JP6998540B2 - lighting equipment - Google Patents

Description

The present invention relates to a lighting fixture.

Conventionally, a lighting fixture having a function (so-called toning function) capable of changing the light color of the illumination light according to the purpose of use or the usage situation is known (see, for example, Patent Document 1).

Conventional lighting fixtures having a color matching function include, for example, a light emitting module having two light emitting parts having different light colors from each other, and a power supply circuit capable of independently controlling the light output of the two light emitting parts of the light emitting module. It is equipped with. In such a luminaire, the color of the illuminating light can be adjusted by controlling the light output ratios of the two light emitting units with a power supply circuit.

Japanese Unexamined Patent Publication No. 2009-110781

However, when the illumination light is toned using two light emitting units having different light colors, the toning can be performed only on the straight line connecting the two chromaticity points on the chromaticity diagram. For example, when the emission colors of the two light emitting units are neutral white and light bulb color, the chromaticity on a straight line connecting the two points of the chromaticity point indicating neutral white and the chromaticity point indicating the light bulb color on the chromaticity diagram. You can only change the color of the illumination light.

For this reason, in the toning by the two light emitting parts having different light colors, a color shift occurs between the light emitting part and the blackbody locus, and the light color of the illumination light cannot be changed so as to trace the blackbody locus. It is difficult to reproduce white light that satisfies the entire trajectory.

Therefore, it is conceivable to adjust the color of the illumination light using three light emitting parts with different light colors, but if the light outputs of the three light emitting parts are independently controlled by the power supply circuit, the power supply circuit becomes complicated or the power supply is supplied. The cost of the circuit becomes high.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a luminaire capable of reproducing a color with a light color close to a blackbody locus by using a low-cost power supply circuit. And.

In order to achieve the above object, one aspect of the lighting equipment according to the present invention includes a light emitting module and a power supply circuit that outputs a current for causing the light emitting module to emit light to the light emitting module. It has three or more light emitting units having different light colors of emitted light and a current control circuit, and the three or more light emitting units are provided on different current paths, and the light emitting module is provided from the power supply circuit. The number of outputs of the power supplied to the current control circuit is smaller than the number of the three or more light emitting units, and the current control circuit is based on the current output ratio according to the amount of current supplied from the power supply circuit to the current control circuit. The current is supplied to a plurality of light emitting units connected to the current control circuit among the three or more light emitting units.

According to the present invention, it is possible to reproduce a color with a light color close to a blackbody locus by using a low-cost power supply circuit.

It is a figure which shows typically the installation example of the lighting fixture which concerns on Embodiment 1. FIG. It is a figure which shows the circuit structure of the lighting fixture which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the light emitting module in the luminaire which concerns on Embodiment 1. FIG. It is a figure which shows the circuit structure of the luminaire of the comparative example 1. FIG. FIG. 5 is an xy chromaticity diagram showing a change in the light color of the illumination light due to toning control between the luminaire according to the first embodiment and the luminaire of Comparative Example 1. It is a figure which shows the flow of the electric current at the time of performing the color adjustment control (the color adjustment control at the chromaticity point P1) of the lighting equipment which concerns on Embodiment _1. FIG. It is a figure which shows the flow of the electric current at the time of performing the color adjustment control (the color adjustment control at the chromaticity points P1 to P2) of the lighting equipment which concerns on Embodiment _{1. FIG} . It is a figure which shows the flow of the electric current at the time of performing the color adjustment control ₍ the color adjustment control at the chromaticity points _P3 to P4) of the lighting equipment which concerns on Embodiment 1. FIG. It is a figure which shows the flow of the electric current at the time of performing the color adjustment control (the color adjustment control at the chromaticity _{points P4} to P5) of the lighting equipment which concerns on Embodiment 1. FIG. It is a figure which shows the circuit structure of the lighting fixture which concerns on Embodiment 2. FIG. FIG. 5 is an xy chromaticity diagram showing a change in the light color of the illumination light due to toning control between the luminaire according to the second embodiment and the luminaire of Comparative Example 2. It is a figure which shows the circuit structure of the lighting fixture which concerns on Embodiment 3. FIG. FIG. 5 is an xy chromaticity diagram showing a change in the light color of the illumination light due to toning control between the luminaire according to the third embodiment and the luminaire of Comparative Example 3. It is a figure which shows the structure of the light emitting module which concerns on the modification.

Hereinafter, embodiments of the present invention will be described. In addition, all of the embodiments described below show a preferable specific example of the present invention. Therefore, the numerical values, shapes, materials, components, the arrangement positions of the components, the connection form, and the like shown in the following embodiments are examples and are not intended to limit the present invention. Therefore, among the components in the following embodiments, the components not described in the independent claims indicating the highest level concept of the present invention will be described as arbitrary components.

Further, each figure is a schematic view and is not necessarily exactly illustrated. Therefore, the scales and the like do not always match in each figure. In each figure, substantially the same configuration is designated by the same reference numeral, and duplicate description will be omitted or simplified.

(Embodiment 1)
First, the configuration of the lighting fixture 1 according to the first embodiment will be described with reference to FIGS. 1 to 3. FIG. 1 is a diagram schematically showing an installation example of the lighting fixture 1 according to the first embodiment. FIG. 2 is a diagram showing a circuit configuration of the lighting fixture 1. FIG. 3 is a diagram showing the configuration of the light emitting module 100 in the lighting fixture 1.

As shown in FIG. 1, the luminaire 1 in the present embodiment is a downlight that irradiates the illuminating light downward (floor or the like), and is installed on the ceiling 2 of the building. For example, the lighting fixture 1 is embedded and arranged in the ceiling 2.

As shown in FIG. 1, the luminaire 1 includes a lamp unit 10 having a light emitting module 100 and a power supply unit 20 having a power supply circuit 200. For example, the lamp unit 10 is embedded and arranged in the opening 2a of the ceiling 2, and the power supply unit 20 is arranged on the back surface (behind the ceiling) of the ceiling 2. The opening 2a of the ceiling 2 is a mounting hole for mounting the lamp unit 10 to the ceiling 2, and is, for example, a through hole of a circular opening penetrating the ceiling 2.

The lamp unit 10 has, for example, a base 11 and a frame body 12 fixed to the front of the base 11. The light emitting module 100 is attached to the base 11. The base 11 is made of a metal material such as aluminum, and not only functions as a mounting portion of the light emitting module 100, but also functions as a heat sink that dissipates heat generated by the light emitting module 100. The frame body 12 is attached to the opening 2a of the ceiling 2 by a leaf spring or the like.

The light emitting module 100 emits illumination light of a predetermined color. For example, the light emitting module 100 emits white light as illumination light. As shown in FIG. 2, the light emitting module 100 includes a plurality of light emitting units 110 that emit light of a predetermined color. In the present embodiment, the light emitting module 100 is an LED module, and the light emitting unit 110, which is a light source, is composed of LEDs.

The light emitting module 100 has a plurality of light emitting units 110 whose light colors are different from each other. The plurality of light emitting units 110 is three or more. In the present embodiment, the light emitting module 100 is lower than the color temperature (first color temperature) of the first light emitting unit 111 that emits light having the first color temperature and the light emitted by the first light emitting unit 111. It is composed of three light emitting units 110, that is, a second light emitting unit 112 that emits light having a second color temperature, which is a color temperature, and a third light emitting unit 113 that emits red light. As an example, the first light emitting unit 111 emits white light having a color temperature of 6200 K (first color temperature), and the second light emitting unit 112 emits white light having a color temperature of 2200 K (second color temperature). The third light emitting unit 113 emits red monochromatic light having a peak wavelength in the range of 620 nm to 700 nm, and its color temperature (third color temperature) is about 1800 K.

The first light emitting unit 111 is composed of a plurality of LED elements 111a (first LED elements) connected in series. Specifically, the first light emitting unit 111 is a series connection body in which six LED elements 111a are connected in series. The six LED elements 111a have the same configuration and characteristics (IF-VF characteristics, etc.). Therefore, the color temperature of the light of the six LED elements 111a is 6200K. The number of LED elements 111a constituting the first light emitting unit 111 is not limited to six, and may be one or a plurality of LED elements 111a other than six.

The second light emitting unit 112 is composed of a plurality of LED elements 112a (second LED elements) connected in series. Specifically, the second light emitting unit 112 is a series connection body in which five LED elements 112a are connected in series. The five LED elements 112a have the same configuration and characteristics (IF-VF characteristics, etc.). Therefore, the color temperature of the light of the five LED elements 112a is 2200K. The number of LED elements 112a constituting the second light emitting unit 112 is not limited to five, and may be one or a plurality of LED elements 112a other than five.

The third light emitting unit 113 is composed of a plurality of LED elements 113a (third LED elements) connected in series. Specifically, the third light emitting unit 113 is a series connection body in which two LED elements 113a are connected in series. The two LED elements 113a have the same configuration and characteristics (IF-VF characteristics, etc.). Therefore, the light color of the light of the two LED elements 113a is red. The number of LED elements 113a constituting the third light emitting unit 113 is not limited to two, and may be one or a plurality of LED elements 113a other than two.

The first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 are provided on different current paths. That is, the LED element 111a constituting the first light emitting unit 111, the LED element 112a constituting the second light emitting unit 112, and the LED element 113a constituting the third light emitting unit 113 are not connected in series. .. In the present embodiment, the LED element 112a constituting the second light emitting unit 112 and the LED element 113a constituting the third light emitting unit 113 are connected in parallel.

Further, assuming that the total amount of forward voltage of the plurality of LED elements connected in series in each light emitting unit 110 is the total Vf (total Vf), in the present embodiment, the value of the total Vf of the element row of each light emitting unit 110 is It depends on the number of LED elements of each light emitting unit 110. Therefore, the total Vf of the first light emitting unit 111 composed of the six LED elements 111a is set to TVf1, and the total Vf of the second light emitting unit 112 composed of the five LED elements 112a is set to TVf2. Assuming that the total Vf of the third light emitting unit 113 including TVf3 is TVf3, TVf1> TVf2> TVf3.

The light emitting module 100 further includes a current control circuit 120 in addition to the light emitting unit 110 (first light emitting unit 111, second light emitting unit 112, third light emitting unit 113).

The current control circuit 120 is connected to the current control circuit 120 among the plurality of light emitting units 110 in the light emitting module 100 based on the current output ratio according to the amount of current supplied from the power supply circuit 200 to the current control circuit 120. A current is supplied to the light emitting unit 110 of. The current control circuit 120 includes a current detection circuit that detects the amount of current supplied from the power supply circuit 200 to the current control circuit 120.

In the present embodiment, the current control circuit 120 is connected to the second light emitting unit 112 and the third light emitting unit 113, and the input current supplied to the current control circuit 120 is transferred to the second light emitting unit 112 and the third light emitting unit 112. It is distributed and supplied to the light emitting unit 113 of 3. In this case, the current control circuit 120 detects the current amount (current value) of the input current input from the power supply circuit 200 to the current control circuit 120. Then, the current output ratio (distribution ratio) of the input current for distribution to the second light emitting unit 112 and the third light emitting unit 113 is determined according to the detected current amount, and the current control circuit 120 determines this current output. A current is shunted between the second light emitting unit 112 and the third light emitting unit 113 by the amount of current based on the ratio.

Further, when the current control circuit 120 divides the current into the plurality of light emitting units 110 connected to the current control circuit 120, the total amount of forward voltage among the plurality of light emitting units 110 connected to the current control circuit 120 is small. A current is passed in preference to the light emitting unit 110. Therefore, the current control circuit 120 starts to flow a current from the light emitting unit 110 having a small total amount of forward voltage, and when the amount of current supplied from the power supply circuit 200 to the current control circuit 120 increases, the other light emitting unit 110 The current is also divided.

In the present embodiment, the second light emitting unit 112 and the third light emitting unit 113 are connected to the current control circuit 120, and the total amount of forward voltage is the third light emitting unit than the second light emitting unit 112. The part 113 is smaller. Therefore, the current control circuit 120 first starts to flow a current only to the third light emitting unit 113, which has a smaller total amount of forward voltage than the second light emitting unit 112, and is supplied from the power supply circuit 200 to the current control circuit 120. As the amount of current increases, the amount of current diverted to the third light emitting unit 113 is increased. Then, when the amount of current supplied from the power supply circuit 200 to the current control circuit 120 becomes larger and the current flowing through the third light emitting unit 113 becomes maximum, the current control circuit 120 also causes a current to the second light emitting unit 112. Is started to flow, and the amount of current shunted to the second light emitting unit 112 is increased.

The light emitting module 100 configured in this way has, for example, the structure shown in FIG. Specifically, the light emitting module 100 has a substrate 130, and has a plurality of light emitting units 110 (first light emitting unit 111, second light emitting unit 112, third light emitting unit 113) and a current control circuit 120. Is provided on the substrate 130.

In the present embodiment, the third light emitting unit 113 is arranged in the central portion of the substrate 130. Specifically, the two LEDs 113a constituting the third light emitting unit 113 are arranged side by side in the central portion of the substrate 130.

Further, the second light emitting unit 112 is divided into a plurality of parts, and the third light emitting unit 113 is arranged between one and the other of the plurality of second light emitting units 112. Specifically, the LED element 112a constituting the second light emitting unit 112 is divided into two regions via the third light emitting unit (LED element 113a) and arranged, and the third light emitting unit 113 is arranged. The constituent LED element 113a is arranged between the LED element 112a arranged in one area and the LED element 112a arranged in the other area.

Further, the first light emitting unit 111 is arranged between the second light emitting unit 112 and the third light emitting unit 113. Specifically, the LED element 111a constituting the first light emitting unit 111 is arranged between the LED element 112a constituting the second light emitting unit 112 and the LED element 113a constituting the third light emitting unit 113. Has been done.

By arranging the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 in this way, the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 can be arranged. The light emitted from each can be mixed uniformly. In particular, when the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 are synchronized toning control as described later, the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 are controlled. One or more of these light emitting units 113 emit light, but the colors can be uniformly mixed in any of the brightnesses.

In the present embodiment, the LED element 111a constituting the first light emitting unit 111, the LED element 112a constituting the second light emitting unit 112, and the LED element 113a constituting the third light emitting unit 113 are individually packaged. It is a surface mount (SMD: Surface Mount Device) type LED element.

Specifically, each of the LED elements 111a, 112a and 113a includes a white resin package (container) having a recess, and one or more LED chips (bare chips) primarily mounted on the bottom surface of the recess of the package. It has a sealing member enclosed in a recess of the package. The sealing member is made of a translucent resin material such as a silicone resin.

The LED chip is an example of a semiconductor light emitting device that emits light by a predetermined DC power, and is a bare chip that emits visible light of a single color. In this case, the LED chips in the LED elements 111a and 112a are, for example, blue LED chips that emit blue light when energized, and have a peak wavelength in the range of, for example, 440 nm to 470 nm. In the LED elements 111a and 112a, in order to obtain white light, the sealing member is provided with a yellow phosphor such as YAG (yttrium aluminum garnet) that fluoresces with the blue light from the blue LED chip as excitation light. It is contained. In the LED elements 111a and 112a, a part of the blue light of the blue LED chip is absorbed by the yellow phosphor, the yellow phosphor is excited, and the yellow light is emitted from the yellow phosphor, which is absorbed by the yellow light and the yellow phosphor. White light is generated by mixing with the blue light that was not emitted.

However, the first light emitting unit 111 emits light having a color temperature higher than the color temperature of the light emitted by the second light emitting unit 112. Therefore, in order to make the color temperature of the light emitted by the first light emitting unit 111 higher than the color temperature of the light emitted by the second light emitting unit 112, the type of phosphor contained in the sealing member (for example, red fluorescence). The chromaticity of the first light emitting unit 111 and the second light emitting unit 112 is adjusted by adjusting the body, the green phosphor, and the blue phosphor) and the amount.

On the other hand, the LED chip in the LED element 113a is a red LED chip that emits red light when energized, and has a peak wavelength in the range of, for example, 620 nm to 700 nm. Since the LED element 113a takes out the red light of the red LED chip as it is, the sealing member does not contain a phosphor.

The LED elements 111a, 112a and 113a configured in this way are mounted on the substrate 130 by, for example, soldering.

Further, the current control circuit 120 is configured as an IC package having a plurality of lead terminals, and is mounted on the substrate 130 by, for example, soldering.

The substrate 130 is a printed wiring board on which metal wiring (not shown) is formed, and a predetermined pattern of metal wiring is formed on the surface of the substrate 130. The LED elements 111a, 112a and 113a and the current control circuit 120 are solder-connected to the metal wiring formed on the substrate 130. The LED elements 111a, 112a and 113a and the current control circuit 120 are electrically connected by the metal wiring in the circuit configuration shown in FIG.

Examples of the substrate 130 include a resin substrate made of an insulating resin material, a metal base substrate made of a metal material whose surface is coated with a resin, a ceramic substrate which is a sintered body of a ceramic material, a glass substrate made of a glass material, and the like. Can be used. Further, when the wiring path between the LED elements 111a, 112a and 113a and the current control circuit 120 becomes complicated, by using a multilayer board as the board 130, these electrical connections can be easily performed.

The substrate 130 is not limited to a rigid substrate, and may be a flexible substrate. Further, a resist film may be formed on the surface of the substrate 130 as an insulating film so as to cover the metal wiring.

Further, the substrate 130 is provided with a plurality of input terminals 131 electrically connected to the electric wire 30 led out from the power supply circuit 200. In the present embodiment, the plurality of input terminals 131 are composed of a first input terminal 131a, a second input terminal 131b, and a third input terminal 131c.

The current (input current) input from the power supply circuit 200 to the light emitting module 100 passes through the first input terminal 131a and the second input terminal 131b. On the other hand, the current (output current) output from the light emitting module 100 to the power supply circuit 200 passes through the third input terminal 131c.

Returning to FIG. 1, the power supply unit 20 includes a housing 21, a circuit board 22 housed in the housing 21, a plurality of circuit elements 23 mounted on the circuit board 22, and an AC power supply 3 (for example, a commercial power supply). It is provided with a terminal block 24 that receives AC power from. The housing 21 is a case made of metal or an insulating resin. The circuit board 22 is a printed wiring board on which metal wiring is formed. The terminal block 24 receives, for example, an AC voltage of AC100V as an input voltage. The AC voltage received by the terminal block 24 is supplied to the power supply circuit 200.

The power supply circuit 200 is composed of a plurality of circuit elements 23. The plurality of circuit elements 23 include, for example, a capacitive element (electrolytic capacitor, ceramic capacitor, etc.), a resistance element (resistor, etc.), a rectifying circuit element, a coil element, a transformer, a noise filter, a diode, an integrated circuit element (IC), or an integrated circuit element (IC). , Semiconductor elements (FET, etc.), etc.

The power supply circuit 200 generates electric power for causing the light emitting module 100 to emit light based on an input voltage from an external power source, and outputs the generated electric power to the light emitting module 100. Further, the power supply circuit 200 has a power supply function for generating electric power for causing the light emitting module 100 to emit light, and also has a lighting control function for controlling the lighting mode of the light emitting module 100. Specifically, the power supply circuit 200 has a dimming function for changing the brightness of the illumination light of the light emitting module 100 and a toning function for changing the light color of the illumination light of the light emitting module 100 as a lighting control function.

In the present embodiment, the power supply circuit 200 has a synchro toning function that changes the brightness of the light emitting module 100 and the light color in conjunction with each other. For example, when the brightness of the light emitting module 100 is increased, the light changes to a light having a high color temperature, and when the brightness of the light emitting module 100 is reduced to a small value, the light changes to a light having a low color temperature. As a result, it is possible to realize illumination light that changes to a brightness and light color that is comfortable for humans.

In this case, the synchro toning of the light emitting module 100 can be controlled by the dimming switch 4. The dimming switch 4 is installed, for example, on a wall or the like, and is provided on a wiring path between the AC power supply 3 and the power supply circuit 200 (terminal block 24). The dimmer switch 4 is, for example, a phase control type dimmer (two-wire type dimmer) that controls the phase of an AC voltage. In this case, the phase angle (conduction angle) of the AC voltage supplied from the AC power supply 3 is controlled by the dimming switch 4, so that the input current to the light emitting module 100 changes. Specifically, the power supply circuit 200 generates an input current corresponding to the AC voltage controlled by the dimming switch 4. In this way, by adjusting the brightness of the light emitting module 100 with the dimming switch 4, the light color of the light emitting module 100 can also be adjusted. The dimming switch 4 includes, for example, an operation unit such as a slider or a knob that can be operated by the user, and the phase angle (conduction angle) is controlled according to the operation of the operation unit by the user.

In the present embodiment, the power supply circuit 200 is a two-circuit control power supply, and outputs two input powers to the light emitting module 100 as electric power for causing the light emitting unit 110 of the light emitting module 100 to emit light. Specifically, the power supply circuit 200 supplies two input powers to the light emitting module 100 having the three light emitting units 110 of the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113. It is outputting. As described above, the number of outputs of electric power supplied from the power supply circuit 200 to the light emitting module 100 is smaller than the number of light emitting units 110 (three in the present embodiment). That is, the number of power supply circuits in the power supply circuit 200 is smaller than the number of emission colors of the light emitting unit 110 (that is, the number of light source colors).

The two input powers output from the power supply circuit 200 to the light emitting module 100 can be independently controlled by the power supply circuit 200. Specifically, two DC powers independently controlled as drive currents for causing the light emitting unit 110 of the light emitting module 100 to emit light are supplied from the power supply circuit 200 to the light emitting module 100 as input currents. In the present embodiment, two input currents output from the power supply circuit 200 to the light emitting module 100 are supplied to the first light emitting unit 111 and the other to the current control circuit 120.

The power supply unit 20 and the lamp unit 10 are connected by an electric wire 30. Therefore, the DC power generated by the power supply circuit 200 of the power supply unit 20 is supplied to the light emitting module 100 of the lamp unit 10 via the electric wire 30. Specifically, a current corresponding to the dimming control by the dimming switch 4 is generated in the power supply circuit 200, and the generated current is emitted from the power supply circuit 200 via the electric wire 30 as an input current to the light emitting module 100. It is supplied to the module 100. The electric wire 30 is a power line such as a power cable.

In the present embodiment, the power supply circuit 200 outputs DC power to the first light emitting unit 111 and the current control circuit 120, so that the input current input from the power supply circuit 200 to the light emitting module 100 flows through the electric wire 30. There are a total of three power lines, two power lines and one power line through which the output current output from the light emitting module 100 to the power supply circuit 200 flows.

Next, the toning control of the luminaire 1 according to the first embodiment will be described with reference to FIGS. 4 to 6D in comparison with the toning control of the luminaire 1X of Comparative Example 1. FIG. 4 is a diagram showing a circuit configuration of the lighting fixture 1X of Comparative Example 1. FIG. 5 is an xy chromaticity diagram showing a change in the light color of the illumination light due to toning control between the luminaire 1 according to the first embodiment and the luminaire 1X of the comparative example 1. 6A to 6D are diagrams showing a current flow when color matching control of the lighting fixture 1 according to the first embodiment is performed.

As shown in FIG. 4, the luminaire 1X of Comparative Example 1 has a light emitting module 100X having a first light emitting unit 111 that emits light having a color temperature of 6200 K and a second light emitting unit 112 that emits light having a color temperature of 2200 K. And a power supply circuit 200. In the luminaire 1X of Comparative Example 1, the illumination light of the luminaire 1X can be adjusted by controlling the light output ratios of the first light emitting unit 111 and the second light emitting unit 112 by the power supply circuit 200.

However, in the luminaire 1X of Comparative Example 1, as shown by the broken line in FIG. 5, the adjustment is performed only on the straight line connecting the two points of the chromaticity point P1 corresponding to _6200K and the chromaticity point _PX5 corresponding to 2200K. Can't do color. That is, the color temperature of the illumination light can be changed only by the chromaticity on the straight line connecting the _two points of the chromaticity point P1 and the chromaticity point _PX5 .

Therefore, in the luminaire 1 of Comparative Example 1, a color shift occurs between the luminaire 1 and the blackbody locus shown by the curve of FIG. 5, and the color temperature of the illumination light cannot be changed so as to trace the blackbody locus. , It is difficult to reproduce white light that satisfies the entire blackbody trajectory.

On the other hand, in the light emitting module 100 of the lighting fixture 1 in the present embodiment, the first light emitting unit 111 that emits light having a color temperature of 6200 K and the second light emitting unit 112 that emits light having a color temperature of 2200 K are used. In addition, a third light emitting unit 113 that emits red light is provided. Then, two input currents are supplied from the power supply circuit 200 to the light emitting module 100, one of which is supplied to the first light emitting unit 111 and the other of which is supplied to the current control circuit 120. Further, the current control circuit 120 distributes and supplies the input current to the second light emitting unit 112 and the third light emitting unit 113 according to the current amount of the input current of the other side.

Specifically, the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 have the chromaticity points P ₁ , P ₂ , P ₃ , P ₄ , and P ₅ in FIG. 5, respectively. A current is supplied so as to have an optical output ratio as shown in Table 1 below corresponding to the straight line connecting the points, and the color temperature and brightness of the illumination light of the light emitting module 100 change. The chromaticity points P ₁ , P ₂ , P ₃ , P ₄ , and P ₅ indicate the chromaticity coordinates in the xy chromaticity diagram of FIG.

More specifically, when the chromaticity point is P1, as shown in FIG. 6A, only the _first input current I _IN 1 is output from the power supply circuit 200 to the light emitting module 100. The first input current I _IN1 supplied to the light emitting module 100 is supplied only to the first light emitting unit 111 as a drive current _IL1 . As a result, in the light emitting module 100, only the first light emitting unit 111 emits light, and the light emitting module 100 emits illumination light having a color temperature of 6200 K.

Further, while the chromaticity points are from P ₁ to P ₃ , as shown in FIGS. 6B and 6C, the power supply circuit 200 to the light emitting module 100 have a first input current I _IN 1 and a second input current I _{IN 2} . Two input currents are output.

Of these, the first input current I _IN1 is supplied only to the first light emitting unit 111 as the drive current _IL1 , and the first light emitting unit 111 emits light. On the other hand, the second input current I _IN2 is supplied to the current control circuit 120.

At this time, in the current control circuit 120, the second input current I _IN2 is distributed and supplied to the second light emitting unit 112 and the third light emitting unit 113 according to the amount of current of the second input current I _IN2 . In the embodiment, the current control circuit 120 preferentially flows a current to the light emitting unit 110 having a small total amount of forward voltage among the plurality of light emitting units 110 connected to the current control circuit 120.

Therefore, when the chromaticity points are P ₁ to P ₂ , as shown in FIG. 6B, the current control circuit 120 is limited to the third light emitting unit 113 having a smaller total amount of forward voltage than the second light emitting unit 112. The second input current I _IN2 starts to flow. That is, the second input current I _IN2 is supplied as the drive current _IL3 as it is only to the third light emitting unit 113, and no current is supplied to the second light emitting unit 112. As a result, the third light emitting unit 113 emits light, and the second light emitting unit 112 does not emit light.

After that, when the ratio of the second input current I _IN2 becomes larger than that of the first input current I _IN1 , the drive current _IL3 flowing through the third light emitting unit 113 also becomes larger, and the second input current I _IN2 becomes larger. When the maximum current that can be passed through the _third light emitting unit 113 is reached (chromaticity point P3), as shown in FIG. 6C, the current control circuit 120 sets the second input current I _{IN 2} to the second light emitting unit. It also splits into 112. That is, the second input current I _IN2 is shunted into the drive current _IL2 to the second light emitting unit 112 and the drive current _IL3 to the third light emitting unit 113.

After that, when the ratio of the second input current I _IN2 to the first input current I _IN1 increases, the current increase of the second input current I _IN2 directly increases the drive current _IL2 of the second light emitting unit 112. It will be a minute. That is, the drive current _IL3 flowing through the third light emitting unit 113 remains constant, and the ratio of the drive current _IL2 flowing through the second light emitting unit 112 increases.

As described above, when the chromaticity points are P ₁ to P ₃ , the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 have the first input current I _IN 1 and the second input, respectively. It emits light independently controlled by the current I _IN2 , and has a chromaticity point P1 and _a chromaticity point according to the light output ratios of the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113. Toning control is performed along a straight line connecting _two points with P3. That is, the light emitting module 100 emits illumination light having a color temperature of 6200K to 2700K. In this embodiment, since the synchro toning is performed, the brightness of the light emitting module 100 gradually decreases as the color temperature decreases.

When the chromaticity point is between _P3 and P4 _, as shown in FIG. 6C, the power supply circuit 200 to the light emitting module 100 are connected to the first input current I _IN1 and the second input current I _IN2 . Two input currents are output.

Of these, the first input current I _IN1 is supplied only to the first light emitting unit 111 as the drive current _IL1 , and the first light emitting unit 111 emits light. On the other hand, the second input current I _IN2 is supplied to the current control circuit 120. In the current control circuit 120, the second input current I _IN2 is distributed and supplied to the second light emitting unit 112 and the third light emitting unit 113 according to the amount of current of the second input current I _IN2 , according to the present embodiment. Then, the current control circuit 120 preferentially flows a current to the light emitting unit 110 having a small total amount of forward voltage among the plurality of light emitting units 110 connected to the current control circuit 120.

Therefore, when the chromaticity point is from P3 to P4 _, as shown in FIG. 6C, the current control circuit 120 supplies the drive current _IL2 to the _second light emitting unit 112 while supplying the third light emitting unit IL2. The drive current _IL3 is also supplied to 113. Then, in the present embodiment, when the chromaticity point is from P3 to _{P5 ,} the drive supplied to the second light emitting unit 112 becomes smaller as the drive current _IL1 supplied to the first light emitting unit 111 becomes smaller. The current _IL2 increases. Then, at the chromaticity point P4, the drive current _IL1 supplied to the _first light emitting unit 111 becomes zero.

As described above, even when the chromaticity points are P ₃ to P ₄ , the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 have the first input currents I _IN 1 and the third, respectively. It emits light independently controlled by the two input currents I _IN2 , and has a chromaticity point P3 and a color according to the light output ratios of the first light emitting unit 111, the second light emitting unit 112, and the _third light emitting unit 113. Color matching is controlled along a straight line connecting _two points with the degree point P4. That is, the light emitting module 100 emits illumination light having a color temperature of 2700K to 2200K. In this embodiment, since the synchro toning is performed, the brightness of the light emitting module 100 gradually decreases as the color temperature decreases.

Further, while the chromaticity point is from _P4 to P5, as shown in FIG. 6D, only the _second input current I _IN2 is output from the power supply circuit 200 to the light emitting module 100. The second input current I _IN2 supplied to the light emitting module 100 is supplied to the current control circuit 120.

At this time, in the current control circuit 120, the second input current I _IN2 is distributed and supplied to the second light emitting unit 112 and the third light emitting unit 113 according to the amount of current of the second input current I _IN2 . In the embodiment, the current control circuit 120 preferentially flows a current to the light emitting unit 110 having a small total amount of forward voltage among the plurality of light emitting units 110 connected to the current control circuit 120.

Therefore, when the chromaticity point is from _P4 to _P5 , as shown in FIG. 6D, the current control circuit 120 supplies the drive current _IL2 to the second light emitting unit 112 and emits a third light as described above. The drive current _IL3 is also supplied to the unit 113, but since the total amount of forward voltage is smaller in the third light emitting unit 113 than in the second light emitting unit 112, the drive current supplied to the third light emitting unit 113 is also supplied. _IL3 is always larger than the drive current _IL2 supplied to the second light emitting unit 112.

_In the present embodiment, when the chromaticity point is P4 to P5, the drive current _IL2 supplied to the _second light emitting unit 112 is controlled to be gradually reduced. When the chromaticity point _{P5 is reached, the drive current IL2 supplied to the second light emitting unit 112 becomes zero, and the drive current IL3 is supplied} only to the third light emitting unit 113.

As described above, when the chromaticity _points are _P4 to P5, the first light emitting unit 111 does not emit light, and only the second light emitting unit 112 and the third light emitting unit 113 are subjected to the second input current I _IN2 . It emits light under independent control, and is along a straight line connecting the two _points of the chromaticity point _P4 and the chromaticity point P5 according to the light output ratio of the second light emitting unit 112 and the third light emitting unit 113. Toning control. That is, the light emitting module 100 emits illumination light having a color temperature of 2200K to 1800K. In this embodiment, since the synchro toning is performed, the brightness of the light emitting module 100 gradually decreases as the color temperature decreases.

As described above, in the luminaire 1 in the present embodiment, as shown by the solid line in FIG. ₅ , when the color matching is controlled from the high color temperature to the low color temperature, the chromaticity points _P3 to P5 are relative to each other. In addition, the amount of current flowing through the third light emitting unit 113 is gradually increased. As a result, in the luminaire 1X of Comparative Example 1, the chromaticity point having a color temperature of 2200K was _PX5 , but in the luminaire 1 in the present embodiment, the chromaticity point having a color temperature of _2200K was changed to P4. And the chromaticity point with a color temperature of _2200K can be moved from _PX5 to P4. Therefore, the chromaticity of the illumination light of the luminaire 1 can be set to the target chromaticity close to the blackbody locus. That is, the third light emitting unit 113 can shift the color deviation (Duv) of the illumination light of the lighting fixture 1 (light emitting module 100) on the low color temperature side to the minus side. As a result, the color temperature of the illumination light on the low color temperature side can be brought closer to the blackbody locus. As a result, it is possible to reproduce white light that satisfies the entire area of the blackbody locus.

Moreover, in the lighting fixture 1 of the present embodiment, the current corresponding to the current amount of the second input current I _IN2 supplied from the power supply circuit 200 to the current control circuit 120 by the current control circuit 120 provided in the light emitting module 100. The second input current I _IN2 is distributed and supplied to the second light emitting unit 112 and the third light emitting unit 113 in terms of output ratio. As a result, the number of input currents (outputs) that can be independently controlled by the power supply circuit 200 while using the three light emitting units 110 of the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113. Even if the number) is two, which is smaller than the number of the light emitting units 110, it is possible to change the color temperature of the illumination light so as to trace the blackbody locus. That is, as the power supply circuit 200, it is possible to control the color matching of the light emitting module 100 having three light emitting units 110 having different light colors from each other by using an existing two-circuit control power supply having a simple structure at low cost.

Therefore, according to the lighting fixture 1 in the present embodiment, it is possible to reproduce the color with a light color close to the blackbody locus by using the low-cost power supply circuit 200.

In the toning control of the lighting fixture 1 in the present embodiment, a current is passed through the _third light emitting unit 113 that emits red light only when the chromaticity point is between _P3 and P4. Further, since the third light emitting unit 113 emits light when the brightness of the light emitting module 100 is low, the number of LED elements 113a constituting the third light emitting unit 113 is small (in the present embodiment). It can be two).

(Embodiment 2)
Next, the lighting fixture 1A according to the second embodiment will be described with reference to FIG. 7. FIG. 7 is a diagram showing a circuit configuration of the lighting fixture 1A according to the second embodiment.

The luminaire 1A according to the present embodiment and the luminaire 1 according to the first embodiment differ only in the functions of the third light emitting unit and the current control circuit 120, and are the same except for the functions.

Specifically, as shown in FIG. 7, the light emitting unit 110A of the light emitting module 100A in the lighting apparatus 1A according to the present embodiment has a first light emitting unit 111 that emits light having a first color temperature and a first light emitting unit 110A. A second light emitting unit 112 that emits light having a second color temperature that is lower than the color temperature, and a third color temperature that is higher than the first color temperature and the second color temperature. It is composed of a third light emitting unit 113A that emits light.

In the present embodiment, the first light emitting unit 111 and the second light emitting unit 112 are the same as those in the first embodiment. Therefore, the first light emitting unit 111 is composed of the LED element 111a that emits white light having a color temperature of 6200 K (first color temperature), and the second light emitting unit 112 has a color temperature of 2200 K (second color). It is composed of an LED element 112a that emits white light of (color temperature).

On the other hand, the configuration of the third light emitting unit 113A is different from that of the first embodiment, and the third light emitting unit 113A emits white light having a color temperature of 8000K (third color temperature). Further, the third light emitting unit 113A is composed of three LED elements 113aA (third LED element) connected in series. The three LED elements 113aA have the same configuration and characteristics (IF-VF characteristics, etc.). Therefore, the color temperature of the light of the three LED elements 113aA is 8000K. The number of LED elements 113aA constituting the third light emitting unit 113A is not limited to three, and may be one or a plurality of LED elements 113aA other than three.

Further, in the current control circuit 120 according to the first embodiment, when the current is diverted to the plurality of light emitting units 110 connected to the current control circuit 120, the current control circuit 120 is sequentially among the plurality of light emitting units 110 connected to the current control circuit 120. Although the current is preferentially passed to the light emitting unit 110 having a small total amount of directional voltage, the current control circuit 120 in the present embodiment is used when the current is diverted to the plurality of light emitting units 110 connected to the current control circuit 120. Of the plurality of light emitting units 110 connected to the current control circuit 120, the current is passed preferentially to the light emitting unit 110 having a large total amount of forward voltage.

Next, the color matching control of the lighting fixture 1A according to the present embodiment will be described with reference to FIG. 8 in comparison with the color matching control of the lighting fixture of Comparative Example 2. FIG. 8 is an xy chromaticity diagram showing a change in the light color of the illumination light due to toning control between the luminaire 1A according to the second embodiment and the luminaire of Comparative Example 2.

As shown by the broken line in FIG. 8, the luminaire of Comparative Example 2 can perform color matching only on a straight line connecting two points of the chromaticity point _P1Y and the chromaticity point P4 ₍ target chromaticity). Can not. Therefore, in the lighting fixture of Comparative Example 2, color shift occurs between the lighting fixture and the blackbody locus shown by the curve of FIG. 8, and it is difficult to reproduce white light satisfying the entire area of the blackbody locus.

On the other hand, in the light emitting module 100A of the luminaire 1A in the present embodiment, the first light emitting unit 111 that emits light having a color temperature of 6200 K and the second light emitting unit 112 that emits light having a color temperature of 2200 K are used. In addition, a third light emitting unit 113A that emits light having a color temperature of 8000 K is provided. Then, two input currents are supplied from the power supply circuit 200 to the light emitting module 100A, one of the currents (first input current) is supplied to the first light emitting unit 111, and the other current (second input current) is supplied. It is supplied to the current control circuit 120. Further, the current control circuit 120 distributes the current (second input current) to the second light emitting unit 112 and the third light emitting unit 113A according to the current amount of the other current (second input current). We are supplying.

Specifically, as shown by the solid line in FIG. 8, when the toning control is performed from the high color temperature at which the chromaticity _point is P1 to the low color temperature at which the chromaticity point is _P4 , the current control circuit is in the middle of the control. The amount of current flowing through the third light emitting unit 113A is gradually increased by 120.

As a result, in the lighting fixture of Comparative Example 2, the color temperature corresponding to the chromaticity point P _Y3 on the straight line connecting the _two chromaticity points P _Y1 and the chromaticity point P4 is set to the lighting fixture in the present embodiment. At ₁ , it can be moved to the chromaticity point P3. That is, the third light emitting unit 113A can shift the color deviation (Duv) of the illumination light of the lighting fixture 1A (light emitting module 100A) corresponding to the intermediate color temperature between 2200K and 6200K to the plus side. .. As a result, the color temperature of the illumination light of the luminaire 1A (light emitting module 100A) can be brought closer to the blackbody locus. As a result, it is possible to reproduce white light that satisfies the entire area of the blackbody locus. As described above, in the present embodiment, the illumination light of the luminaire 1A (light emitting module 100A) corresponds to the straight line connecting the chromaticity points P ₁ , P ₂ , P ₃ , and P ₄ in FIG. The light color changes.

Moreover, also in the lighting fixture 1A of the present embodiment, the second input current supplied from the power supply circuit 200 to the current control circuit 120 by the current control circuit 120 provided in the light emitting module 100A, as in the first embodiment. The second input current is distributed and supplied to the second light emitting unit 112 and the third light emitting unit 113A at a current output ratio corresponding to the amount of current. As a result, the number of input currents (outputs) that can be independently controlled by the power supply circuit 200 while using the three light emitting units 110A of the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113A. Even if the number) is two, which is smaller than the number of the light emitting units 110A, it is possible to change the color temperature of the illumination light so as to trace the blackbody locus. That is, as the power supply circuit 200, the existing two-circuit control power supply having a simple configuration at low cost can be used to perform color matching control of the light emitting module 100A having three light emitting units 110A having different light colors.

Therefore, according to the lighting fixture 1A in the present embodiment, it is possible to reproduce the color with a light color close to the blackbody locus by using the low-cost power supply circuit 200.

(Embodiment 3)
Next, the lighting fixture 1B according to the third embodiment will be described with reference to FIG. FIG. 9 is a diagram showing a circuit configuration of the lighting fixture 1B according to the third embodiment.

The luminaire 1B according to the present embodiment and the luminaire 1 according to the first embodiment differ only in the current control circuit, and are basically the same except for the current control circuit.

Specifically, as shown in FIG. 9, the light emitting unit 110 of the light emitting module 100B in the lighting fixture 1B in the present embodiment is the first that emits light having the first color temperature, as in the first embodiment. It is composed of a light emitting unit 111, a second light emitting unit 112 that emits light having a second color temperature lower than the first color temperature, and a third light emitting unit 113 that emits red light. Will be done. The number of the LED elements 113a constituting the third light emitting unit 113 is three, but the number is not limited to three, and may be one or a plurality of LED elements 113a other than three.

Further, in the first embodiment, the current control circuit 120 distributes and supplies the input current to the second light emitting unit 112 and the third light emitting unit 113, but in the present embodiment, the current control circuit 120B is used. Distributes the input current to the first light emitting unit 111 and the third light emitting unit 113. In this case, the current control circuit 120B detects the current amount (current value) of the input current input from the power supply circuit 200 to the current control circuit 120B. Then, the current output ratio (distribution ratio) of the input current for distribution to the first light emitting unit 111 and the third light emitting unit 113 is determined according to the detected current amount, and the current control circuit 120B determines this current output. A current is supplied to the first light emitting unit 111 and the third light emitting unit 113 by the amount of current based on the ratio.

Further, the current control circuit 120B in the present embodiment is different from the current control circuit 120 in the first embodiment, and the current control circuit 120 is used when the current is diverted to the plurality of light emitting units 110 connected to the current control circuit 120B. Of the plurality of light emitting units 110 connected to the light emitting unit 110, the current is preferentially passed to the light emitting unit 110 having a large total amount of forward voltage.

Next, with reference to FIG. 10, the color matching control of the lighting fixture 1B according to the present embodiment will be described in comparison with the color matching control of the lighting fixture of Comparative Example 3. FIG. 8 is an xy chromaticity diagram showing a change in the light color of the illumination light due to toning control between the luminaire 1B according to the third embodiment and the luminaire of Comparative Example 3.

As shown by the broken line in FIG. 10, the luminaire of Comparative Example ₃ can perform color matching only on a straight line connecting two points of the chromaticity point _PZ1 and the chromaticity point P3 (target chromaticity). Can not. Therefore, in the lighting fixture of Comparative Example 3, color shift occurs between the lighting fixture and the blackbody locus shown by the curve of FIG. 10, and it is difficult to reproduce white light satisfying the entire area of the blackbody locus.

On the other hand, in the lighting fixture 1B of the present embodiment, two input currents are supplied from the power supply circuit 200 to the light emitting module 100B, and one of the currents (first input current) is supplied to the second light emitting unit 112. The other current (second input current) is supplied to the current control circuit 120B. Further, the current control circuit 120B distributes the current (second input current) to the first light emitting unit 111 and the third light emitting unit 113 according to the current amount of the other current (second input current). We are supplying.

Specifically, as shown by the solid line in FIG. 10, when the toning control is performed from the low color temperature at which the chromaticity point is P3 to the high color temperature at which the chromaticity _point is P1 _, the current control circuit is in the middle of the control. The amount of current flowing through the third light emitting unit 113 is gradually increased by 120B.

As a result, in the luminaire of Comparative Example 3, the chromaticity point having a color temperature of 6200K was P _Z1 , but in the luminaire _1B in the present embodiment, the chromaticity point having a color temperature of 6200K is set to P1. And the chromaticity point with a color temperature of 6200K can be moved from P _{Z 1} to P 1. Therefore, the chromaticity of the illumination light of the luminaire 1B can be set to the target chromaticity close to the blackbody locus. That is, the third light emitting unit 113 can shift the color deviation (Duv) of the illumination light of the lighting fixture 1B (light emitting module 100B) on the high color temperature side to the minus side. As a result, the color temperature of the illumination light on the high color temperature side can be brought closer to the blackbody locus. As a result, it is possible to reproduce white light that satisfies the entire area of the blackbody locus. As described above, in the present embodiment, the light color of the illumination light of the luminaire 1B (light emitting module 100B) corresponds to the straight line connecting the chromaticity points P ₁ , P ₂ , and P ₃ in FIG. Change.

Moreover, also in the lighting fixture 1B of the present embodiment, the current amount of the input current supplied from the power supply circuit 200 to the current control circuit 120B by the current control circuit 120B provided in the light emitting module 100B, as in the first embodiment. The input current is distributed and supplied to the first light emitting unit 111 and the third light emitting unit 113 at a current output ratio corresponding to the above. As a result, the number of input currents (outputs) that can be independently controlled by the power supply circuit 200 while using the three light emitting units 110 of the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113. Even if the number) is two, which is smaller than the number of the light emitting units 110, it is possible to change the color temperature of the illumination light so as to trace the blackbody locus. That is, as the power supply circuit 200, the existing two-circuit control power supply having a simple configuration at low cost can be used to perform color matching control of the light emitting module 100 having three light emitting units 110 having different light colors.

Therefore, according to the lighting fixture 1B in the present embodiment, it is possible to reproduce the color with a light color close to the blackbody locus by using the low-cost power supply circuit 200.

(Modification example)
The lighting fixture according to the present invention has been described above based on the embodiment, but the present invention is not limited to the above embodiment.

For example, in the above-described first to third embodiments, the dimming control of the plurality of light emitting units is performed by phase dimming (two-wire system), but the dimming control method is not limited to this, and PWM dimming is used. Dimming control of a plurality of light emitting units may be performed by (four-wire system) or 0-10 VDC dimming.

Further, in the first embodiment, the LED element constituting the light emitting unit 110 is an SMD type, and the light emitting module 100 is an SMD type, but the present invention is not limited to this. For example, a COB (Chip On Board) type light emitting module in which an LED chip (bare chip) is directly mounted on a substrate may be used. For example, as in the light emitting module 101 shown in FIG. 11, a plurality of LED chips and the LED chips in which the first light emitting unit 111, the second light emitting unit 112, and the third light emitting unit 113 are mounted on the substrate 130 are mounted on the substrate 130. It may be configured by a sealing member for sealing. In this case, in the first light emitting unit 111 and the second light emitting unit 112, a blue LED chip is used as the LED chip, and one or more kinds of phosphors such as a yellow phosphor are contained as a sealing member. Use the contained resin. On the other hand, in the third light emitting unit 113, a red LED chip is used as the LED chip, and a transparent resin containing no phosphor is used as the sealing member. The COB type light emitting module may also be applied in the second and third embodiments.

Further, in the above-described first to third embodiments, the number of light emitting units provided in the light emitting module is three, but the number is not limited to this. For example, the light emitting module may be provided with three or more light emitting units. In this case as well, by making the number of power outputs supplied from the power supply circuit to the light emitting module smaller than the number of light emitting units, the power supply circuit is more than the case of using a power supply circuit having the same number of power outputs as the number of light emitting parts. The cost can be suppressed.

Further, in the first to third embodiments, the color matching control of the light emitting module is performed by using the dimming switch 4 connected to the power supply unit via the electric wire, but the present invention is not limited to this. For example, by incorporating a wireless module in the power supply unit, the color matching control of the light emitting module may be performed by transmitting a dimming / coloring signal from the wireless terminal to the wireless module.

Further, in the above-described first to third embodiments, in performing the toning control, the synchro toning in which the toning and the dimming are linked is performed, but the present invention is not limited to this. For example, toning control may be performed so as to change only the light color without changing the brightness.

Further, although the downlight is exemplified in the above-described first to third embodiments, the present invention can be applied to other lighting fixtures such as a spotlight or a base light.

In addition, it is realized by arbitrarily combining the components and functions in each embodiment to the extent obtained by applying various modifications to each of the above embodiments to be conceived by those skilled in the art, and to the extent that the gist of the present invention is not deviated. Also included in the present invention.

1, 1A, 1B Lighting equipment 100, 100A, 100B, 101 Light emitting module 110, 110A Light emitting unit 111 First light emitting unit 112 Second light emitting unit 113, 113A Third light emitting unit 120, 120B Current control circuit 130 Board 200 Power circuit

Claims (7)

Light emitting module and
It is provided with a power supply circuit that outputs electric power for making the light emitting module emit light to the light emitting module.
The light emitting module has three or more light emitting units having different light colors of emitted light and a current control circuit.
The three or more light emitting units are provided on different current paths, and the light emitting units are provided on different current paths.
The number of outputs of electric power supplied from the power supply circuit to the light emitting module is two or more, and is smaller than the number of the three or more light emitting units.
The power supply circuit supplies the electric power to the current control circuit and supplies the electric power to at least one of the three or more light emitting units without going through the current control circuit.
The current control circuit has a plurality of light emitting units connected to the current control circuit among the three or more light emitting units based on a current output ratio according to the amount of current supplied from the power supply circuit to the current control circuit. Supply current to the unit,
lighting equipment. The three or more light emitting units are a first light emitting unit that emits light having a first color temperature and a second light emitting unit that emits light having a second color temperature that is lower than the first color temperature. It is composed of a part and a third light emitting part that emits red light.
The first light emitting unit, the second light emitting unit, and the third light emitting unit are not the same.
The power supply circuit outputs the electric power to the first light emitting unit and the current control circuit.
The current control circuit supplies a current to the second light emitting unit and the third light emitting unit based on the current output ratio.
The lighting fixture according to claim 1. The current control circuit starts to flow a current from the light emitting unit having a small total amount of forward voltage among the plurality of light emitting units connected to the current control circuit.
The lighting fixture according to claim 1 or 2. The three or more light emitting units are a first light emitting unit that emits light having a first color temperature and a second light emitting unit that emits light having a second color temperature that is lower than the first color temperature. It is composed of a unit and a third light emitting unit that emits light having a third color temperature, which is a color temperature higher than the first color temperature and the second color temperature.
The first light emitting unit, the second light emitting unit, and the third light emitting unit are not the same.
The power supply circuit outputs the electric power to the first light emitting unit and the current control circuit.
The current control circuit supplies a current to the second light emitting unit and the third light emitting unit based on the current output ratio.
The lighting fixture according to claim 1 or 2. The three or more light emitting units are a first light emitting unit that emits light having a first color temperature and a second light emitting unit that emits light having a second color temperature that is lower than the first color temperature. It is composed of a part and a third light emitting part that emits red light.
The first light emitting unit, the second light emitting unit, and the third light emitting unit are not the same.
The power supply circuit outputs the electric power to the second light emitting unit and the current control circuit.
The current control circuit supplies a current to the first light emitting unit and the third light emitting unit based on the current output ratio.
The lighting fixture according to claim 1 or 2. The light emitting module has a substrate and has a substrate.
The three or more light emitting units and the current control circuit are provided on the substrate.
The lighting fixture according to any one of claims 1 to 5. Each of the three or more light emitting units is composed of a plurality of LED elements connected in series.
The lighting fixture according to any one of claims 1 to 6.

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