JPH0525698U - Color temperature variable lighting device - Google Patents

Abstract

(57) [Summary] [Purpose] To adjust the amount of light emitted from the light emitting portion and prevent the light control amount of each light source from exceeding 100%. [Structure] A light emitting section 4 having a plurality of light sources of different emission colors is provided. The mixing ratio setting unit 2 stores the mixing ratio required for obtaining the color temperature selected by the color selecting unit 1 for the emission color of each light source of the light emitting unit 4. The selection range limiting unit 7 selects the amount of emitted light of the light emitting unit 4 and limits the adjustment range of the color temperature according to the selected amount of emitted light.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention is a color temperature variable lighting device used in a normal living space such as a house or an office, which includes a light emitting unit having a plurality of light sources having different light emitting colors, and adjusts a mixing ratio of the light emitting colors. The present invention relates to a color temperature variable illuminating device capable of performing illumination at a desired color temperature.

[0002]

[Prior Art]

An example of this type of toning control device is to provide a light-emitting unit equipped with light sources of three colors, red, green, and blue, and adjust the brightness of each light source in the light-emitting unit to obtain light emission obtained as a mixed color. It has been considered to adjust the color temperature of the illumination light from the part. For example, as shown in FIG. 5, the light emitting section 4 is configured by light sources 11 _R , 11 _G , and 11 _B of three colors of red, green, and blue, and a color selecting section 1 for selecting an illumination color and a color selecting section. A mixing ratio setting unit 2 that stores the light amount ratios of the light sources 11 _R , 11 _G , and 11 _B required to obtain the color temperature selected in 1 is provided, and the light emitting unit is based on the output of the mixing ratio setting unit 2. The brightness of each of the four light sources 11 _R , 11 _G , and 11 _B is adjusted.

The mixing ratio setting unit 2 uses, for example, an 8-bit ROM. The color selection section 1 uses two 4-bit address setting switches AS to specify the upper 4 bits and the lower 4 bits of the mixing ratio setting section 2, respectively. The mixing ratio setting unit 2 stores the light amount ratio data required to bring the illumination color of the light emitting unit 4 to a desired color temperature. For example, the emission colors of the light sources 11 _R , 11 _G , and 11 _B are (0.5684, 0.3435), (0.3577, 0.5102), (0.1536, 0. 10 09). At this time, if the color temperature of the light emitting unit 4 is set to 5000 K, the light amount ratio of the light sources 11 _R , 11 _G , and 11 _B becomes 51: 68: 8, and if the color temperature is set to 6500 K, 46: Since it is 69:82, such light amount ratio data is stored in the mixing ratio setting unit 2.

By the way, the theoretical value of the mixing ratio is stored in the mixing ratio setting unit 2 assuming that the light emitting efficiencies of the light sources 11 _R , 11 _G , and 11 _B are equal. However, since the light sources 11 _R , 11 _G , and 11 _B generally have different light emitting efficiencies, there is a problem that a desired color temperature cannot be obtained with the output value of the mixing ratio setting unit 2. Therefore, the light emission amount correction units 12 _R , 12 _G , and 12 _B are provided for each light emission color of the light sources 11 _R , 11 _G , and 11 _B so that the correction corresponding to the light emission efficiency of each light source 11 _R , 11 _G , and 11 _B is added. It is provided. The light emission amount correction units 12 _R , 12 _G , and 12 _B corresponding to the respective light emission colors are detachably connected via connectors 13 _R , 13 _G , and 13 _B , respectively. Therefore, when the rated power or the number of the light sources 11 _R , 11 _G , and 11 _B of each emission color of the light emitting unit 4 is different, the light emission amount correction unit 12 according to the states of the light sources 11 _R , 11 _G , and 11 _B. By connecting _R , 12 _G , and 12 _B , it is possible to cope with changes in the state of the light emitting unit 4.

For example, as the light sources 11 _R , 11 _G , and 11 _B , two red fluorescent lamps that obtain a luminous flux of 560 lumens at 40 W and one green fluorescent lamp that obtains a luminous flux of 1220 lumens at 20 W, respectively. , If one blue fluorescent lamp that obtains a luminous flux of 1020 lumens at 40 W is used, if the color temperature of the illumination color from the light emitting unit 4 is set to 5000 K and the total luminous flux is set to 1500 lumens, the red light is red. Since the luminous fluxes of green, green, and blue will be 600 lumens, 800 lumens, and 100 lumens, the dimming amount for each color must be 54%, 49%, and 10%. Therefore, in the light emission amount correction units 12 _R , 12 _G , and 12 _B , the mixing ratio 51: 68: 8 stored in the mixing ratio setting unit 2 is adjusted to match the light sources 11 _R , 11 _G , and 11 _B. The light amount is converted to 54%, 49%, and 10%, and the light emission amount correction units 12 _R , 12 _G , and 12 _B may have a predetermined function table. Specifically, each of the light emission amount correction units 12 _R , 12 _G , and 12 _B is configured by a ROM, and for example, for red, the value “54” is stored in the address “51”, and the mixture is performed. The value stored at the address designated by the output value from the ratio setting unit 2 may be used as the output value.

In addition, each light source 11 of the light emitting unit 4_R, 11_G, 11_BWhen the light emission amount is changed without changing the light emission color,_R, 12_G, 12_BIt is possible to use one having a different function table. For example, the green light source 11 _G If the light flux is changed from 20W to 40W and the luminous flux is changed from 1220 lumens to 3070 lumens, the dimming amount must be changed from 49% to 26% to obtain the same color temperature. Therefore, when the light emitting unit 4 having such a configuration is used, the light emission amount correction unit 12 corresponding to green is used._GIt is possible to use the one having a function table for converting “68” into “26”. At this time, the other light emission amount correction unit 12_R, 12_BDoes not need to be changed.

The light amount ratio data corrected by the light emission amount correction units 12 _R , 12 _G , and 12 _B are input to the dimming signal generation units 9 _R , 9 _G , and 9 _B for each light emission color, and the light amount ratio data of each light emission color is obtained. A dimming signal is generated. The dimming signal output from the dimming signal generator 9 _R , 9 _G , 9 _B is input to the lighting circuit 10 _R , 10 _G , 10 _B provided for each light source 11 _R , 11 _G , 11 _B. The light sources 11 _R , 11 _G , and 11 _B of the light emitting unit 4 are dimmed to a predetermined light amount.

[0008]

[Problems to be solved by the device]

Now, let us consider a case where each of the light sources 11 _R , 11 _G , and 11 _B is configured by using two 40 W fluorescent lamps in the above configuration. Here, assuming that the light flux of each of the light sources 11 _R , 11 _G , and 11 _B is 2550 lumens, 3670 lumens, and 1100 lumens, respectively, the luminous flux of each emission color is 5100 lumens, 7340 lumens, and 2200 lumens, respectively. Become.

On the other hand, if the color temperature is 10,000 K, the mixing ratio stored in the mixing ratio setting unit 2 is 15:67:18. Therefore, set the color temperature to 10,000 K and set the total luminous flux to 10,000 lumen. Then, the dimming amount of each of the light sources 11 _R , 11 _G , and 11 _B is 29%, 91%, and 82%. If the color temperature is set to 10000K and the total luminous flux is set to 15000 lumens, the dimming amount of each of the light sources 11 _R , 11 _G and 11 _B becomes 44%, 137% and 123%. Become.

When the total luminous flux (emission light amount) is changed in this way, the dimming amount may exceed 100%. In reality, dimming exceeding 100% is not possible, so the dimming amount of each of the light sources 1 1 _R , 11 _G , and 11 _B is 44%, 100%, and 100%. Will be different. That is, there is a problem in that the user feels uncomfortable because the color temperature changes even though the amount of emitted light is changed without changing the color temperature.

Further, even when trying to continuously change the color temperature while keeping the light amount constant, if the dimming amount of each of the light sources 11 _R , 11 _G and 11 _B exceeds 100%, There is a problem in that the color temperature does not change continuously and the user feels uncomfortable. The present invention is intended to solve the above-mentioned problems, and it is possible to adjust the amount of light emitted from the light emitting unit and prevent the light intensity of each light source from exceeding 100%, thereby achieving a color temperature Another object of the present invention is to provide a variable color temperature illumination device that does not give a user an unpleasant feeling when the amount of emitted light is changed.

[0012]

[Means for Solving the Problems]

 According to the present invention, in order to achieve the above-mentioned object, a light emitting unit including a plurality of light sources having different emission colors, a color selecting unit for selecting a color temperature of light emitted from the light emitting unit, and a light source for each light source of the light emitting unit are provided. Regarding the luminescent color, the mixing ratio setting part that stores the mixing ratio required to obtain the color temperature selected in the color selection part, the amount of light emitted from the light emitting part, and the color depending on the amount of light emitted are selected. It is equipped with a selection range limiting unit that limits the selection range of temperature.

[0013]

[Action]

 According to the above configuration, the light emission amount of the light emitting unit is selected, and the selection range limiting unit that limits the selection range of the color temperature according to the selected light emission amount is provided, so that the light emission amount of the light emitting unit can be adjusted. Moreover, by limiting the selection range of the color temperature, it is possible to prevent the color temperature from being set so that the dimming amount of the light source exceeds 100%. As a result, the color temperature does not change continuously when trying to change the color temperature continuously while keeping the emitted light amount constant, or the color temperature does not change when trying to change the emitted light amount while keeping the color temperature constant. The temperature can be prevented from changing, and the user is not uncomfortable.

[0014]

【Example】

Example 1 FIG. 1 shows the basic configuration. The difference from the conventional configuration shown in FIG. 5 is that a selection range limiting unit 7 is provided. The light amount correction unit is omitted by using, as the light amount ratio data of the mixing ratio setting unit 2, data corrected so as to correspond to each light source forming the light emitting unit 4. Further, although the dimming signal generator 5 and the lighting circuit 6 are described as one, it is considered that the dimming signal generator 5 and the lighting circuit 6 are configured by the circuits for each of the light sources 11 _R , 11 _G , and 11 _B shown in FIG. It doesn't matter. Further, the light quantity ratio data stored in the mixing ratio setting section 2 is set so that the light quantity emitted from the light emitting section 4 can be adjusted in a plurality of steps for the same color temperature.

As shown in FIG. 2, the light emitting section 4 of the present embodiment is provided with one red light source 11 _R and one blue light source 11 _B and two green light sources 11 _G1 and 11 _G2. It has become. Further, each of the light sources 11 _R , 11 _G1 , 11 _G2 , and 11 _B is a fluorescent lamp of 40 W and has the same structure as the conventional one. When such a light emitting unit 4 is used, the relationship between the settable color temperature range and the total luminous flux (amount of emitted light) is as shown by the broken line in FIG. That is, when the amount of emitted light is small, the dimming range of each of the light sources 11 _R , 11 _G1 , 11 _G2 , and 11 _B can be wide, so that the setting range of the color temperature is wide, but when the amount of emitted light is large, The setting range of color temperature tends to be narrow. For example, when the total luminous flux of the light emitting unit 4 is set to 5000 lumens, the color temperature can be controlled at 2500 to 10000K, but when the total luminous flux is set to 10000 lumens, the control range of the color temperature is 5000 to 7500K. become. The relationship shown in FIG. 3 is an example, and it goes without saying that the relationship is different if the configuration of the light emitting unit 4 is different.

Based on such knowledge, in the present embodiment, the selection range limiting unit 7 is provided to select the light emission amount of the light emitting unit 4, and the color temperature in the color selecting unit 1 is selected according to the selected light emission amount. The light control amount of each of the light sources 11 _R , 11 _G1 , 11 _G2 and 11 _B does not exceed 100% by limiting the selection range. That is, in this embodiment, the color selection unit 1 is configured by the up / down counter 1a, the up switch 1b for increasing the output value of the up / down counter 1a, and the down switch 1c for decreasing the output value. In the mixing ratio setting unit 2, the light amount ratio data is arranged such that the color temperature is increased when the output value of the up-down counter 1a is increased and the color temperature is decreased when the output value of the up-down counter 1a is decreased. The selection range limiting section 7 is composed of a limitation data storage section 7a which is a ROM and a selection switch 7b which selects the limitation data to be read. The limit data is data that limits the output value of the up / down counter 1a to a predetermined range. By limiting the range of the output value of the up / down counter 1a, the light amount set in the mixing ratio setting unit 2 is limited. Limit the read range of ratio data. Further, by inputting the light emission amount data corresponding to the light emission amount selected by the selection switch 7b to the mixture ratio setting unit 2 from the limit data storage unit 7a, the light amount ratio data set in the mixture ratio setting unit 2 is obtained. , The selection is made for each data group in which the light emission amount of the light emitting unit 4 is the same. That is, in the mixing ratio setting unit 2, the address is specified by the output value of the up / down counter 1a and the light emission amount data. For example, the upper 1 bit of the address data corresponds to the light emission amount data. It is sufficient to set the quantitative ratio data.

For example, if the light emission amount of the light emitting unit 4 is configured to be selectable in four stages of 5000 lumens, 7,000 lumens, 8000 lumens, and 10,000 lumens, it is possible to select a color according to each emission light amount. The temperature selection ranges are set to 2500 to 10000K, 3200 to 9400K, 3800 to 9000K, and 5000 to 7500K, respectively. The light intensity ratio data (light adjustment data) is, for example, when the light emission amount of the light emitting unit 4 is 10,000 lumens and the color temperature is 5000K, the light adjustment amounts for red, green, and blue are 90%, 93%, and 82%. When the emitted light quantity is 8000 lumens and the color temperature is 5000K, the dimming quantity is 72%, 73% and 66%. When the emitted light quantity is 8000 lumens and the color temperature is 9000K, the dimming quantity is 41%. , 74%, 100%.

The dimming data read from the mixing ratio setting unit 2 is input to the dimming signal generating unit 5 to generate a dimming signal to be input to the lighting circuit 6, and each light source 11 _R , 1 1 _G1 , 11 _G2 and 11 _B are lit with the dimming amount indicated by the dimming signal. In this embodiment, since the selection range of the color temperature for each emitted light amount is set to the maximum controllable range, it is particularly effective when a large variable range of the color temperature is desired, but the controllable range is not always required. It is not necessary to set the maximum range. Further, for the color selection 1, it is possible to use, without using the up / down counter 1a, one for selecting the address of the mixing ratio setting unit 2 by operating the fader, a switch for generating a digital value, or the like. The light quantity ratio data may be set not by a digital value but by an analog value. Further, as the dimming signal generated from the dimming signal generating section 5, a phase control signal, a duty ratio control signal (PWM control) Etc.), analog signals, etc., and the color matching signal may be transmitted in either serial transmission or parallel transmission. Even if the lighting circuit 6 is provided for each of the light sources 11 _R , 11 _G1 , 11 _G2 , and 11 _B , one lighting circuit is provided for each of the light sources 11 _R , 11 _G1 , 11 _G2 , and 11 _B. The lighting circuit 6 may be shared. Further, depending on the configuration of the light emitting unit 4 and the configuration of the dimming signal generating unit 5, the output of the dimming signal generating unit 5 may be directly input to the light emitting unit 4 without using the lighting circuit 6. For the light sources 11 _R , 11 _G1 , 11 _G2 , and 11 _B , in addition to color fluorescent lamps, other discharge lamps are used, or a combination of a white light source and color filters, a colored light bulb, or the like is used. May be. The number of light sources forming the light emitting section 4 and the maximum output luminous flux of each light source may be appropriately set according to the purpose. When the combination of light sources is changed in this way, a light emission amount correction unit is provided as in the conventional configuration shown in FIG. 5, and the light amount ratio data set in the mixing ratio setting unit 2 is not changed and light emission is performed. If only the correction data of the quantity correction unit is changed, the work of changing the data accompanying the change of the light emitting unit 4 becomes easy. Further, the selection range limiting section 7 may be of a switching type using the selection switch 7b, or may be configured to continuously change the selection range of the color temperature.

Second Embodiment In the present embodiment, as shown in FIG. 4, the output value of the mixture ratio setting unit 2 is corrected by the light emission amount correction unit 3 as in the conventional example shown in FIG. The light emitting amount is controlled by inputting the light emitting amount data output from the selection range limiting unit 7 to the light emitting amount correcting unit 3. Therefore, in the mixing ratio setting unit 2, only the ratio of the light amount with respect to the emission color of each of the light sources 11 _R , 11 _G1 , 11 _G2 , and 11 _B forming the light emitting unit 4 is stored as the light amount ratio data. Compared to the first embodiment, the amount of data registered in the mixing ratio setting unit 2 is reduced. Further, if the correction data of the light emission amount correction unit 3 is changed, it is not necessary to change the light amount ratio data of the mixture ratio setting unit 2 as long as the light emission unit 4 has the same combination of emission colors, and it is necessary to change the data. Is less.

For example, in the mixing ratio setting section 2, the light quantity ratios of (37,61,2), (23,68,9) and (15,67,18) are respectively set for the color temperatures of 3000K, 5000K and 10000K. Assuming that the data is stored, the light sources 11 _R , 11 _G1 , 11 _G2 , and 11 _B of the light emitting unit 4 are the above-mentioned 40 W fluorescent lamps. In this case, assuming that the total luminous flux from the light emitting unit 4 is set to 8000 lumens and the color temperature is set to 50000K, the dimming amount of each of the light sources 11 _R , (11 _G1 , 11 _G2 ), and 11 _B is 72%. , 73%, 66%, and the color temperature is 9000K, the correction data of the light emission amount correction unit 3 is set so that the dimming amounts are 41%, 74%, and 100%. Other configurations are similar to those of the first embodiment.

[0021]

[Effect of the device]

 As described above, according to the present invention, the light emission amount of the light emitting unit is selected, and the selection range limiting unit that limits the selection range of the color temperature according to the selected light emission amount is provided. It is possible to adjust the color temperature, and by limiting the selection range of the color temperature, it is possible to prevent the color temperature from being set so that the dimming amount of the light source exceeds 100%. As a result, when trying to change the color temperature continuously with a constant amount of emitted light, the color temperature does not change continuously, or when trying to change the amount of emitted light with a constant color temperature. It is possible to prevent the color temperature from changing and there is an advantage that the user does not feel uncomfortable.

[Brief description of drawings]

FIG. 1 is a block diagram showing the basic configuration of the present invention.

FIG. 2 is a block diagram showing a first embodiment.

FIG. 3 is a diagram illustrating the principle of the first embodiment.

FIG. 4 is a block diagram showing a second embodiment.

FIG. 5 is a block diagram showing a conventional example.

[Explanation of symbols]

1 color selection unit 2 mixture ratio setting unit 3 light emission amount correction unit 4 light emitting unit 5 dimming signal generation unit 6 lighting circuit 7 selection range limiting unit 11 _R light source 11 _G1 light source 11 _G2 light source 11 _B light source

Claims (1)

[Scope of utility model registration request] 1. A light emitting section having a plurality of light sources of different emission colors, a color selecting section for selecting a color temperature of light emitted from the light emitting section, and a color selecting section for the emission color of each light source of the light emitting section. A mixing ratio setting unit that stores in advance the mixing ratio required to obtain the selected color temperature, and a selection that selects the amount of light emitted from the light emitting unit and limits the selection range of the color temperature according to the selected amount of emitted light. A variable color temperature illumination device comprising a range limiting section.