JP2533267B2 - Lighting equipment - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lighting device, and more particularly to an indoor lighting device.

[0002]

2. Description of the Related Art Conventionally, as a lighting device for indoor use, a lighting device of white or near-white monochromatic light has been generally used. These illuminating devices use light sources having different spectral distributions to emit light having different color temperatures depending on the device.

For example, a fluorescent lamp set to a color temperature of 6,000 to 100 degrees K emits a whitish color close to sunlight and is used in offices and study rooms. A fluorescent lamp set to a color temperature of 4,000 to 100 degrees K emits a natural color close to that of daytime natural light and is used in a living room or the like. If a light source with a lower color temperature is used, reddish light can be obtained, and a tungsten filament incandescent lamp has a color temperature of 2800 to 3100K.

Since the atmosphere of the room changes greatly depending on the color of light of the lighting device, these lighting devices are manufactured and used in various color temperatures so as to create an atmosphere according to the room used. There is. Further, the type of light source is not limited to one type for one lighting device, and for example, there is a lighting device including both an incandescent lamp and a fluorescent tube in one lighting device.

[0005]

However, according to the conventional lighting device, the color of the light is determined by the spectral distribution of the light source used. Therefore, if the color temperature of the lighting device installed in the living room is set to, for example, 4500K, in order to obtain a warm light color (light with a low color temperature) on a cold winter night, the light source bulb is set to the color temperature. Must be replaced with a low one, and the replacement work is complicated and uneconomical. In addition, in conventional lighting devices, fine color temperature
Is difficult to adjust and does not always achieve the desired color temperature.
There was a problem that it could not be done.

In view of the above points, it is an object of the present invention to provide an illuminating device which can change the color of light without the trouble of replacing the light source (light bulb etc.) of the device according to the atmosphere of the room at that time. To do.

[0007]

The above-mentioned problems can be solved by the following constitution.

That is, the illuminating device according to the present invention is configured such that the light source, the filter means having a plurality of color regions for respectively transmitting the light of the predetermined color, and the light transmission / block control can be controlled independently. And a light transmitting unit having a plurality of light transmitting regions, the light from the light source is configured to pass through the respective color regions of the light transmitting unit and the filter unit, and according to a control signal from the outside. more provided on the light transmissive means Te
Of each of the light transmission areas of the
Variable control of light transmission area by selectively setting
And, provided a control means for controlling the amount of light of each color transmitted through each color area of the light transmitting means and said filter means, and a mixing means for mixing the light transmitted through the respective color regions of said light transmitting means and said filter means It has a different configuration.

[0009]

The illumination device constructed by the above means operates as follows. The light from the light source is configured to pass through each color region of the light transmitting means and the filter means. On this occasion,
Since the filter means has a plurality of color areas that transmit light of a predetermined color, the light is color-separated by transmitting through the color areas, and in each color area, light of a predetermined color corresponding to the color of the color area is transmitted. Only transparent. Further, the light transmitting means has a plurality of light transmitting regions each of which is capable of independently controlling the transmission and blocking of light. The light transmitting means is controlled by the control means, and a control signal from the outside is controlled. Multiple light transmission areas according to
Selective for each of the regions to the light transmission state or the light blocking state
By variably controlling the light transmission area by setting it, it becomes possible to change the light amount for each color transmitted through each color region of the light transmission means and the filter means. Furthermore,
The mixing means mixes the light transmitted through the respective color regions of the light transmitting means and the filter means. Therefore, it is possible to irradiate light corresponding to the color and the light amount of each color that has passed through the light transmitting means and the filter means. In addition, as described above, the light transmission means
Select each light transmission area to the light transmission state or the light blocking state.
The light transmission area can be variably controlled by selectively setting it.
Since it is configured to control the amount of light transmission by
The amount of light of each color that passes through the color region can be precisely controlled, and light of a desired color can be easily emitted. In addition to this, each light transmission region is
It is configured to be controlled to either one of the cutoff states of
Therefore, it is possible to control digitally and control the light quantity of each color.
It can be performed stably.

[0010]

FIG. 1A is a sectional view of the first embodiment of the present invention.

In FIG. 1, the halogen bulb 1 is disposed at the inner apex of a substantially bell-shaped housing 2 having an opening 2a at the bottom of the figure, and is located inside the housing 2 and below the halogen bulb 1. Is IR (Infrared Radiation;
An ultraviolet (UV) cut filter 5 is provided, and a heat ray absorbing coating 6 is applied to the inner surface of the housing 2 so that rays other than visible rays are not emitted downward in the figure.

Below the IR cut filter 5,
For example, a liquid crystal panel 8 having color filters 7a, 7b, 7c made of gelatin formed on its upper surface is provided. Each color filter is a primary color filter. The color filter 7a is colored red (R; Red), the color filter 7b is colored green (G; Green), and the color filter 7c is colored blue (B; Blue). The liquid crystal panel 8 has a matrix structure described later, and is driven by an output control signal b from the control circuit 3 to change the transmittance of a predetermined part.

A diffused light reflection film 9 is provided in the opening 2a of the housing 2, and the light from the halogen bulb 1 emitted from the opening 2a is diffusely reflected by the light and is emitted below the housing 2.

FIG. 1B is a plan view schematically showing a liquid crystal panel 8 which is a main part of the first embodiment of the present invention shown in FIG. In the figure, the operation will be described assuming that the liquid crystal panel 8 has a matrix structure of vertical 10 (dots) × horizontal 15 (dots). The liquid crystal panel 8 actually used has a vertical length of 128 (dots) x a horizontal length of 256 (dots), a dot pitch of 0.47 (mm) x 0.47 (mm), a vertical dimension of 70 (mm) x a horizontal dimension of 127 (dots). mm) is a general-purpose product.

In FIG. 1 (B), the coordinates of the matrix of the liquid crystal panel 8 are x coordinates (1) to (15) and y coordinates I as shown.
~ X. At this time, a color filter 7 that selectively transmits red light on the upper surface of the region represented by the x coordinate (1) to (5) on the left side ⅓ of the vertical 10 (dots) × horizontal 15 (dots) in the figure.
a is a color filter 7b that selectively transmits green light on the upper surface of the region represented by the x-coordinates (6) to (10) of the central part 1/3 in the figure,
Color filters 7c that selectively transmit blue light are formed on the upper surfaces of the regions represented by the x coordinates (11) to (15) on the right side ⅓ in the drawing.

The liquid crystal panel 8 having the above-mentioned structure is driven and controlled by the control circuit shown in FIG. 2 together with the halogen bulb 1, and a predetermined dot among the dots transmits (hereinafter referred to as ON) or blocks (hereinafter, referred to as ON) light. The amount of light transmitted through the liquid crystal panel 8 is variably controlled.

In FIG. 2, the microcomputer 13
Is a general configuration having a CPU (Central Processing Unit), a read-only memory ROM (Read Only Memory), a readable / writable memory RAM (Random Access Memory), a bus line, an input / output port, etc., which are not shown.

The A / D conversion circuit 11 has a DC voltage V ₁ (input control signal a) obtained by dividing the power supply voltage V _CC by the variable resistor R.
Is input, and this DC input voltage V ₁ is applied to the A / D conversion circuit 1
1 is supplied to the microcomputer 13 as a binary signal D ₁ corresponding to the level. The output resistance value of the variable resistor R is configured to be variable according to the rotation angle of a first knob (not shown), and the first knob is used when the brightness of the lighting device is changed.

Further, input DC voltages V ₂ and V ₃ (input control signal a), which are respectively generated according to the rotation angles of the second and third knobs (not shown), are input to the input interface circuit 12. Input interface circuit 1
2 generates a binary signal D ₁ according to these input DC voltages and supplies it to the microcomputer 13.

The second knob is used when it is desired to specify and change the color of light of the device, and the scale is marked from "red" to "purple". The third knob is used according to the mood of a person, and is marked on the scale as, for example, "carefree", "tension", or the like. Thereby, the light color of the device is configured to be a color according to the mood specified by the scale.

That is, the microcomputer 13 is R
According to the program stored in the OM, the input signal D ₁ ,
The X drive is performed such that the ON / OFF of each of the plurality of dots (light-transmitting regions) of the liquid crystal panel 8 which is the light-transmitting means is independently controlled according to D ₂ to vary the light-transmitting area of the region in which each color filter is formed. The liquid crystal panel 8 is driven and controlled by the circuit 14 and the Y drive circuit 15. In this way, the microcomputer
Switch 13 turns individual dots on (transmission of light) or
Is a binary digital control of the off state (light blocking state).
Therefore, compared to analog control, the environment where the lighting device is placed (temperature
It is possible to perform stable light intensity control that is not easily affected by
it can.

As a result, the light from the halogen bulb 1 which is illuminated by the lighting circuit 16 and emits light is filtered by each color filter 7a.
.About.7c (each constituting a color region), the transmission amounts of the red, green, and blue color lights selectively generated and transmitted are variably controlled.
More specifically, the color filters 7a-
There are a plurality of dots corresponding to each of 7c. Therefore, for example, if one color filter 7a is taken as an example, as shown in FIG.
(Dots × vertical 10) correspond to each other, and the 50 dots corresponding to the filter 7a can be turned on / off independently, so that the light transmission area can be changed , and the amount of light transmitted through the color filter 7a (that is, , The amount of red light) can be accurately controlled. As a result, the mixing ratio of the lights of the three primary colors is changed, and the light precisely controlled to the desired brightness and color designated by each knob can be emitted downward from the diffused reflection film 9.

For example, by turning the first knob, each dot in each area of the liquid crystal panel 8 in which each color filter is formed is turned off at a constant rate in each area as shown in black in FIG. 1 (B). In the end, the total amount of light transmitted through the liquid crystal panel 8 is reduced while keeping the mixing ratio of each color light constant.
As a result, in the case shown in the figure, the color of the light of the halogen bulb 1 is set to about 4/5 as it is.

When "red" is designated by the second knob, the x coordinate of each dot of the liquid crystal panel 8 is changed from (1).
Each dot up to (5) is turned on and transmits light, and the x coordinate is
The dots from (6) to (15) are turned off to block the light.
As a result, the color filter 7 of the visible light of the halogen bulb 1
Only the red light selectively transmitted by a is emitted from the liquid crystal panel 8 and the diffused reflection film 9, respectively.

The microcomputer 13 is further programmed to variously control the ON / OFF of each dot of the liquid crystal panel 8 according to the input signal D ₂ to obtain light of various colors obtained by combining the light of the three primary colors. ing.

For example, the liquid crystal panel is controlled by the X drive circuit 14 and the Y drive circuit 15 so that all the dots whose x coordinates are (1) to (5) are turned off to block blue light and transmit red and green light. If 8 is driven and controlled, yellow light can be obtained, and x
If the liquid crystal panel 8 is driven and controlled by the X drive circuit 14 and the Y drive circuit 15 so that all the dots having coordinates (11) to (15) are turned off to block the red light and transmit the blue and green lights. Cyan light is obtained.

Not limited to this, various colors of light can be obtained,
When the 3rd knob is set to “Relax”, light of a color that relaxes and relaxes the nerves of a person, for example, orange light is obtained, and when set to “Tension”, the color of a tone that tensions the nerves of a person is obtained. A microcomputer 13 for changing the mixing ratio of the three primary color lights so that light, for example, blue-green light is obtained.
Is programmed.

The diffuse reflection film 9 diffuses and mixes each color light so that three shades are not formed by the red, green and blue color lights selectively transmitted through each color filter. For example, the liquid crystal filter 8 is used. It is also possible to obtain a similar effect by applying a coating that causes diffused reflection inside the housing 2 between the opening 2a and the opening 2a. Further, the heat ray absorbing coating 6 is provided on the inside of the housing 2 and in the vicinity of the halogen bulb 1, and at the same time,
It is also conceivable to perform processing that diffusely reflects light from the.

FIG. 3 is a plan view schematically showing a modified example of the color filter which is the essential part of the first embodiment of the present invention.

The color filter 17 shown in FIG. 3A has a red color filter R and a green color filter in a total of 36 vertical and horizontal areas obtained by dividing a 128 (dots) × 256 (dots) area of the liquid crystal panel 8 into six equal parts. In this configuration, the color filters G and the blue filters B are alternately arranged.

In the color filter 18 shown in FIG. 3B, a red color filter R and a green color filter G are provided in twelve triangular regions with twelve radiations having the radiation center at the center point of the liquid crystal panel 8 as boundaries. The blue color filters B are alternately arranged.

By constructing the color filters as described above, it is possible to make it more difficult to form the three shadows of the red, green and blue lights. At this time, it is desirable to subdivide each color area of the color filter as much as possible.

FIG. 4 is a schematic configuration diagram of the second embodiment of the present invention. In FIG. 4, the halogen bulbs 22 and 2 are provided inside the three substantially bell-shaped housings 19, 20 and 21, respectively.
3, 24 are provided, and the opening 19 of each housing is provided.
In front of a, 20a, 21a, a red color filter 25,
A liquid crystal panel 8 provided with a green color filter 26 and a blue color filter 27 is arranged.

The light from each halogen bulb is selectively transmitted through the bands corresponding to the respective color filters 25, 26 and 27, and then the liquid crystal panel 8 is controlled to turn on / off the respective parts formed in a matrix by a control circuit (not shown). Through. The red light λ _R transmitted through the red color filter 25 and the liquid crystal panel 8 is reflected by the reflecting mirror 29, then by the half beam splitter 30, and further passes through the half beam splitter 31.

The green light λ _G transmitted through the green color filter 26 and the liquid crystal panel 8 is transmitted through the half beam splitters 30 and 31. The blue light λ _B transmitted through the blue color filter 27 and the liquid crystal panel 8 is reflected by the reflecting mirror 32 and then by the half beam splitter 31. In the present embodiment, the respective colored lights λ _R , λ _G , λ _B obtained by selectively transmitting the light from the halogen bulbs 22, 23, 24 with the respective color filters.
Are thus combined on the same optical axis by the half beam splitters 30 and 31. Therefore, three shadows do not occur.

Also in the present embodiment, the liquid crystal panel 8 is on / off controlled as described above, and the three primary color lights are combined at a predetermined ratio in accordance with the input signal of the microcomputer not shown in FIG. 4 to obtain a desired color. Of course, light can be obtained.

[0037]

As described above, according to the present invention, since the plurality of light transmitting areas forming the light transmitting means are configured so that the light transmission amount can be controlled independently of each other, the light is transmitted through each color area. It is possible to control the amount of light for each color to be performed, and thus it is possible to precisely control the amount of light for each color that passes through the color region.
It is possible to easily generate and irradiate light of a desired color and light amount. In addition, each light transmission region is in the light transmission state or
The configuration is such that either one of the light blocking states is controlled.
Therefore, it is possible to control digitally and control the light quantity of each color.
Can be performed stably.

[Brief description of drawings]

FIG. 1 is a cross-sectional view and a plan view of an essential part of a first embodiment of the present invention.

FIG. 2 is a block diagram of a control circuit according to the first embodiment of the present invention.

FIG. 3 is a plan view of a modified example of the main part of the first embodiment of the present invention.

FIG. 4 is a schematic configuration diagram of a second embodiment of the present invention.

[Explanation of symbols]

1,2,23,24 Halogen bulb (light source) 3 Control circuit (control means) 7a, 7b, 7c, 17,18,25,26,27 Color filter (filter means) 8 Liquid crystal panel (light transmission means) 9 Light Diffuse reflection film (mixing means) 13 Microcomputer 29,32 Reflecting mirror (mixing means) 30,31 Half beam splitter (mixing means)

Claims (1)

(57) [Claims] 1. A light source, a filter means having a plurality of color areas for transmitting light of a predetermined color respectively, and a plurality of light transmitting areas configured to independently control transmission and blocking of light. A light transmitting means having the light transmitting means, wherein light from the light source is transmitted through each color region of the light transmitting means and the filter means, and the light transmitting means is provided to the light transmitting means according to a control signal from the outside. The light transmission state or light
The light transmission area can be set by selectively setting the
Control means for variably controlling and controlling the amount of light of each color transmitted through each color area of the light transmission means and the filter means, and mixing means for mixing light transmitted through each color area of the light transmission means and the filter means. A lighting device comprising: