side surface 54.
The slope reflector 83 and the slope reflector 84 reflect the light of the LED module 70 in the direction of the emission surface portion 56.

Although two pairs of LED modules are provided in FIG. 1 for the side part 52 and the side part 54 facing each other, at least one pair of LED modules is sufficient.
A pair of slope reflectors is provided from the side surface portion 52 and the side surface portion 54 in the light emitting direction of the LED module 70 to the bottom surface portion 51.
Each LED module 70 is attached to the center of the side surface in the vertical direction (half the height of Z).
Each slope reflecting plate is provided so as to be inclined from the lower central portion of the side surface portion to the bottom surface portion 51.

<<< Structure of LED Module 70 >>>
(A) of FIG. 2 has shown the light distribution characteristic of LED module BX03SA-W4F-765 by Mitsubishi Electric OSRAM Co., Ltd. as the LED module 70. FIG.
BX03SA-W4F-765 uses a DC12V constant voltage power supply, emits white light (6500K), and is used as an LED module for box signboard interior lighting and indirect illumination.
FIG. 2B is a configuration diagram of BX03SA-W4F-765.
In BX03SA-W4F-765, three LEDs 71 are evenly arranged on the line.

The specifications of BX03SA-W4F-765 are as follows.
Rated input voltage: DC12V
Rated power consumption: 7.5W
Total luminous flux: 381 [lm]
Dimensions (L x W x H): 300 x 35 x 17 mm
Operating temperature condition: -25 degrees Celsius to 50 degrees Celsius LED spacing: 110 mm

A broken line in FIG. 2A indicates a light distribution curve in the Z direction (A axis).
The solid line in FIG. 2B shows the light distribution curve in the Y direction (B axis).
The light distribution curve represents how much light (light intensity) is emitted in which direction.
The angle at which the brightness is halved compared to the brightness of the optical axis (center) is called the beam angle.
BX03SA-W4F-765 is an elliptical light distribution type LED module having a beam angle of about 12 degrees in the Z direction (A axis) and a beam angle of about 56 degrees in the Y direction (B axis).

<<< Description of Configuration of Light Source Unit 50 >>>
FIG. 3 shows, as a comparative example, a case where the bottom surface portion 51 is covered with a bottom reflecting plate 81 and the slope reflecting plate 83 and the slope reflecting plate 84 are not provided.
FIG. 4 shows a case where there is a bottom reflector 81, a slope reflector 83, and a slope reflector 84 as a suitable example.
An angle formed by the slope reflector 83 or the slope reflector 84 and the bottom surface portion 51 is defined as A degree. For example, in FIG. 4, the angle A is about 7 to 14 degrees.

  Hereinafter, the result of measuring the illuminance will be described for 26 different configurations in which the configuration of the reflector is changed using the sign 1 and the sign 2 using the light source units 50 having different total lengths X.

The size of the signboard 1 is as follows.
X = 1.8m
Y = 0.84m
Z = 0.2m

The size of the signboard 2 is as follows.
X = 3.0m
Y = 0.84m
Z = 0.2m

The reflectance of each part is as follows. An example of the reflector is Furukawa Electric's MCPET (registered trademark).
Reflectance of bottom reflector 81: 90%
Reflectivity of longitudinal reflector 82: 90%
Reflectivity of slope reflector 83: 90%
Reflectivity of slope reflector 84: 90%
Reflectance of the side part 52: 50%
Reflectance of the side part 53: 50%
Reflectance of side surface portion 54: 50%
Reflectivity of side surface portion 55: 50%
Reflectivity of exit surface portion 56: 70%

FIG. 5 is a configuration diagram from Configuration 1 to Configuration 23.
“Configuration 1, 14” is a case where only the bottom reflector 81 is installed.
“Configurations 2, 3, 4, and 23” are cases where slope reflectors 83 having heights of 0.065 m, 0.05 m, 0.05 m, and 0.05 m from the center are installed to the end.
“Configuration 5” is a case where the vertical reflector 82 having a height of 0.05 m is installed at the center.
“Configurations 6 and 15” are cases where longitudinal reflectors 82 having a height of 0.05 m and 0.05 m are installed at the ends, respectively.
“Configuration 7, 8, 9, 10, 11, 12, 13, 16, 17, 18, 19, 20, 21, 22” are respectively a slope reflector 83 and a slope reflector having a height of 0.05 m from the end. 84 and S [m] are installed.

FIG. 6 is a configuration diagram from the configuration 24 to the configuration 26.
“Configuration 24” is a case where the LED module 70 is disposed only on one side and the slope reflector 83 and the slope reflector 84 are installed.
“Configuration 25” is a case where the LED module 70 is arranged only on one side and only the slope reflector 83 is installed.
“Configuration 26” is a case where the LED module 70 is arranged only on one side and only the slope reflector 84 is installed.

<<< Measurement result of illuminance in each configuration of light source unit 50 >>>
7, 8, and 9 are diagrams illustrating the results of measuring the illuminance in each configuration (configuration 1 to configuration 26) of the signboard 1 and the signboard 2.
FIGS. 11-19 is a figure which shows the contour map of the illumination intensity of the output surface part from the structure 1 to the structure 26. FIG.

  FIG. 20 is a graph showing the relationship between the angle A and the average illuminance in the configurations 6 to 13, and FIG. 21 shows the relationship between the slope length / full length [S / X] and the average illuminance in the configurations 6 to 13. It is a graph to show. 22 is a graph showing the relationship between the angle A and the illuminance in the configurations 15 to 22, and FIG. 23 is the relationship between the slope length / full length [S / X] and the average illuminance in the configurations 15 to 22. It is a graph which shows.

For example, the average illuminance of configuration 6 in FIG. 20 is a point indicated by “(6)” on a plot (solid line) of average illuminance. In addition, in the standard deviation plot (dotted line), although “(6)” is not shown, the point on the standard deviation plot on the horizontal axis that is the same as the average illuminance of configuration 6 is the standard deviation of configuration 6. (The same applies to others).
(In FIGS. 20 to 21, plots of configurations 1 to 5 are omitted.)

  Here, the illuminance refers to the brightness of the light (30% light) passing through the emission surface portion 56 when the reflectance of the emission surface portion 56 is uniform over the entire surface and the reflectance is 70%. It is equal to the luminous flux per unit area on the upper surface (outer surface) of 56.

The average illuminance is an average value of illuminance on the exit surface portion 56.
The maximum illuminance is the maximum value of illuminance on the exit surface portion 56.
The minimum illuminance is the minimum value of illuminance on the exit surface portion 56.
The standard deviation is a value indicating the uniformity of the illuminance light on the exit surface portion 56.

FIG. 7 shows the measurement results of the illuminance in the configurations 1 to 13 of the signboard 1.
In the signboard 1 of FIG. 7, the configurations 2 to 13 are determined based on the configuration 1 in which only the bottom surface is provided with a reflector (only the bottom reflector 81 is installed).
Configurations 2 to 5 cannot be used because the standard deviation is larger than that of Reference Configuration 1 (x).
In the configurations 6 to 13, the average illuminance is brighter than the standard configuration 1, and the standard deviation is small and good (◯).
As shown in FIGS. 20 and 21, in the configurations 6 to 13, the average illuminance exceeds “948 lux” of the reference configuration 1 and the standard deviation is equal to or less than “137 lux” of the reference configuration 1.
In particular, the configurations 11 and 12 are excellent (（).

  Configuration 11 is a case where a slope reflector having a height of 0.05 m from the end is installed by 0.2 m, the angle A to the horizontal direction is 14 degrees, and the slope length / full length [S / X] is 1/9. . In the configuration 11, the average illuminance is as high as 1010 lux, and the standard deviation (light uniformity) is 110, which is the lowest, and is the most uniform among the configurations 1 to 13.

  Configuration 12 is a case where a slope reflector having a height of 0.05 m from the end is set to 0.4 m, the angle A to the horizontal direction is 7 degrees, and the slope length / full length [S / X] is 1 / 4.5. Thus, the average illuminance is as high as 1015 lux, and the standard deviation (uniformity of light) among the configurations 1 to 13 is the second uniform with 118 lux.

FIG. 8 shows measurement results of illuminance in the configurations 14 to 23 of the signboard 2.
In the signboard 2 in FIG. 8, the configurations 15 to 23 are determined based on the configuration 14 in which only the bottom surface is provided with a reflector (only the bottom reflector 81 is installed).
In the configurations 15 to 19, the average illuminance and the standard deviation are almost the same as the reference configuration 14 (Δ).
In configurations 20 to 21, the average illuminance is brighter than that of the reference configuration 14, and the standard deviation is the same as that of the reference configuration 14 of 108 lux.
The configurations 22 to 23 are not possible because the standard deviation is higher than the standard configuration 14 (x).

  Configuration 20 is a case where a slope reflector having a height of 0.05 m from the end is installed by 0.2 m, the angle A to the horizontal direction is 7 degrees, and the slope length / full length [S / X] is 1/15, The average illuminance is 634 lux, which is higher than that of the standard configuration 14, and the standard deviation (light uniformity) is 112 lux, which is about the same as the standard configuration 14.

  Configuration 21 is a case where a slope reflector having a height of 0.05 m from the end is set to 0.4 m, the angle A to the horizontal direction is 7 degrees, and the slope length / full length [S / X] is 1 / 7.5. Thus, the average illuminance is 641 lux, which is higher than the standard configuration 14, and the standard deviation (light uniformity) is 115 lux, which is about the same as the standard configuration 14.

FIG. 9 shows measurement results of illuminance in the configurations 24 to 26 of the signboard 1.
In the signboard 1 of FIG. 9, the configurations 25 to 26 are determined based on the configuration 24 in which the LED modules are installed only on one side and the slope reflectors 83 and 84 are provided.
The configuration 25 is good (O) because the both sides of the standard configuration 24, the average illuminance, and the standard deviation hardly change.
Configuration 26 is not possible because the average illuminance is lower than the standard configuration 24 and the standard deviation is increased (x).

Here, the relationship between the reflector and the illuminance is considered.
FIG. 10 is an explanatory diagram of the principle when the LED module 70 is installed only on the side surface portion 52 on one side.
As shown to (a), when S / X is about 1/10, light can be reflected to the output surface part 56. FIG. Thereby, the output surface part 56 becomes bright and illuminance improves. In particular, the light is reflected at the end portion of the emission surface portion 56 (the end portion on the side surface portion 54 side opposite to the side surface portion 52). And the edge part of the output surface part 56 is a dark place, when there is no slope reflecting plate 83, and the uniformity of illumination intensity increases because this part becomes bright. That is, the effect of improving the uniformity of illuminance is high.
As shown in (b), when S / X is about ½, for example, much larger than about 1/10, light is reflected on the side surface portion 54 opposite to the LED module 70. Although the illuminance is improved, the end of the exit surface portion 56 is not particularly brighter than the other portions of the exit surface portion 56, so the effect of improving the uniformity of the illuminance is low.
As shown in (c), for example, when the reflecting plate stands upright like the longitudinal reflecting plate 82 and S / X is much smaller than about 1/10, the light is reflected on the side surface portion 52 on the LED module 70 side. The And since light is not reflected by the output surface part 56, the improvement effect of illumination intensity is low.

<<< About preferred specifications >>>
Based on the above results, a suitable specification for X = 1.8 m to 3.0 m will be considered. Hereinafter, although the slope reflector 83 is described, since it is bilaterally symmetrical, the slope reflector 84 is also the same.

FIG. 20 is a graph showing the relationship between the angle A and the illuminance in the configurations 6 to 13 of the signboard 1. The horizontal axis is the angle A, the solid line corresponds to the average illuminance on the vertical axis, and the broken line corresponds to the standard deviation on the vertical axis.
FIG. 21 is a graph showing the relationship between slope length / full length [S / X] and illuminance in configurations 6 to 13 of the signboard 1. The horizontal axis is the slope length / full length [S / X], and the solid line and the broken line are the same as those in FIG.
FIG. 22 is a graph showing the relationship between the angle A and the illuminance in the configurations 15 to 22 of the signboard 2. FIG. 23 is a graph showing the relationship between slope length / full length [S / X] and illuminance in configurations 15 to 22 of the signboard 2.
FIG. 24 is a diagram showing suitable specifications for the signboard 1 and the signboard 2.

(About the angle range of 3 degrees to 30 degrees)
First, in FIG. 20, in the signboard 1, if the angle A is 3 degrees or more, the average illuminance is equal to or higher than the average illuminance (948 looks: illustrated by a solid line in FIG. 20) of the configuration 1 that is the reference of the signboard 1. The standard deviation is also improved from the standard deviation of the configuration 1, which is the reference of the signboard 1 (137 looks: shown by a broken line in FIG. 20).

And when FIG. 21 is seen, the average illuminance of the configuration 1 in which the average illuminance is the reference of the signboard 1 in the range of the slope length / full length [S / X] of ½ or less (948 looks: illustrated by a solid line in FIG. 21). As described above, the standard deviation is also improved from the standard deviation of the configuration 1 that is the reference of the signboard 1 (137 looks: shown by a broken line in FIG. 21).
In FIG. 21, as the horizontal axis advances to the right such as “1/2”, “1 / 4.5”, and “1/9”, the values are “0.5”, “0.22”, It is as small as “0.11”. That is, the range in which the slope length / full length [S / X] is ½ or less is a portion in the right direction from the position where the horizontal axis indicates ½ in FIG. This also applies to the explanation relating to the slope length / full length [S / X] in FIGS. 21 and 23 described later.

Here, the angle of 3 degrees in the signboard 1 is when the slope length of the slope reflector 83 having a height of 0.05 m is 0.9 m as shown in FIG. This angle of 3 degrees is derived by “tan ⁻¹ (0.05 / 0.9) = about 3 degrees”. In this case, slope length / full length [S / X] = 0.9 m / 1.8 m = 1/2. That is, an angle of 3 degrees corresponds to slope length / full length [S / X] = 1/2.

As shown in FIG. 20, in the signboard 1, when the angle is 30 degrees or less, the standard deviation is drastically improved as compared with a range where the angle is larger than 30 degrees, and the standard deviation is the best value at an angle of 14 degrees. . Therefore, in the signboard 1, an angle of 30 degrees or less is suitable.
Then, referring to FIG. 21, the standard deviation is drastically improved at S / X = 1/21 or less.
Here, the angle of 30 degrees in the signboard 1 is when the slope length of the slope reflector 83 having a height of 0.05 m is 0.086 m (tan ⁻¹ (0.05 / 0.086) = approximately 30 degrees). That is, in the signboard 1, the angle of 30 degrees corresponds to the slope length / full length [S / X] = 0.086 m / 1.8 m = 1/21.

  Therefore, as shown in FIG. 24, in the signboard 1, it is preferable that the angle is 3 degrees or more and 30 degrees or less, and 1/21 ≦ S / X ≦ 1/2.

On the other hand, in the signboard 2 in FIG. 22, if it is considered that a standard deviation equivalent to the standard deviation “137 looks (illustrated by a broken line in FIG. 22)” of the configuration 1 that is the reference of the signboard 1 is allowed, the angle A = 2 degrees is not possible (x), and the lower limit of the angle A is about 3 degrees.
Accordingly, it is derived from the measurement result of the signboard 2 that the angle of 3 degrees is set as the lower limit value.
23, when S / X = 1/3 or less, the standard deviation is “137 lux (shown by a broken line in FIG. 23)” or less.
The angle of 3 degrees in the signboard 2 corresponds to the slope length / full length [S / X] = about 0.95 m / 3.0 m = about 1/3. Note that the derivation of the correspondence between the angle A and the slope length / full length [S / X] is the same as described above, and thus the description thereof is omitted (the same applies to the following description).

In the signboard 2 of FIG. 22, the slope of the solid line indicating the average illuminance becomes gentle as the angle increases. The slope of the solid line is almost zero in the range “greater than 30 degrees”, but the slope of the solid line is in the section “14 degrees to 30 degrees”, and the average illuminance value is larger than the range of “greater than 30 degrees”. It is getting bigger.
That is, the angle of 30 degrees or less is suitable also for the signboard 2.
23, when the slope length / full length [S / X] is smaller than 1/35, the average illuminance value is larger in the range of 1/35 or more.
In the signboard 2, the angle of 30 degrees corresponds to the slope length / full length [S / X] = 1/35.

  Therefore, as shown in FIG. 24, in the signboard 2, it is preferable that the angle is not less than 3 degrees and not more than 30 degrees, and 1/35 ≦ S / X ≦ 1/3.

Therefore, as described above, in the signboard 1 and the signboard 2, the angle A is preferably 3 degrees or more and 30 degrees or less.
In addition, the slope length / full length is a preferable specification in which 1/21 ≦ S / X ≦ 1/3, which is a range in which the signboard 1 and the signboard 2 are in common.

(For an angle range of 7 degrees to 14 degrees)
Further, when the contour map of the illuminance of the configuration 13 (signboard 1) in FIG. 15 is seen, it can be seen that there are two portions of 1200 lux, and the illuminance is uneven. On the other hand, when the contour map of the illuminance of the configuration 12 (signboard 1) in FIG. 14 is viewed, the peak illuminance is lower than that of the configuration 13, but the location of 1100 lux is uniform over a wide area, and the illuminance is not uneven. I understand. Here, the angle A of the configuration 12 is 7 degrees, and corresponds to the slope length / full length [S / X] = 1 / 4.5 in the signboard 1.

Furthermore, when looking at FIG. 20, in the signboard 1, the average illuminance is higher in the range of angle 7 to 14 degrees than in the range of angle 14 to 30 degrees.
21, in the signboard 1, the average illuminance is higher when the slope length / full length [S / X] is in the range of 1/9 to 1 / 4.5 than the range of 1/21 to 1/9. Is expensive.
Here, the angle of 14 degrees corresponds to the slope length / full length [S / X] = 1/9 in the signboard 1.

  Therefore, as shown in FIG. 24, in the signboard 1, an angle of 7 degrees to 14 degrees and 1/9 ≦ S / X ≦ 1 / 4.5 are preferable.

On the other hand, referring to FIG. 22, also in the signboard 2, the standard deviation rapidly deteriorates at an angle smaller than 7 degrees. Therefore, it can be seen from the measurement result of the signboard 2 that the angle of 7 degrees is the boundary of the illuminance state change.
In the sign 2, the angle of 7 degrees corresponds to the slope length / full length [S / X] = 1 / 7.5.

  And when FIG. 22 is seen, in the signboard 2, the inclination of the solid line which shows average illuminance becomes gentle as the angle increases. Then, the slope of the solid line indicating the average illuminance is steeper and the value of the average illuminance is larger in the section “7 to 14 degrees” than in the section “14 to 30 degrees”. That is, the angle A = 14 degrees or less is a more preferable range. In the signboard 2, the angle of 14 degrees corresponds to the slope length / full length [S / X] = 1/15.

  Referring to FIG. 23, in the signboard 2, the average illuminance is higher in the range of 1/15 to 1 / 7.5 than the range of 1/35 to 1/15 in the slope length / full length [S / X]. . And at 1 / 7.5 or more, the standard deviation deteriorates rapidly.

  Therefore, as shown in FIG. 24, in the signboard 2, an angle of 7 degrees to 14 degrees and 1/15 ≦ S / X ≦ 1 / 7.5 are preferable.

Therefore, as described above, in the signboard 1 and the signboard 2, the angle A is more preferably 7 degrees or more and 14 degrees or less.
Further, the slope length / full length is a more preferable specification in which 1/9 ≦ S / X ≦ 1 / 7.5, which is a range in which the sign 1 and the sign 2 are in common.

(About the angle range of 10 degrees to 11 degrees)
Furthermore, if more preferable conditions are to be obtained, the angle A is desirably 10 degrees or more and 11 degrees or less in the middle between the angle 7 degrees and the angle 14 degrees in the signboard 1 and the signboard 2.

Here, in the signboard 1, an angle of 10 degrees corresponds to the slope length / full length [S / X] = 1/6, and an angle of 11 degrees corresponds to the slope length / full length [S / X] = 1/7.
On the other hand, in the signboard 2, an angle of 10 degrees corresponds to the slope length / full length [S / X] = 11/11, and an angle of 11 degrees corresponds to the slope length / full length [S / X] = 1/12.

  That is, the slope length / full length is a more desirable specification for the signboard 1, 1/7 ≦ S / X ≦ 1/6, and the signboard 2 is a more desirable specification for 1/12 ≦ S / X ≦ 1/11. is there.

(About a suitable angle corresponding to 1/9 ≦ S / X ≦ 1 / 7.5)
Furthermore, a more preferable condition for the angle is derived based on 1/9 ≦ S / X ≦ 1 / 7.5, which is the slope length / total length of the sign 1 and the sign 2 described above.
In the sign 1, S / X = 1 / 7.5 corresponds to an angle of 12 degrees, and S / X = 1/9 corresponds to an angle of 14 degrees.
In the sign 2, S / X = 1 / 7.5 corresponds to an angle of 7 degrees, and S / X = 1/9 corresponds to an angle of 8.5 degrees.

  That is, the specification of the angle A is more preferably 12 degrees or more and 14 degrees or less for the signboard 1, and the specification is more preferably 7 degrees or more and 8.5 degrees or less for the signboard 2.

  The above-mentioned suitable specification when X = 1.8 m to 3.0 m is considered to be applicable even if there is a difference of about plus or minus 10% in the total length X.

<<< Relationship between Angle A and Slope Length / Full Length >>>
Here, the range of the slope length / full length that can be realized by the slope reflector 83 with the lower limit value of 3 degrees and the upper limit value of 30 degrees indicated as the above-described preferable conditions will be verified.
Although the slope reflector 83 will be described here as well, the slope reflector 84 is the same because it is symmetrical.

As described above, when the slope reflector 83 having a height of 0.05 m and a slope length of 0.086 m is installed at the end of the “signboard 2” having an overall length X of 3.0 m, the angle A is “tan”. ⁻¹ (0.05 / 0.086) = 30 degrees ”,“ slope length / full length [S / X] = 0.086 / 3.0 = 1/35 ”.
When a slope reflector 83 having an angle of 30 degrees and a height of 0.05 m and a slope length of 0.086 m is installed at the end of a signboard having a total length X of 0.172 m, for example, Long / full length [S / X] is 1/2.

  That is, as the total length X changes, the correspondence of the slope length / full length to the angle A changes. Therefore, the slope reflector 83 having an angle of 30 degrees can realize a structure of slope length / full length = 1/35 to 1/2.

For example, the angle of the slope reflector 83 having a height of 0.079 m and a slope length of 1.5 m is 3 degrees. When the slope reflector 83 having an angle of 3 degrees is installed at the end of the “signboard 2” having an overall length X of 3.0 m, “slope length / full length [S / X] = 1.5 / 3. 0 = 1/2.
On the other hand, for example, the angle of the slope reflector 83 having a height of 0.005 m and a slope length of 0.086 m is also 3 degrees. When the slope reflector 83 having the angle of 3 degrees is installed at the end of the “signboard 2” having the total length X of 3.0 m, “slope length / total length [S / X] = 0.086 / 3.0 = 1/35 ".

  That is, depending on the change in the height and slope length of the slope reflector 83, the correspondence between the slope length and the total length with respect to the angle A also changes. Therefore, the slope reflector 83 having an angle of 3 degrees can also realize a structure of slope length / full length = 1/35 to 1/2.

Therefore, if the total length X is changed (or the slope length S is changed), the slope reflector 83 at any angle of 3 degrees or more and 30 degrees or less has a slope length / total length = 1/35 to 1/2. Any of the above structures can be realized.
For example, the slope reflector 83 at any angle between 3 degrees and 30 degrees has a slope length / total length of “1/21 to 1/3”, “1/9 to 7.5”, “1/7 to 1”. / 6 ”and“ 1/12 to 1/11 ”can be realized.
Further, for example, a range of “7 degrees or more and 14 degrees or less” and “10 degrees or more and 11 degrees or less” is included in a range of 3 degrees or more and 30 degrees or less.
Therefore, the slope reflector 83 at any angle of “7 degrees or more and 14 degrees or less” has a slope length / total length of “1/21 to 1/3”, “1/9 to 7.5”, “1/1”. Any structure of “7 to 1/6” and “1/12 to 1/11” can be realized.
Further, the slope reflector 83 at any angle of “10 degrees or more and 11 degrees or less” has a slope length / total length of “1/21 to 1/3”, “1/9 to 7.5”, “1/7”. It is possible to realize any structure of “˜1 / 6” and “1/12 to 1/11”.

<<< Summary >>>>
When installing an elliptical light source (eg LED module BX03SA-W4F-765) on the side of the signboard, in addition to the bottom, install a reflector at an angle of about 7 to 14 degrees in the horizontal direction. The signboard's average illuminance increases.
The uniformity of light (standard deviation) is not impaired even when the reflector is installed obliquely at the end, and is equal to or more than that when the reflector is installed only on the bottom surface.
However, the effect of increasing the average illuminance decreases as the total length X of the signboard increases.

<<< Other Embodiments >>>>
Hereinafter, differences from the above embodiment will be described.

As shown in another configuration 1 in FIG. 25, the slope reflector 83 and the slope reflector 84 may be curved outward.
As shown in another configuration 2 in FIG. 25, the slope reflector 83 and the slope reflector 84 do not have to be symmetrical.

  As the LED module 70, a module other than BX03SA-W4F-765 may be used.

  Each example or each value in each of the above embodiments may be combined.

  The light source unit of the embodiment described above is
  A box-shaped housing having a bottom surface portion that reflects light, a side surface portion that reflects light, and an emission surface portion that emits light, and the bottom surface portion and the emission surface portion are parallel;
  A light emitting diode (LED) module that is attached to the side surface and irradiates light between the bottom surface and the exit surface in a predetermined light emitting direction;
  A slope reflector that is inclined from a side surface portion to a bottom surface portion in a predetermined light emitting direction of the LED module and reflects light of the LED module to an output surface portion;
It is characterized by providing.

  If the length of the bottom surface portion in the predetermined light emitting direction is the total length X, and the length in the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the side surface portion is the slope length S, 1/21 ≦ S / X ≦ 1/3.

  The angle formed by the slope reflector and the bottom surface is 7 degrees or more and 14 degrees or less.

  When the length of the bottom surface portion in the predetermined light emitting direction is the total length X and the length in the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the side surface portion is the slope length S, 1/9 ≦ S /X≦1/7.5.

  The angle formed by the slope reflector and the bottom surface is 10 degrees or more and 11 degrees or less.

  If the length of the bottom surface portion in the predetermined light emitting direction is the total length X, and the length of the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the side surface portion is the slope length S, 1/7 ≦ S / X ≦ 1/6.

  Assuming that the length of the bottom surface portion in the predetermined light emitting direction is the total length X and the length of the predetermined light emitting direction from the intersection position of the slope reflector and the bottom surface portion to the side surface portion is the slope length S, 1/12 ≦ S / X ≦ 1/11.

  A pair of LED modules are provided for the opposite side portions,
  A pair of slope reflectors is provided from a side surface portion to a bottom surface portion in a predetermined light emitting direction of a pair of LED modules,
  Each LED module is attached to the top and bottom center of the side part,
  Each of the slope reflectors is provided so as to be inclined from the lower center of the upper and lower sides of the side surface portion to the bottom surface portion.

  50 light source unit, 51 bottom surface portion, 52 side surface portion, 53 side surface portion, 54 side surface portion, 55 side surface portion, 56 exit surface portion, 60 housing, 70 LED module, 71 LED, 81 bottom reflector, 82 longitudinal reflector, 83 slope Reflector, 84 slope reflector, A angle, X total length, S slope length.

Claims (5)

A box-shaped housing having a bottom surface portion that reflects light, a plurality of side surface portions that are provided opposite to each other and that reflect light, and an emission surface portion that emits light, and wherein the bottom surface portion and the emission surface portion are parallel to each other; ,
Attached to one side surface of the side surface portion and the other side surface portion provided opposite to each other, and irradiates light between the bottom surface portion and the emission surface portion in a predetermined light emitting direction. A light emitting diode (LED) module,
A slope reflector that is provided to be inclined from the other side surface portion of the LED module in the predetermined light emission direction to the bottom surface portion and reflects light of the LED module to the emission surface portion; The predetermined light emission direction is parallel to the bottom surface portion and the emission surface portion,
The slope reflector reflects light to an end portion of the emission surface portion on the other side surface portion opposite to the one side surface portion to which the LED module is attached,
The surface of the bottom portion is covered with a flat bottom reflector,
An angle between the slope reflecting plate and the bottom portion is state, and are 3 times or more than 30 degrees,
When the length of the bottom surface portion in the predetermined light emitting direction is a full length X, and the length of the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the other side surface portion is a slope length S. 1/21 ≦ S / X ≦ 1/3 . An angle between the slope reflecting plate and the bottom portion, Ri 7 degrees 14 degrees der below,
When the length of the bottom surface portion in the predetermined light emitting direction is a full length X, and the length of the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the other side surface portion is a slope length S. the light source unit according to claim 1, characterized in that the 1/9 ≦ S / X ≦ 1 / 7.5. The angle formed by the slope reflector and the bottom surface is 10 degrees or more and 11 degrees or less,
When the length of the bottom surface portion in the predetermined light emitting direction is a full length X, and the length of the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the other side surface portion is a slope length S. The light source unit according to claim 1 , wherein 1/7 ≦ S / X ≦ 1/6. The angle formed by the slope reflector and the bottom surface is 10 degrees or more and 11 degrees or less,
When the length of the bottom surface portion in the predetermined light emitting direction is a full length X, and the length of the predetermined light emitting direction from the crossing position of the slope reflector and the bottom surface portion to the other side surface portion is a slope length S. the light source unit according to claim 1, wherein it is a 1/12 ≦ S / X ≦ 1/11. The LED module is provided in a pair with respect to the side parts provided opposite to each other,
A pair of the slope reflectors is provided from the other side surface portion to the bottom surface portion in the predetermined light emission direction of the pair of LED modules,
Each LED module is attached to the top and bottom center of each side part,
Each slope reflector, a light source unit according to any claim 1-4, characterized in that the lower part of the upper and lower center of each side portion is provided to be inclined toward the bottom portion.

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