JP2013038016A - Window-like lighting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a window-like lighting device capable of attaining a uniform luminance distribution in a plane of a dimming plate.SOLUTION: The window-like lighting device includes a surface-shaped dimming member having an incident surface and an emitting surface and emitting light incident from the incident surface from the emitting surface by refracting the light, a lattice member having a first side face approximately perpendicular to the dimming member and a second side face opposite to the first side face, a light source arranged on the first side face of the lattice member, and a reflection section arranged on the second side face and reflecting light from the light source to the incident surface of the dimming member.

Description

  Embodiments described herein relate generally to a window-type lighting device.

  There has been proposed a window-type illumination device that has both a function as a window for taking in natural light from the outside and a function as illumination by a light source such as an LED. Such an illuminating device includes a light source for illumination and a dimming plate that adjusts light transmission by refracting light from the light source, and has a function as a window and a function as illumination. Can be switched.

  When the lighting device functions as illumination, the light control plate refracts light from the light source and diffuses it within the surface of the light control plate. As a result, the entire surface of the light control plate shines, and this light is irradiated into the room as illumination light.

  However, when a plurality of light sources are arranged in parallel to the surface of the light control plate, the light from the light sources is irradiated into the room without being sufficiently diffused when the lighting device functions as illumination. As a result, the luminance near the light source in the plane of the light control plate is increased. For this reason, in the plane of the light control plate, a bright area is partially strong and dazzled, which is not preferable as a lighting device.

JP 2008-192507 A

  Provided is a window illumination device capable of making the luminance distribution in a plane of a light control plate closer to uniform.

  The window-type illumination device of the embodiment has an incident surface and an exit surface, and is parallel to the planar light control member that refracts light incident from the entrance surface and emits the light from the exit surface. A grating member having a first side surface substantially perpendicular to the light control member and a second side surface facing the first side surface; a light source provided on the first side surface of the grating member; And a reflecting portion that is provided on two side surfaces and reflects light from the light source toward the incident surface of the light control member.

The block diagram of the window type illuminating device which concerns on 1st embodiment. The figure explaining the function of the window type illuminating device which concerns on 1st embodiment. The block diagram of the window grating | lattice of the window type illuminating device which concerns on 1st embodiment. The figure explaining the function of the window lattice of the window type illuminating device which concerns on 1st embodiment. The block diagram of the window grating | lattice of the window-type illuminating device which concerns on the modification of 1st embodiment. The block diagram of the window lattice of the window type illuminating device which concerns on 2nd embodiment.

  Hereinafter, embodiments for carrying out the invention will be described.

(First embodiment)
FIG. 1 is a diagram illustrating a configuration of a window-type lighting device 100 according to the first embodiment.

  The window illumination device 100 is installed as a window in a building such as a general home or office. And, for example, it functions as a window that directly captures natural light during the day, and when it is not possible to collect sufficient natural light due to the weather, etc. even during the day, or as illumination with a light source 31 such as an LED as necessary at night Function.

  In FIG. 1, the front side of the window-type lighting device 100 is the indoor side of the building, and the back side is the outdoor side. Moreover, this window-shaped illuminating device 100 may be always fixed and installed, or may be installed movably along the window rail, for example.

1 includes a window frame 10, a light control plate 20 attached to the window frame 10, a plurality of window lattices 30 attached in parallel to the window frame 10 from the outside, and the window illumination device 100, respectively. A control unit 40 that switches the functions of the window lighting device 100, and an operation unit 50 that allows the user to select a function of the window illumination device 100.

  The window frame 10 forms the outer periphery of the window-type lighting device 100. For example, an open rectangular frame. When the frame window 10 is fixedly installed, a part of the frame window 10 may be integrated with the wall surface of the building.

  The light control plate 20 is a flat plate member that is attached to the inside so as to fill the opening of the window frame 10. This light control plate 20 is controlled to be in a transparent state (normal mode) shown in FIG. 2A and an opaque state (diffusion mode) shown in FIG. Can be switched.

  The light control plate 20 has liquid crystal molecules inside. For example, the light transmittance is controlled by changing the refractive index of incident light by controlling the orientation and arrangement of the internal liquid crystal molecules by applying a voltage. Can be switched between the normal mode and the diffusion mode.

  The normal mode is used when the window illumination device 100 functions as a window, and the diffusion mode is used when the window illumination device 100 functions as illumination.

  When functioning as illumination, switching to the above diffusion mode diffuses light incident from the outdoor side surface (incident surface) of the light control plate 20, and diffuses this light to the indoor side surface (exit surface). ) Can illuminate the room.

  The window lattice 30 is attached to the window frame 10 in a state horizontal to the plane of the light control plate 20. Specifically, as shown in FIG. 1, a plurality of window lattices 30 are provided in parallel with each other over the plane of the light control plate 20. As will be described in detail later, the window lattice 30 is provided with a light source 31 such as an LED and a reflection portion 32 that reflects light from the light source 31 toward the light control plate 20.

  The control unit 40 is electrically connected to the light control plate 20 and the light source 31 of the window grid 30 through, for example, conductive leads 34. Then, the control unit 40 applies a voltage to the light control plate 20 and the light source 31 through the lead 34.

  Thereby, switching of the mode of the light control plate 20 and light emission of the light source 31 provided in the window lattice 30 are controlled.

Hereinafter, the configuration of the window grid 30 will be described in detail with reference to FIG. 3. FIG. 3 is a diagram showing the configuration of the window grid 30. 3A is a perspective view of the window grid 60, and FIG. 3B is a top view of the window grid 60. FIG.

  The window lattice 30 includes a lattice main body 33, a plurality of light sources 31 such as LEDs provided in the lattice main body 33, and a reflection portion 32 that reflects light from the light source 31.

  The lattice main body 33 is a columnar member as shown in FIG. Specifically, the side surface A on which the light source 31 is provided and the side surface B on which the reflection unit 32 is provided face each other. The side surface A and the side surface B are connected by the back surface C.

  The side surface A, the side surface B, and the back surface C are integrally formed. The material of the grid body 33 is preferably a material with excellent heat dissipation (such as a heat dissipation material based on an aluminum alloy or synthetic resin) in order to dissipate heat from the light source 31. In this embodiment, an aluminum alloy is used.

  The light source 31 is a fine point light source such as an LED disposed on the side surface A of the grid body 33 along the longitudinal direction of the grid body 33. The plurality of light sources 31 are connected via a single lead 34 shared with the control unit 40.

  The reflection part 32 is a convex member provided facing the side surface A on which the light source 31 of the lattice body 33 is provided. The reflection part 32 is formed integrally with the side surface B of the lattice body 30. Accordingly, since the material is the same aluminum alloy as that of the lattice main body 33, the reflecting portion 32 reflects the irradiated light.

  Further, in the present embodiment, since the reflecting portion 32 has a convex shape, the light to be irradiated is reflected and diffused as described above (hereinafter, diffuse reflection) prior to the diffusion at the light control plate 20. ).

  In addition, as the reflection part 32, you may form in combination as a member different from the lattice main body 30. FIG. In this case, for example, a material that reflects light, such as an aluminum alloy, can be used in the same manner as described above. When a material that does not reflect light is used, the surface of the reflecting portion 32 reflects light. It is also possible to coat with a material.

Next, the arrangement relationship between the light control plate 20 and the window lattice 30 will be described with reference to FIG. 4A shows this embodiment, and FIG. 4B shows the distance between the back surface C and the surface of the light control plate 20 as L3 as in FIG. 4A. Comparative examples in the case of providing 31 are shown.

  As described above, the window lattice 30 is provided in parallel to the plane of the light control plate 20. Further, in the present embodiment, the side surface A and the plane of the light control plate 30 are arranged substantially vertically.

  Specifically, as shown in FIG. 4A, the side surface A and side surface B of the window lattice 30 and the plane of the light control plate 30 are in a substantially vertical positional relationship, and the back surface C of the window lattice 30 and the light control plate The 20 planes are in a substantially horizontal positional relationship.

  Thereby, it is possible to prevent light from the light source 31 from directly irradiating the plane of the dimming plate 30, and light diffusely reflected by the reflecting portion 32 is irradiated to the plane of the dimming plate 30. It will be. Therefore, by preventing the luminance from being improved in the vicinity of the planar light source 31 of the light control plate 30, the planar luminance distribution can be made uniform. For the same reason, the luminance in the vicinity of the light source 31 can be reduced, and the antiglare property can be improved.

  Further, as shown in FIG. 4A, the window lattice 30 is arranged such that the light source 31 and the surface of the light control plate 20 are separated from the light control plate 20 by a distance L1. At this time, when the shortest distance (straight line distance) from the center of the light source 31 to the reflecting portion 32 is L2, the light source 31 is formed so as to satisfy L1 + L2 ≧ L3.

  Thereby, compared with the case where the light directly from the light source 31 arranged on the back surface C reaches as in the comparative example, in this embodiment, the path length (OA + AB) between the surface of the light source 31 and the light control plate 20 is long. Since the light from the light source 31 spreads over a wider range, the luminance distribution in the plane can be made closer to uniform by preventing the improvement in luminance in the vicinity of the light source 31 on the plane of the light control plate 30 in addition to the above.

  Further, as the distance between the light source 31 and the surface of the light control plate 20 is longer, the light from the light source 31 spreads over a wider range, but the path length is set in a direction (OA) parallel to the surface of the light control plate 20 as described above. Since it becomes possible to shorten L3 by that much, the window-type illuminating device 100 can be reduced in thickness.

  Further, by adopting the configuration of the window lattice 30 as described above, when the light control plate 30 is in the normal mode, the light source 31 does not directly enter the field of view of the user in the room. Property (designability) can be improved.

  Furthermore, since the light source 31 is surrounded by the side surfaces A and B and the back surface C of the grid body 33 except for the indoor side, the light emission from the light control plate 20 is reduced without irradiating light outdoors. be able to.

(Example)
Specific examples will be described below.

In this embodiment, a small LED (size: 3.0 mm × 1.4 mm, luminous flux: 50 lumen) is used as the light source 31. In addition, a lattice main body 32 made of an aluminum alloy (heat transfer coefficient 5 [W / (K · m ² )]) whose back surface C is 400 mm in length in the longitudinal direction and 20 mm in width is used.

  In one window grid 30, nine LEDs are arranged in series along the longitudinal direction. The window frame 10 is provided with five window lattices 30 in parallel. Therefore, in this case, the entire window-type lighting device includes a total of 45 LEDs, and a total of 2250 lumens of light is emitted. This is a value sufficient to use the window illumination device as the illumination device.

  The driving voltage per LED is 6.5V, and a total voltage of 58.5V is required to illuminate nine LEDs arranged in series. This is a value that can be sufficiently covered by a general power source.

  The material used for the lattice body 32 is preferably a material that can sufficiently dissipate the heat generated by the LED.

  Here, for the purpose of estimation, it is assumed that the input power to the LED is 0.5 W, and half of this (0.25 W) is used for heat generation. In this case, the allowable junction temperature is 120 ° C., and the environmental temperature is 25 ° C.

At this time, if the heat from the LED is radiated from the back surface C of the lattice body 32 for simplification, the heat radiation area per LED is from the area of the back surface C (400 mm x 20 mm = 8000 mm ² ). By dividing the number (9), it is calculated to be about 8.8 × 10 ⁻⁴ [m ² ].

In addition, since the thermal resistance at this time is calculated as 1 / (8.8 × 10 ⁻⁴ × 5) = 227, the junction temperature of the LED is 25+ (0.25 × 227) = 82 ° C. It can be seen that the allowable value of 120 ° C. or less is suppressed.

  As described above, the material of the lattice body 32 is a material having an appropriate heat transfer coefficient (or heat conductivity) so that the junction temperature of the LED calculated from the input power to the LED is equal to or less than an allowable value. Can be selected.

Hereinafter, operation | movement of the control part 40 of the window-type illuminating device 100 is demonstrated.

The control unit 40 controls application of voltage to the light control plate 20 and the light source 31. Specifically, as shown in the following table, the mode (window mode, illumination mode, protection mode) of the window-type lighting device 100 is changed depending on the combination of the mode of the light control plate 20 and whether or not the light source 31 emits light. In addition, ON / OFF here has shown the case where the control part 40 applies / does not apply a voltage with respect to the light control board 20 and the light source 31, respectively.

Here, with reference to Table 1, each mode of the window-type lighting device 100 will be described.

  The “window mode” is a mode in which the window illumination device 100 functions as a normal window as described above. At this time, the control unit 40 switches the light control plate 20 to the normal mode by applying a voltage to the light control plate 20 as shown in the above table. At the same time, the transparent window illumination device 100 is realized without applying a voltage to the light source 31.

  This window mode is used, for example, during the daytime, and natural light such as sunlight can be taken into the room through the window-type lighting device 100.

  The “illumination mode” is a mode in which the window illumination device 100 functions as illumination as described above. At this time, the controller 40 switches the light control plate 20 to the diffusion mode without applying a voltage to the light control plate 20 as shown in the above table. The light source 31 is caused to emit light by applying a voltage to the light source 31. Thereby, by diffusing the light from the light source 31 in the plane of the light control plate 20, the entire surface of the light control plate 20 functions as an illumination device.

  This illumination mode is used, for example, at night, and the room is illuminated by light emission from the entire surface of the window-type illumination device 100.

  In the “protection mode”, the control unit 40 does not apply a voltage to both the light control plate 20 and the light source 31 as shown in the above table. Thereby, the light control board 20 is switched to a diffusion mode, and the light source 31 does not light-emit.

  This protection mode is used, for example, at bedtime and can be used for private protection. Further, as other usage scenes, for example, when used during the day, an effect as a awning can be expected.

  The mode of the window illumination device 100 is changed by the user selecting the operation unit 50 or the like, for example. That is, when the user selects a mode with the operation unit 50, the control unit 40 switches the mode of the window illumination device 100 by controlling the voltage application in a pattern corresponding to each mode as shown in Table 1.

(Modification)
FIG. 5 is a diagram illustrating a configuration of the window grid 60 used in the window-type lighting device 100 according to the modification of the first embodiment. 5A is a perspective view of the window grid 60, and FIG. 5B is a top view of the window grid 60. FIG.

  The window grating 60 of FIG. 5 is different from the reflecting part 32 of the first embodiment in that the reflecting part 62 provided on the side surface B of the grating body 63 has a plurality of integral convex members. As a material of the reflecting portion 62, an aluminum alloy is used because it is necessary to diffusely reflect light as in the first embodiment.

  In addition, when using the material which does not reflect light as the reflection part 62, it is also possible to coat the surface of the reflection part 62 with the material which reflects light.

  By using the reflection part 62 described above, the light from the light source 61 can be diffused over a wider range than in the case where there is one convex member. Furthermore, since the reflection part 62 has a plurality of convex members, the surface area can be reduced as compared with the case of using the reflection part 32 having one convex member or a simple reflection part (not shown). It is possible to increase the heat radiation effect of the heat from the light source 61.

  Further, a light source unit 65 having a light source 61 and leads 64 integrally is provided on the side surface A of the lattice body 63. By using this light source unit 65, manufacture becomes easier as compared with the case where the light sources 61 are individually provided on the side surface A.

  Furthermore, a heat radiating portion 66 having, for example, a plurality of fins is provided on the back surface C of the lattice main body 63. The heat radiating section 66 radiates heat generated by the light source 61 to the outside. Therefore, the heat dissipation characteristic of the window-type lighting device 100 can thereby be improved.

(Second embodiment)
FIG. 6 is a diagram showing a configuration of the window grid 70 used in the window-type lighting device 200 of the second embodiment. 6A is a perspective view of the window grid 70, and FIG. 6B is a top view of the window grid 70. FIG.

  The window illumination device 200 according to the present embodiment is different in that a diffusion unit 72 that diffuses light is provided immediately above the light source 71.

  The diffusion unit 72 is a lens that diffuses light, and for example, a convex lens as shown in FIG. 6 can be used. The diffusing portion 72 is provided so as to cover a portion directly above the light source 71 provided on the side surface A of the lattice main body 73. Thereby, the light from the light source 71 is diffused by the diffusion unit 72.

  In addition, the side surface B of the lattice body 73 is provided with a reflecting portion 77 that reflects the light diffused by the diffusing portion 72 toward the dimming plate 20 side (inside the room) of the window-type lighting device 200. The reflecting portion 77 is a plane having a predetermined angle (for example, 45 °) with respect to the side surface B of the lattice main body 73.

  By using the window grating 70 described above, the luminance distribution in the vicinity of the planar light source 71 of the light control plate 20 can be prevented, and the planar luminance distribution can be made uniform. For the same reason, the luminance can be reduced and the antiglare property can be improved.

Note that the light source here is described using an LED as an example, but a light emitting source other than an LED such as a fluorescent lamp may be used.

  Further, as an example of the arrangement of the window lattice, the arrangement in which the side surfaces A and B of the lattice main body are always aligned in one direction has been described, but the arrangement in which the side surfaces A and B of the window lattice are alternately reversed, for example, dimming It is also possible to arrange the plates so that the side surfaces A and B are reversed with respect to the center of the installation direction of the window grid.

According to the window illumination device of at least one embodiment described above, the luminance distribution in the plane of the light control plate can be made close to uniform.

  These embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 10 ... Window frame 20 ... Light control board 30, 60, 70 ... Window lattice 31, 61, 71 ... Light source 32, 62, 77 ... Reflection part 33, 63, 73 ... Lattice body 34, 64, 74 ... lead 40 ... control unit 50 ... operation unit 65 ... light source unit 66 ... heat dissipation unit 72 ... diffusion unit 100, 200 ... window-shaped illumination apparatus

Claims (5)

A planar light control member having an incident surface and an exit surface, refracting light incident from the entrance surface and exiting from the exit surface;
A lattice member provided in parallel with the light control member and having a first side surface substantially perpendicular to the light control member and a second side surface facing the first side surface;
A light source provided on the first side surface of the lattice member;
A reflecting portion provided on the second side surface for reflecting light from the light source toward the incident surface of the light control member;
A window-type lighting device.   The window-shaped illumination device according to claim 1, wherein the reflection portion is convex, and diffuses and reflects light from the light source.   The window illumination device according to claim 1, further comprising a diffusion unit that covers the light source and diffuses light from the light source. A plurality of the lattice members;
The said light control member refracts the light reflected by the said reflection part, diffuses the said light inside the said light control member by the said refraction, and makes the said output surface light-emit. The window-type lighting device of description. The light control member has a variable refractive index,
The window-type illuminating device of any one of Claims 1 thru | or 4 further provided with the control part which each controls the refractive index of the said light control member, and light emission of the said light source.