JP7483536B2 - Illumination device equipped with light source module unit - Google Patents

Description

The present invention relates to a lighting device equipped with a light source module unit.

Known surface-emitting lighting devices used for signs, road signs, traffic information boards, etc. include direct-lighting lighting devices in which multiple light sources are arranged on the back side of the display board, and edge-lighting lighting devices in which a light guide plate is arranged on the back side of the display board and light sources are arranged on the side of this light guide plate.

In recent years, there has been a demand for larger light-emitting surfaces in these surface-emitting lighting devices to further enhance the design effect of buildings. One such demand for larger surfaces is the surface-emitting lighting device developed by the applicant of the present application and described in JP 2020-53157 A.

JP 2020-53157 A

The surface-emitting lighting device of Patent Document 1 ensures sufficient uniformity of brightness, making it possible to increase the size of lighting devices, which has been in demand in recent years, even with thin lighting devices. In designing a thin lighting device like that of Patent Document 1, the position and dimensions of each component are determined taking into consideration factors such as the dimensions and spacing of each component and the output of the light source in order to ensure sufficient uniformity of brightness.

In order to further commercialize this surface-emitting lighting device, the applicant is also researching and developing its application to buildings, such as walls, floors, and ceilings. During this development process, the inventor of the present application discovered that when applying a lighting device having multiple light source modules to an actual building, it is difficult to install the multiple light source modules as designed, and that if the multiple light source modules are not located as designed, there are cases in which sufficient uniformity of brightness cannot be ensured.

The present invention has been made to solve the above problems, and aims to provide a lighting device that is thin and can be made large, and that can easily ensure sufficient uniformity of brightness and improve ease of installation when applied to real buildings.

In order to solve the above problems, the present invention provides an illumination device comprising: a light source module unit having a plurality of light source modules; a light diffusing member facing the light source module unit; and a fixing frame to which the light source modules are fixed ;
a through hole into which a fixture for attaching the light source module to the fixing frame is inserted is formed in the light source module;
the fixing frame has a receiving portion on which a lower end of the light source module is placed,
a dimension of the through hole from an end of the light source module is the same as a dimension from a fixing portion of the fixing frame to which the light source module is fixed to the receiving portion;
A groove is formed in the fixing portion .

In the lighting device of the present invention, it is preferable that the fixing frame has a receiving portion on which the lower end of the light source module is placed.

In the lighting device of the present invention, it is preferable that the fixing frame is formed with a retaining groove portion that accommodates the upper end of the light source module.

In the lighting device of the present invention, it is preferable that the retaining groove portion is partially formed by the receiving portion.

In the lighting device of the present invention, it is preferable that the light source module has multiple LEDs arranged two-dimensionally.

The present invention provides a lighting device that is thin and can be made large, and that can easily ensure sufficient uniformity of brightness and improve ease of installation when applied to real buildings.

1 is a central vertical cross-sectional view of a lighting device according to a first embodiment; Cross-sectional view of the same A side view of the fixing frame showing the state in which the light source module is fixed An enlarged view of the area circled in FIG. Front view of LED module Front view of the fraction adjustment LED module 1A to 1E are diagrams showing the procedure for fixing the fixing frame and the LED module. 1 is a central vertical cross-sectional view of a lighting device according to a second embodiment; Cross-sectional view of the same 11 is a central vertical cross-sectional view of a lighting device according to a third embodiment; Cross-sectional view of the same FIG. 11 is a front view of a lighting device in which three lighting devices according to a third embodiment are arranged side by side;

The following describes in detail the embodiments of the present invention with reference to the drawings. In this specification, common components are shown with the same terminology, are illustrated in substantially the same manner in each drawing, and detailed descriptions are omitted, and are indicated by the same reference numerals as necessary.

The lighting device of the present invention comprises a light source module unit having multiple light source modules, a light diffusing member facing the light source module unit, and a fixing frame to which the multiple light source modules are fixed.

1 and 2 show a first embodiment of the lighting device of the present invention when it is mounted on the wall surface of a building to form a light wall. Note that in Figs. 1 and 2, intermediate portions in the vertical and horizontal directions are omitted. The lighting device 1 of this embodiment shown in Figs. 1 and 2 includes an upper frame 2, a lower frame 3, a right frame 4, a left frame 5, a fixing frame 6, a light source module unit 8 having a plurality of light source modules 7, and a light diffusion member 9. In this embodiment, the upper frame 2, the lower frame 3, the right frame 4, and the left frame 5 of the lighting device 1 are each fixed to the wall surface of the building. Note that the following description is based on the state in which the lighting device 1 is mounted on the wall surface of a building, unless otherwise specified.

The upper frame 2 can be, for example, a long aluminum molding. In this embodiment, the upper frame 2 has a radiation side planar portion 21 located on the side of the radiation direction of the light from the lighting device 1, a body side planar portion 22 located on the side opposite the radiation direction of the light from the lighting device 1, an intermediate planar portion 23 located between the radiation side planar portion 21 and the body side planar portion 22, and a connection planar portion 24 connected to the upper ends of the radiation side planar portion 21, the body side planar portion 22, and the intermediate planar portion 23. The upper frame 2 is fixed to the building's structure by screwing the body side planar portion 22 to the building's structure on which the lighting device 1 is mounted with fixing screws 16.

The lower end of the radial side plane portion 21 is formed with a protruding portion 21a that protrudes toward the intermediate plane portion 23. The lower end of the intermediate plane portion 23 is formed with a folded portion 23a that protrudes toward the radial side plane portion 21 and then toward the connecting plane portion 24. The intermediate plane portion 23 also has a protruding portion 23b between its upper and lower ends that protrudes toward the radial side plane portion 21. The connecting plane portion 24 is formed with tapping holes 24a between the radial side plane portion 21 and the intermediate plane portion 23, and between the intermediate plane portion 23 and the body side plane portion 22. The tapping holes 24a are used to tighten the assembly screws 18 for connecting the right frame 4 and the left frame 5.

In the upper frame 2 of this embodiment, the space surrounded by the radiation side plane portion 21, the intermediate plane portion 23, and the connection plane portion 24 constitutes a storage portion that stores the upper end of the light diffusion member 9.

The lower frame 3 can be, for example, a long aluminum molding. The lower frame 3 of this embodiment has a radiation side planar portion 31 located on the radiation direction side of the lighting device 1, a body side planar portion 32 located on the opposite side to the radiation direction of the light of the lighting device 1, an intermediate planar portion 33 located between the radiation side planar portion 31 and the body side planar portion 32, and a connection planar portion 34 connected to the lower ends of the radiation side planar portion 31, the body side planar portion 32, and the intermediate planar portion 33. The lower frame 3 is fixed to the building's structure by screwing the body side planar portion 32 to the building's structure on which the lighting device 1 is mounted with fixing screws 16.

The upper end of the radial side flat surface 31 is formed with a protruding portion 31a that protrudes toward the intermediate flat surface 33. The upper end of the intermediate flat surface 33 is formed with a folded portion 33a that protrudes toward the radial side flat surface 31 and then toward the connecting flat surface 34. The intermediate flat surface 33 also has a protruding portion 33b between its upper end and lower end that protrudes toward the radial side flat surface 31. The connecting flat surface 34 is formed with tapping holes 34a between the radial side flat surface 31 and the intermediate flat surface 33, and between the intermediate flat surface 33 and the body side flat surface 32. The tapping holes 34a are used to tighten the assembly screws 18 for connecting to the right frame 4 and the left frame 5.

In particular, in the lower frame 3 of this embodiment, the lower surface of the connection plane portion 34 is formed with extensions 35 and 36 with an L-shaped cross section. The extension 35 is formed between the radiation side plane portion 31 and the intermediate plane portion 33, and the extension 36 is formed at the end of the connection plane portion 34 opposite the radiation direction of the light of the lighting device 1 (below the frame side plane portion 32). In addition, the radiation side plane portion 31, the connection plane portion 34, and the extension 35 form a step portion 37 that is set back from the radiation side plane portion 31 toward the frame side. This step portion 37 can be inserted with the tip of a floor finishing material, improving the aesthetic appearance of the finish and ease of construction.

In the lower frame 3 of this embodiment, the space surrounded by the radiation side plane portion 31, the intermediate plane portion 33, and the connection plane portion 34 constitutes a storage portion that stores the lower end of the light diffusion member 9.

The right frame 4 and the left frame 5 are configured substantially identically, so an example of the configuration of the right frame 4 will be described, and an example of the configuration of the left frame 5 will be omitted. In this embodiment, the right frame 4 can be, for example, a long aluminum molded product, as shown in FIG. 2, and its cross-sectional shape is formed to be substantially rectangular. In the right frame 4 of this embodiment, five grooves 4c, 4d, 4e, 4f, and 4g are formed on the frame side 4b opposite the light diffusion member side 4a facing the left frame 5. Among these grooves, the grooves 4c and 4g are fastened with assembly screws 18 for connecting the upper frame 2 and the lower frame 3. In addition, the groove 4e is fastened with a fixing screw 16 for fixing the right frame 4 to the frame of the building in which the lighting device 1 is mounted. The five grooves 4c, 4d, 4e, 4f, and 4g have a depth such that the head of the assembly screw 18 does not protrude from the frame side.

Figure 3 is a side view of the fixed frame 6 showing the state in which the light source module 7 is fixed, and Figure 4 is an enlarged view of the part circled in Figure 3. The fixed frame 6 can be, for example, a long aluminum molding. The fixed frame 6 of this embodiment has a mounting surface portion 61, a fixing portion 62 formed above the mounting surface portion 61, a receiving portion 64 formed below the mounting surface portion 61 via a connecting portion 63, and a holding groove portion 65 formed below the receiving portion 64. The fixed frame 6 is attached to the building frame by screwing the mounting surface portion 61 to the building frame on which the lighting device 1 is mounted with fixing screws 16.

The light source module 7 is fixed to the fixing portion 62 by a mounting screw 17, which is a mounting fixture. In this embodiment, the fixing portion 62 has a groove into which the light source module 7 can be screwed.

Specifically, one end of the connection portion 63 is connected to the lower end of the mounting surface portion 61, and the other end is configured to be flush with the tip of the fixing portion 62. In this embodiment, the receiving portion 64 is connected to the lower surface of the connection portion 63 near the other end.

The receiving portion 64 in this embodiment has an L-shape with a first portion 64a extending parallel to the mounting surface portion 61 and a second portion 64b extending in the direction of light emission from the lighting device 1. The lower end of the light source module 7 fixed to the fixing portion 62 is placed on the upper surface of the second portion 64b.

The holding groove 65 is configured to be able to accommodate the upper end of the light source module 7, and accommodates the upper end of another light source module 7 fixed to the lower side of the light source module 7 fixed to the fixing portion 62. Note that if the light source module 7 fixed to the fixing portion 62 is the bottom layer, the upper end of the light source module 7 is not accommodated in the holding groove 65.

The holding groove 65 of this embodiment includes a first portion 65a extending parallel to the mounting surface 61, which is continuous with the first portion 64a of the receiving portion 64, a second portion 65b extending from the lower end of the first portion 65a toward the light radiation direction of the lighting device 1, and a third portion 65c extending parallel to the mounting surface 61 from the end of the second portion 64b of the receiving portion 64 in the light radiation direction of the lighting device 1. In particular, the holding groove 65 of this embodiment is composed of the first portion 65a, the second portion 65b, the third portion 65c, and the second portion 64b of the receiving portion 64. Thus, in this embodiment, the holding groove 65 is partially composed of the receiving portion 64. However, the holding groove 65 may be composed completely separately from the receiving portion 64.

The tip of the second portion 65b of the retaining groove 65 is configured to be flush with the tip of the fixing portion 62 and the other end of the connecting portion 63.

Figure 5 is a front view of an LED module 7A in which multiple LEDs used as the light source module 7 in this embodiment are arranged two-dimensionally, and Figure 6 is a front view of an LED module 7B for fraction adjustment. The light source module unit 8 can be constructed by combining multiple LED modules 7A and multiple LED modules 7B for fraction adjustment. In this embodiment, the light source module unit 8 is constructed by arranging two LED modules 7A in the vertical direction and two in the horizontal direction. The distance (clearance) between the LED modules 7A in the horizontal direction is the same as the vertical dimension t (plate thickness in this embodiment) of the second portion 64b of the receiving portion 64 of the fixed frame 6.

In the LED module 7A of this embodiment, pairs of LEDs 72 are arranged in a grid pattern of eight rows vertically and seven rows horizontally at equal intervals on the surface 71a of a roughly rectangular substrate 71 measuring approximately 290 mm x 290 mm. Electricity is supplied to the LED module 7A by a known power supply structure such as an electric cable.

As shown in FIG. 5, the substrate 71 of the LED module 7A of this embodiment has a plurality of through holes 73 that penetrate to the back surface 71b at positions along the diagonal of the rectangle on the front surface 71a. The cores of the through holes 73 of this embodiment are provided so that the dimension A from the end of the substrate 71 of the LED module 7A, i.e., the side of the rectangular substrate 71, is the same as the dimension A from the core (core of the mounting screw 17) of the fixing part 62 of the fixing frame 6 to the second part 64b (upper surface) of the receiving part 64. In particular, the cores of the through holes 73 of this embodiment are provided so that the distance from the two adjacent sides of the substrate 71 of the LED module 7A is the same as the dimension A from the core of the fixing part 62 of the fixing frame 6 to the second part 64b (upper surface) of the receiving part 64. The substrate 71 is further provided with a plurality of connectors 74.

The fraction adjustment LED module 7B is a lattice arrangement of eight vertical rows and seven horizontal rows of pairs of LEDs 72 spaced equally apart on the surface 71a of a roughly rectangular substrate 71 measuring approximately 290 mm x 290 mm, which can be divided into four equal parts. Each of the fraction adjustment LED modules 7B1 to 7B4 has two vertical rows and seven horizontal rows of LEDs 72. Note that Figure 6 shows the module 7B before it is divided into four, with cut lines provided at the parts to be divided. The fraction adjustment LED module 7B is also supplied with electricity via a known power supply structure such as an electric cable.

As shown in FIG. 6, the substrate 71 of each of the fraction adjustment LED modules 7B1 to 7B4 of this embodiment has two through holes 73 penetrating to the back surface 71b. The core of the through hole 73 of this embodiment is provided so that the dimension A from the end of each substrate 71 of the fraction adjustment LED modules 7B1 to 7B4, i.e., the side of the rectangular substrate 71, is the same as the dimension A from the core of the fixing portion 62 of the fixing frame 6 to the second portion 64b (upper surface) of the receiving portion 64. In particular, the core of the through hole 73 of this embodiment is provided so that the dimension from two adjacent sides of each substrate 71 of each of the fraction adjustment LED modules 7B1 to 7B4 is the same as the dimension A from the core of the fixing portion 62 of the fixing frame 6 to the second portion 64b of the receiving portion 64. Two connectors 74 are further provided on each substrate 71.

In this embodiment, the light diffusion member 9 is composed of a glass plate made of laminated glass with a milky white intermediate film. In the present invention, it is preferable that the surface on which the light source such as the LED of the light source module unit 8 is arranged is parallel to the surface of the light diffusion member 9 facing the light source module unit 8 (inner surface) and/or the surface of the light diffusion member 9 opposite to the surface facing the light source module unit 8 (outer surface).

As shown in FIG. 1, in this embodiment, the light diffusion member 9 is positioned in the vertical direction by being placed on a setting block 10 provided on the lower frame. The upper and lower ends of this light diffusion member 9 are sandwiched between a pre-attached bead 11 and a post-attached bead 12, similar to known fixed windows, and are accommodated in the accommodation sections of the upper frame 2 and the lower frame 3, respectively.

The pre-attached bead 11 is made of soft polyvinyl chloride, and has a shape that is held by the intermediate flat portion 23 and the intermediate flat portion 33 by partially inserting it between the folded portion 23a and the protruding portion 23b of the intermediate flat portion 23 of the upper frame 2, and between the folded portion 33a and the protruding portion 33b of the intermediate flat portion 33 of the lower frame 3.

The retrofit bead 12 is made of soft polyvinyl chloride and has a shape that is held by the radial side flat surface 21 and the radial side flat surface 31 by fitting (inserting) between the protrusion 21a of the radial side flat surface 21 of the upper frame 2 and the outer surface of the light diffusion member 9, and between the protrusion 31a of the radial side flat surface 31 of the lower frame 3 and the outer surface of the light diffusion member 9.

As shown in FIG. 2, in this embodiment, a silicone joint material 13 is provided between the right frame 4 and the left frame 5 and the light diffusion member 9. If the lighting device 1 has two or more light diffusion members 9, this joint material 13 is also provided between the light diffusion members 9.

Next, the procedure for fixing the fixing frame and LED module in this embodiment will be described with reference to FIG. 7. First, as shown in FIG. 7(A), the fixing frame 6 to which the lowest light source module 7 is fixed is attached by screwing it to the desired position of the building's framework (specifically, the base material) with the fixing screws 16. In this embodiment, as shown in FIG. 1, the lower end (lower surface of the connection portion 63) of the mounting surface portion 61 of the fixing frame 6 to which the lowest light source module 7 is fixed is abutted against the upper end of the framework-side flat portion 32 of the lower frame 3, thereby positioning the fixing frame 6 to which the lowest light source module 7 is fixed in the vertical and horizontal directions (longitudinal direction).

Next, as shown in FIG. 7(B) and FIG. 7(C), the lower end of the light source module 7 is abutted against the second portion 64b of the receiving portion 64 of the fixed frame 6 from above the receiving portion 64 of the fixed frame 6. At this time, the tip of the fixing portion 62 of the fixed frame 6 and the tip of the connecting portion 63 are in contact with the back surface 71b of the light source module 7, so that the substrate 71 of the light source module 7 and the mounting surface portion 61 of the fixed frame 6 can be made parallel. In particular, in this embodiment, the through hole 73 of the light source module 7 is formed at a position where the dimension A from the end of the light source module 7 is the same as the dimension A from the core of the fixing portion 62 of the fixed frame 6 to the second portion 64b of the receiving portion 64. Therefore, the position of the through hole 73 and the fixing portion 62 can be aligned simply by placing the light source module 7 in abutment against the second portion 64b of the receiving portion 64 of the fixed frame 6.

Next, as shown in FIG. 7(C), the fixing part 62 with the groove formed therein and the light source module 7 are fixed together with the mounting screw 17.

Next, as shown in FIG. 7(D), the upper end of the light source module 7 fixed to the fixing portion 62 is fitted into the holding groove portion 65 of the other fixed frame 6. At this time, the tip of the second portion 65b of the holding groove portion 65 comes into contact with the rear surface 71b of the light source module 7, thereby maintaining a parallel relationship between the substrate 71 of the light source module 7 and the mounting surface portion 61 of the other fixed frame 6. In particular, in this embodiment, the other fixed frame 6 with the upper end of the light source module 7 fitted into the holding groove portion 65 has its mounting position in the vertical direction guided by the upper end of the light source module 7, making it easy to position it in the vertical direction.

Next, as shown in FIG. 7(E), with the upper end of the light source module 7 fitted into the retaining groove 65, another fixing frame 6 is attached by screwing it to the building's framework with fixing screws 16 in the same manner as in FIG. 7(A). By repeating the steps in FIG. 7(A) to (E) according to the number of light source modules 7 to be stacked vertically, the desired number of light source modules 7 can be stacked vertically.

In the lighting device of the above embodiment, the light source modules 7 constituting the light source module unit 8 are fixed to the fixed frame 6. In such a lighting device 1, multiple light source modules 7 can be installed as designed simply by fixing the light source modules 7 to the fixed frame 6. Therefore, even when a lighting device that is thin and can be made large is applied to an actual building, it is possible to easily ensure sufficient uniformity of brightness and improve workability.

In the lighting device 1 of the above embodiment, the light source module 7 is formed with a through hole 73 into which a mounting screw 17, which is a mounting tool for mounting the light source module 7 to the fixed frame 6, is inserted. This makes it easy to mount the light source module 7 to the fixed frame 6.

In the lighting device 1 of the above embodiment, the fixed frame 6 has a receiving portion 64 on which the lower end of the light source module 7 is placed. This makes it easy to position and attach the light source module 7 to the fixed frame 6.

In the lighting device 1 of the above embodiment, the dimension A from the end of the light source module 7 to the core of the through hole 73 is the same as the dimension A from the core of the fixing part 62 to which the light source module 7 of the fixing frame 6 is fixed to the second part 64b of the receiving part 64. Therefore, the positions of the through hole 73 and the fixing part 62 can be aligned simply by placing the light source module 7 in contact with the receiving part 64 of the fixing frame 6.

In the lighting device 1 of the above embodiment, a groove is formed in the fixing portion 62. This makes it easy to screw the light source module 7 to the fixing frame 6. In addition, there is no need to drill pilot holes for screwing in the fixing portion 62.

In the lighting device 1 of the above embodiment, the fixing frame 6 is formed with a holding groove portion 65 that accommodates the upper end of the light source module 7. Therefore, the fixing frame 6 that accommodates the upper end of the light source module 7 has its mounting position in the vertical direction guided by the upper end of the light source module 7, making it easy to position it in the vertical direction.

In addition, in the lighting device 1 of the above embodiment, the holding groove portion 65 is partially formed by the receiving portion 64. Therefore, the distance (clearance) between adjacent light source modules 7 in the vertical direction is the same as the vertical dimension t of the second portion 64b of the receiving portion 64 of the fixed frame 6, so the distance (clearance) between the upper and lower light source modules 7 can be easily controlled.

In addition, in the lighting device 1 of the above embodiment, the lower end (the lower surface of the connection portion 63) of the mounting surface portion 61 of the fixed frame 6 to which the lowest light source module 7 is fixed is abutted against the upper end of the body side flat portion 32 of the lower frame 3. This makes it particularly easy to position the fixed frame 6 to which the lowest light source module 7 is fixed in the vertical and horizontal directions (longitudinal direction).

In the first embodiment shown in FIG. 1, the light source module unit 8 extends in the vertical direction of the lighting device 1 from the lower end of the body-side flat surface 22 of the upper frame 2 to the upper end of the body-side flat surface 32 of the lower frame 3. However, depending on the dimensions of the wall surface of the building (the installation dimensions of the lighting device 1), there may be cases where the distance between the lower end of the body-side flat surface 22 of the upper frame 2 and the upper end of the body-side flat surface 32 of the lower frame 3 is greater than the dimension from the upper end of the light source module unit 8 to the upper end of the body-side flat surface 32 of the lower frame 3.

In this case, it may be possible to address the issue by increasing the number of light source modules 7 in the vertical direction of the light source module unit 8. However, in the vertical direction of the lighting device 1, the dimension from the lower surface of the connecting flat portion 24 of the upper frame 2 to the upper end of the light source module unit 8 may be shorter than the vertical dimension of the light source module 7, making it impossible to increase the number of light source modules 7 in the vertical direction of the light source module unit 8.

In such a case, the lighting device of the present invention can be configured as in the second embodiment shown in FIG. 8. In the embodiment of FIG. 8, one LED module 7A is arranged in the vertical direction and four in the horizontal direction to configure the light source module unit 8. The distance (clearance) between the LED modules 7A in the horizontal direction is the same as the vertical dimension t of the second part 64b of the receiving portion 64 of the fixed frame 6. In the second embodiment shown in FIG. 8, two upper frames 2 are connected in the horizontal direction of the lighting device 1 by screwing them to the joint fittings 14. Similarly, two lower frames 3 are connected in the horizontal direction of the lighting device 1 by screwing them to the joint fittings 14. Furthermore, in the second embodiment shown in FIG. 8, the lower frame 3 has the same shape as the upper frame 2.

In the second embodiment, the fixing frame 6 to which the LED module 7A is fixed is attached to the building frame without the lower end of the mounting surface 61 abutting against the upper end of the frame frame 3's frame-side flat surface. When adopting such a configuration, it is preferable that the distance B between the light source module unit 8 and the light diffusion member 9 (the distance between the surface 71a of the LED module 7A and the inner surface of the light diffusion member 9) is larger than the distance C between the lower end of the light source module unit 8 (the upper surface of the second part 64b of the receiving portion 64) in the vertical direction of the lighting device 1 and the upper end of the frame frame 3's frame-side flat surface. By having such a relationship, the lower part of the lighting device 1 is prevented from becoming dark, and sufficient uniformity of brightness can be easily ensured.

In the second embodiment, in the vertical direction of the lighting device 1, the upper end of the light source module unit 8 does not extend to the lower end of the body-side flat portion 22 of the upper frame 2. When adopting such a configuration, it is preferable that the distance B between the light source module unit 8 and the light diffusing member 9 is larger than the distance D between the upper end of the light source module unit 8 and the lower end of the body-side flat portion 22 of the upper frame 2 in the vertical direction of the lighting device 1. By achieving such a relationship, the upper part of the lighting device 1 is prevented from becoming dark, and sufficient uniformity of brightness can be easily ensured.

In the second embodiment, the distance C between the lower end of the light source module unit 8 and the upper end of the frame 3's frame-side flat surface portion 32 in the vertical direction of the lighting device 1 is the same as the distance D between the upper end of the light source module unit 8 and the lower end of the frame-side flat surface portion 22 in the upper frame 2. However, the distance C between the lower end of the light source module unit 8 and the upper end of the frame-side flat surface portion 32 in the vertical direction of the lighting device 1 and the distance D between the upper end of the light source module unit 8 and the lower end of the frame-side flat surface portion 22 in the upper frame 2 may be different. In addition, the distance C or the distance D may be formed only between the lower end of the light source module unit 8 and the upper end of the frame-side flat surface portion 32 in the vertical direction of the lighting device 1, or between the upper end of the light source module unit 8 and the lower end of the frame-side flat surface portion 22 in the upper frame 2.

In the first embodiment shown in FIG. 2, the light source module unit 8 extends across the entire light diffusion member 9 in the left-right direction of the lighting device 1. However, depending on the dimensions of the building wall (the installation dimensions of the lighting device 1), the dimensions of the light source module unit 8 in the left-right direction of the lighting device 1 may be smaller than the dimensions of the light diffusion member 9 in the left-right direction.

In this case, it may be possible to address the issue by increasing the number of LED modules 7A in the left-right direction of the light source module unit 8. However, in the left-right direction of the lighting device 1, the difference between the inside dimension between the right frame 4 and the left frame 5 and the outside dimension of the light source module unit 8 may be shorter than the left-right dimension of the LED module 7A, making it impossible to increase the number of LED modules 7A in the left-right direction of the light source module unit 8.

In such a case, the lighting device of the present invention can be configured as shown in the cross-sectional view of the second embodiment in FIG. 9. In the embodiment of FIG. 9, both ends of the light source module unit 8 do not have to extend to both ends of the light diffusion member 9 in the left-right direction of the lighting device 1. When adopting such a configuration, it is preferable that the distance B between the light source module unit 8 and the light diffusion member 9 is larger than the distances E and F between both ends of the light source module unit 8 and both ends of the light diffusion member 9 in the left-right direction of the lighting device 1. By making such a relationship, it is possible to prevent the left-right ends of the lighting device 1 from becoming dark, and to easily ensure sufficient uniformity of brightness. In this embodiment, the left-right dimension of the light diffusion member 9 is the same as the left-right dimension of the fixed frame 6.

In the second embodiment, the distance E between the left frame end of the light source module unit 8 and the left frame end of the light diffusion member 9 in the left-right direction of the lighting device 1 is the same as the distance F between the right frame end of the light source module unit 8 and the right frame end of the light diffusion member 9. However, the distance E between the left frame end of the light source module unit 8 and the left frame end of the light diffusion member 9 in the left-right direction of the lighting device 1 may be different from the distance F between the right frame end of the light source module unit 8 and the right frame end of the light diffusion member 9. In addition, the distance E or the distance F may be formed only between the left frame end of the light source module unit 8 and the left frame end of the light diffusion member 9, and between the right frame end of the light source module unit 8 and the right frame end of the light diffusion member 9 in the left-right direction of the lighting device 1.

Figure 10 is a central vertical cross-sectional view of a lighting device according to the third embodiment, Figure 11 is a horizontal cross-sectional view of the same, and Figure 12 is a front view of a lighting device formed by arranging three lighting devices according to the third embodiment.

In the third embodiment, six LED modules 7A are arranged in the vertical direction and nine in the horizontal direction per lighting device 1. The distance (clearance) between the LED modules 7A in the horizontal direction is the same as the vertical dimension t of the second part 64b of the receiving portion 64 of the fixed frame 6. In this third embodiment, the upper frame 2 and lower frame 3 are made longer than the upper and lower frames of the first embodiment in the horizontal direction.

In the third embodiment, as in the first embodiment, the lower end of the mounting surface portion 61 of the fixing frame 6 to which the bottom LED module 7A is fixed is abutted against the upper end of the body side flat portion 32 of the lower frame 3, thereby positioning the fixing frame 6 to which the bottom LED module 7A is fixed in the vertical and horizontal directions (longitudinal direction).

In the third embodiment, a wet sealant 15 is used instead of the post-installation bead 12. In the third embodiment, the light diffusing member 9 for one lighting device 1 is configured by arranging three glass plates in the left-right direction. In addition, sealant 15 is provided between the glass plates in the left-right direction, between the glass plates and the right frame 4, and between the glass plates and the left frame 5.

In the third embodiment, the upper end of the top LED module 7A in the vertical direction of the lighting device 1 does not extend to the lower end of the frame-side flat portion 22 of the upper frame 2. Also, the distance B between the LED module 7A and the light diffusing member 9 is smaller than the distance D between the upper end of the top LED module 7A in the vertical direction of the lighting device 1 and the lower end of the frame-side flat portion 22 of the upper frame 2. Therefore, in the third embodiment, the fraction adjustment LED module 7B is added to the top layer of the LED module 7A to form the light source module unit 8. In this embodiment, the fraction adjustment LED modules 7B1 to 7B3 (with module 7B4 separated) are attached to the top of the top LED module 7A via the fixing frame 6. This configuration also makes it possible to accommodate the dimensions of the wall of the building.

In the above embodiment, the lighting device is mounted on the wall of a building to create a light wall, but the lighting device of the present invention can also be mounted on the ceiling or floor of a building, or can be used as a lighting device for a signboard.

In the above embodiment, the light diffusion member 9 is a glass plate, but the light diffusion member 9 can be made of any translucent or semi-translucent material, such as paper, cloth, or resin.

In the above embodiment, the case where the fraction adjustment LED module 7B is attached to the top layer of the LED module 7A has been described, but the fraction adjustment LED module 7B can also be attached to the left or right end of the lighting device 1.

The present invention can be understood as a wall surface and a building equipped with the lighting device of the present invention. The present invention can also be understood as a light source device equipped with a light source module unit and a fixing frame in the lighting device of the present invention.

The present invention is not limited to the embodiments described above, and many modifications are possible within the technical concept of the present invention by those with ordinary skill in the art.

The present invention provides a lighting device that is thin and can be made large, and that easily ensures sufficient uniformity of brightness and improves ease of installation when applied to real buildings.

1: Lighting device 2: Upper frame 21: Radiation side flat surface 21a: Protrusion 22: Body side flat surface 23: Intermediate flat surface 23a: Folded portion 23b: Protrusion 24: Connection flat surface 24a: Tapping hole 3: Lower frame 31: Radiation side flat surface 31a: Protrusion 32: Body side flat surface 33: Intermediate flat surface 33a: Folded portion 33b: Protrusion 34: Connection flat surface 34a: Tapping hole 37: Step 4: Right frame 4a: Light diffusion member side surface 4b: Body side surface 4c: Groove 4d: Groove 4e: Groove 4f: Groove 4g: Groove 5: Left frame 6: Fixing frame 61: Mounting surface 62: Fixing portion 63: Connection portion 64: Receiving portion 64a: First portion 64b: Second portion 65: Retaining groove 65a: First portion 65b: Second portion 65c: Third portion 7: Light source module 7A: LED module 7B: LED module for adjusting fraction 71: Board 72: LED 73: Through hole 74: Connector 8: Light source module unit 9: Light diffusion member 10: Setting block 11: Pre-attached bead 12: Post-attached bead 13: Joint material 14: Joint fitting 15: Sealing material 16: Fixing screw 17: Mounting screw 18: Assembly screw

Claims (5)

a light source module unit having a plurality of light source modules;
a light diffusing member facing the light source module unit;
a fixing frame to which the light source module is fixed ,
a through hole into which a fixture for attaching the light source module to the fixing frame is inserted is formed in the light source module;
the fixing frame has a receiving portion on which a lower end of the light source module is placed,
a dimension of the through hole from an end of the light source module is the same as a dimension from a fixing portion of the fixing frame to which the light source module is fixed to the receiving portion;
The lighting device has a groove formed in the fixing portion . The lighting device according to claim 1 , wherein the fixing frame has a receiving portion on which a lower end of the light source module is placed. 3. The lighting device according to claim 1, wherein the fixing frame is formed with a holding groove for accommodating an upper end of the light source module. The fixing frame has a holding groove for receiving an upper end of the light source module,
The lighting device according to claim 2 , wherein the holding groove portion is partially formed by the receiving portion. 5. The lighting device according to claim 1 , wherein the light source module has a plurality of LEDs arranged two-dimensionally.

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