JP6901301B2 - Power circuits, lighting fixtures, and power control methods - Google Patents

Description

The present invention relates to a power supply circuit, a luminaire, and a power supply control method.

There are known luminaires capable of dimming and toning by pulse width modulation (PWM) signals. Such a luminaire generally includes two color luminaires that generate light having different light colors from each other, and two power supply circuits that individually generate currents to be passed through the luminaires of each color. .. Further, PWM signals for controlling the amount of light of each color are input from the two dimmers to the luminaire. The luminaire sets the dimming rate of one color according to the duty ratio of the PWM signal input from one dimmer, and sets the dimming rate of one color according to the duty ratio of the PWM signal input from the other dimmer. , Set the dimming rate of the other color. Therefore, the color adjustment can be performed by manipulating the duty ratios of the PWM signals output from the two dimmers to change the amount of light (mixing ratio) of the light generated from the illumination elements of each color.

On the other hand, in a general lighting control system, since the two power supply circuits are controlled independently, an excessive amount of current may flow during color mixing, and excessive heat may be generated. Specifically, in a general lighting control system, the dimming rate of each color can be set to 100%. In other words, light corresponding to a dimming rate of 200% (light having an excessive amount of light) can be emitted from the luminaire. When the dimming rate of each color is set to 100%, the amount of current is doubled as compared with the case where monochromatic light is generated at a dimming rate of 100%. As a result, excessive heat is generated. Therefore, for example, it is necessary to increase the size of the radiator (heat sink) in case excessive heat is generated.

Patent Document 1 describes a configuration for solving the above problem. Specifically, in the lighting control system described in Patent Document 1, a dimming signal (PWM signal) and a color temperature signal (PWM signal) are input to the luminaire. The dimming signal controls the amount of light (mixed light) emitted from the luminaire, and the color temperature signal controls the color temperature of the light (mixed light) emitted from the luminaire. Specifically, the luminaire described in Patent Document 1 includes a two-color LED (Light Emitting Diode) and one power supply circuit. The power supply circuit generates a current that causes the LEDs of each color to emit light. At the time of dimming, the current flowing through the LEDs of each color is controlled based on the duty ratio of the dimming signal. At the time of color matching, the current flowing through the LEDs of each color is controlled based on the duty ratio of the color temperature signal.

Japanese Unexamined Patent Publication No. 2011-258515

However, the configuration described in Patent Document 1 requires a signal different from the signal used in a general lighting control system. Therefore, it cannot be used for a general lighting control system.

The present invention has been made in view of the above problems, and an object of the present invention is to input a signal for controlling the amount of light of each color to a lighting fixture provided with two-color lighting elements that generate light having different light colors. It is an object of the present invention to provide a power supply circuit, a luminaire, and a power supply control method that do not output an excessive amount of current at the time of color mixing.

The power supply circuit disclosed in the present application generates a first current for lighting the first light source unit based on the first control signal output from the first dimmer, and outputs the second current from the second dimmer. Based on the control signal, a current for lighting the second light source unit is generated. The power supply circuit includes a lighting unit and a control unit. The lighting unit generates pre Symbol a first current and a pre-Symbol second current. Wherein, prior Symbol a first control signal, before SL on the basis of a second control signal, for controlling the lighting unit. The first control signal is a signal that controls the amount of light generated from the first light source unit. The second control signal is a signal that controls the amount of light generated from the second light source unit. The control unit sets the output value of the first current based on the first control signal. The control unit sets the maximum output value of the second current based on the preset output rated value and the output value of the first current. The control unit sets the output value of the second current based on the second control signal and the maximum output value of the second current.

In the power supply circuit disclosed in the present application, the first control signal and the second control signal may indicate a control value indicating the amount of light. Further, the control unit may store a table that defines the relationship between the amount of light and the control value. The table may show the amount of light in a discrete manner.

In the power supply circuit disclosed in the present application, the first control signal and the second control signal can be pulse width modulated signals.

The luminaire disclosed in the present application includes a first light source unit that generates light, a second light source unit that generates light, and the power supply circuit described above.

In the lighting equipment disclosed in the present application, the light generated from the first light source unit may exhibit a light color different from the light generated from the second light source unit.

The power supply control method disclosed in the present application generates a first current for lighting the first light source unit based on the first control signal output from the first dimmer, and outputs the first current from the second dimmer. 2 This is a method of controlling a power supply circuit that generates a second current for lighting a second light source unit based on a control signal. The power supply control method, before SL on the basis of the first control signal, a step of setting an output value of the first current, based a preset rated output value, the output value of the first current, comprising the steps of: setting the maximum output value of the second current, previous SL and a second control signal, based on the maximum output value of the second current, and setting the output value of the second current .. The first control signal is a signal that controls the amount of light generated from the first light source unit. The second control signal is a signal that controls the amount of light generated from the second light source unit.

According to the present invention, in a lighting control system in which a signal for controlling the amount of light of each color is input to a luminaire provided with two-color illuminating elements that generate light having different light colors, an excessive amount from a power supply circuit. It is possible to suppress the output of the current.

It is a figure which shows the lighting control system which concerns on Embodiment 1 of this invention. It is a figure which shows the power-source control method which concerns on Embodiment 1 of this invention. It is a graph which shows the characteristic of the PWM dimming table which concerns on Embodiment 1 of this invention. It is a graph which shows the other characteristic of the PWM dimming table which concerns on Embodiment 1 of this invention. It is a figure which shows the lighting control system which concerns on Embodiment 2 of this invention. It is a figure which shows the lighting control system which concerns on Embodiment 3 of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to the following embodiments. In the figure, the same or corresponding parts are designated by the same reference numerals and the description is not repeated.

[Embodiment 1]
FIG. 1 is a diagram showing a lighting control system 1 according to the first embodiment. As shown in FIG. 1, the lighting control system 1 includes a lighting fixture 2, a first dimmer 3, and a second dimmer 4.

The luminaire 2 includes a power supply circuit 21 and a light source module 22. The light source module 22 includes a first light source unit 23 and a second light source unit 24. Each of the first light source unit 23 and the second light source unit 24 has at least one illumination element such as an LED or an organic EL element. Further, the illumination element of the first light source unit 23 generates light having a light color (for example, color temperature) different from that of the illumination element of the second light source unit 24. The light source module 22 includes a substrate on which the illumination element of the first light source unit 23 and the illumination element of the second light source unit 24 are mounted.

The first dimmer 3 outputs a first control signal that controls the amount of light generated from the first light source unit 23. The second dimmer 4 outputs a second control signal that controls the amount of light generated from the second light source unit 24. In the present embodiment, the first control signal and the second control signal are PWM signals (pulse width modulation signals). The PWM signal is a signal having a constant period T and a variable pulse width τ. In the following description, with the No. 1 system Goshin to as a "first 1PWM signal", the second control signal may be referred to as "first 2PWM signal".

Each of the first dimmer 3 and the second dimmer 4 includes a user interface operated by the user. The user interface is composed of, for example, a dial (volume knob), a plurality of push buttons, or a touch panel. The user can operate the user interface to control the amount of light generated from the first light source unit 23 and the amount of light generated from the second light source unit 24. Specifically, when the user operates the user interface, the duty ratio D (= pulse width τ / period T) of the PWM signal changes. The duty ratio D of the first PWM signal indicates the amount of light generated from the first light source unit 23, and the duty ratio D of the second PWM signal indicates the amount of light generated from the second light source unit 24.

The power supply circuit 21 includes a current generation unit 211, a control unit 212, a first lighting unit 213a, and a second lighting unit 213b. The current generation unit 211 is connected to an external AC power supply 5, and generates a current to be passed through the first light source unit 23 and the second light source unit 24 based on the AC voltage supplied from the AC power supply 5. The AC power supply 5 is typically a commercial AC power supply.

The current generation unit 211 is controlled by the control unit 212 to generate a current to be passed through the first light source unit 23 and the second light source unit 24. Typically, the current generator 211 generates a direct current. More preferably, the current generation unit 211 generates a constant current. Typically, the current generation unit 211 includes a switch element, and the control unit 212 controls the operation (turn-on and turn-off) of the switch element of the current generation unit 211 to cause the current generation unit 211 to generate a current.

The first lighting unit 213a controls the current output from the current generation unit 211 to generate a first current that lights the first light source unit 23. Similarly, the second lighting unit 213b controls the current output from the current generation unit 211 to generate a second current that lights the second light source unit 24.

Typically, the first lighting unit 213a and the second lighting unit 213b include a switch element. The switch elements of the first lighting unit 213a and the second lighting unit 213b are controlled by the control unit 212. Specifically, the control unit 212 drives the switch elements of the first lighting unit 213a and the second lighting unit 213b at a high frequency. Further, the control unit 212 controls the on period of the switch element of the first lighting unit 213a based on the duty ratio D of the first PWM signal, and based on the duty ratio D of the second PWM signal, the control unit 212 of the second lighting unit 213b. Controls the on period of the switch element. As the on period of the switch element of the first lighting unit 213a becomes longer, the amount of current (first current) supplied to the first light source unit 23 increases, and the amount of light generated from the first light source unit 23 increases. To increase. Similarly, as the on period of the switch element of the second lighting unit 213b becomes longer, the amount of current (second current) supplied to the second light source unit 24 increases, and the light generated from the second light source unit 24 increases. The amount of light increases.

The control unit 212 is typically a micro-control unit. The control unit 212 is not limited to the micro control unit. For example, the control unit 212 may be composed of a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory).

The control unit 212 stores a PWM dimming table for the first current. The PWM dimming table for the first current defines the relationship between the duty ratio D of the first PWM signal and the amount of light (the amount of light generated from the first light source unit 23).

The control unit 212 has a current amount (output) of the current (first current) output from the first lighting unit 213a based on the duty ratio D of the PWM signal (first PWM signal) input from the first dimmer 3. Value) is set. Specifically, the control unit 212 determines the duty ratio D of the first PWM signal. The duty ratio D of the first PWM signal is a control value that indicates the amount of light generated from the first light source unit 23. When the control unit 212 determines the duty ratio D of the first PWM signal, the control unit 212 determines the amount of light corresponding to the duty ratio D of the first PWM signal with reference to the PWM dimming table for the first current. Then, the output value of the first current is set so that the light having the light amount corresponding to the duty ratio D of the first PWM signal is generated from the first light source unit 23. As a result, the first light source unit 23 generates light having a light amount corresponding to the duty ratio D of the first PWM signal.

On the other hand, the control unit 212 outputs a current (second) output from the second lighting unit 213b based on the output rated value x of the power supply circuit 21, the output value of the first current, and the duty ratio D of the second PWM signal. Set the current amount (output value) of (current). The output rated value x of the power supply circuit 21 is preset. Hereinafter, the process of setting the output value of the second current will be described with reference to FIGS. 1 and 2.

FIG. 2 is a diagram showing a power supply control method according to the first embodiment. Specifically, FIG. 2 shows a flow of processing for setting the output value of the second current. The process shown in FIG. 2 is executed when the first dimmer 3 and the second dimmer 4 are started. Further, the process shown in FIG. 2 is executed when the duty ratio D of the first PWM signal changes. In the following description, the output value of the first current may be described as "first output value", and the output value of the second current may be described as "second output value".

First, as described with reference to FIG. 1, the control unit 212 sets the output value y (first output value) of the current (first current) output from the first lighting unit 213a to the first light source unit 23. Set (step S21).

Next, the control unit 212 sets the maximum output value z of the current (second current) output from the second lighting unit 213b to the second light source unit 24 (step S22). The maximum output value z of the second current is set based on the output rated value x of the power supply circuit 21 and the first output value y. Specifically, the maximum output value z of the second current is set so that a current exceeding the output rated value x of the power supply circuit 21 is not output from the power supply circuit 21. For example, the maximum output value z of the second current can be calculated based on the following equation 1.
z = xy ... (Equation 1)

Next, the control unit 212 copies the PWM dimming table for the first current to generate a copy table, and corrects the copy table based on the maximum output value z to perform PWM dimming for the second current. Generate a table (step S23). The PWM dimming table for the second current defines the relationship between the duty ratio D of the second PWM signal and the amount of light (the amount of light generated from the second light source unit 24). In the following description, a copy table that is a copy of the PWM dimming table for the first current may be referred to as the "original PWM dimming table".

Specifically, the control unit 212 modifies the original PWM dimming table so that the amount of light corresponding to the maximum output value z becomes the maximum amount of light, and generates a PWM dimming table for the second current. In other words, the maximum amount of light generated from the second light source unit 24 is changed from the maximum amount of light specified in the original PWM dimming table to the amount of light corresponding to the maximum output value z. Hereinafter, the amount of light corresponding to the maximum output value z may be described as "the upper limit of the amount of light". Further, the maximum amount of light specified in the original PWM dimming table may be described as "original maximum amount of light". The upper limit of the amount of light indicates a value smaller than the original maximum amount of light.

The characteristics of the PWM dimming table for the second current are not particularly limited as long as the second output value can be set to the maximum output value z or less. For example, the control unit 212 may modify the relationship between the duty ratio D of the PWM signal and the amount of light so that the upper limit of the amount of light is the maximum amount of light. Specifically, the control unit 212 sets the original PWM dimming table by, for example, reducing the value of the light amount indicated by the original PWM dimming table according to the ratio between the upper limit of the light amount and the original maximum light amount. May be reduced. Alternatively, the control unit 212 may generate a table including a portion equal to or less than the upper limit of the amount of light in the original PWM dimming table as the PWM dimming table for the second current.

The copy table (original PWM dimming table) is generated every time the maximum output value z of the second current is set (updated). Further, the PWM dimming table for the second current is generated (updated) every time the maximum output value z of the second current is set (updated).

The control unit 212 sets the second output value based on the PWM dimming table for the second current and the duty ratio D of the PWM signal (second PWM signal) input from the second dimmer 4. Step S24). When the second output value is set, the control unit 212 ends the process shown in FIG.

Specifically, the control unit 212 determines the duty ratio D of the second PWM signal. The duty ratio D of the second PWM signal is a control value that indicates the amount of light generated from the second light source unit 24. When the control unit 212 determines the duty ratio D of the second PWM signal, the control unit 212 sets the second output value with reference to the PWM dimming table for the second current.

For example, when the PWM dimming table for the second current is a table obtained by reducing the original PWM dimming table based on the maximum output value z, the control unit 212 refers to the PWM dimming table for the second current. Then, the amount of light corresponding to the duty ratio D of the second PWM signal is determined. Then, the control unit 212 sets the output value corresponding to the amount of light determined by referring to the PWM dimming table for the second current as the second output value.

Alternatively, when the PWM dimming table for the second current is composed of a portion equal to or less than the upper limit of the light amount in the original PWM dimming table, and the light amount corresponding to the duty ratio D of the second PWM signal is not more than the upper limit of the light amount. The control unit 212 sets, as the second output value, an output value corresponding to the amount of light determined by referring to the PWM dimming table for the second current. Further, when the duty ratio D of the second PWM signal corresponds to the amount of light exceeding the upper limit of the amount of light (the amount of light exceeding the maximum amount of light specified in the PWM dimming table for the second current), the control unit 212 sends the second PWM signal. The maximum output value z is set as the second output value regardless of the duty ratio D of.

The power supply circuit 21, the luminaire 2, and the power supply control method according to the first embodiment have been described above with reference to FIGS. 1 and 2. According to the first embodiment, the second output value can be regulated so that the total value of the first output value and the second output value is equal to or less than the output rated value x. Therefore, a lighting control system (lighting control) in which a signal (PWM signal) for controlling the amount of light of each color is input to a lighting fixture (lighting fixture 2) including lighting elements of two colors that generate light having different light colors. In the system 1), it is possible to suppress the output of an excessive amount of current from the power supply circuit 21. Further, since it is possible to suppress the flow of an excessive amount of current, it is not necessary to increase the size of the radiator. Typically, the radiator only needs to be able to cope with the heat generated when the monochromatic lighting element emits light at a dimming rate of 100%.

The lighting control system 1 shown in FIG. 1 includes one lighting fixture 2, but the lighting control system 1 may include a plurality of lighting fixtures 2. When the lighting control system 1 includes a plurality of luminaires 2, the plurality of luminaires 2 are connected in parallel to the first dimmer 3 and the second dimmer 4.

Subsequently, with reference to FIG. 3, the characteristics of the PWM dimming table (PWM dimming table for the first current and PWM dimming table for the second current) according to the first embodiment will be described. FIG. 3 is a graph showing the characteristics of the PWM dimming table according to the first embodiment. In FIG. 3, the horizontal axis represents the duty ratio D of the PWM signal, and the vertical axis represents the amount of light (for example, dimming rate).

As shown in FIG. 3, the PWM dimming table according to the first embodiment shows the amount of light discretely. Therefore, the first output value and the second output value described with reference to FIG. 1 are discrete values. Further, as shown in FIG. 3, the PWM dimming table according to the first embodiment has an adjustment width W of the duty ratio D for each light amount (discrete value). Therefore, even if the duty ratio D fluctuates within the adjustment width W, the amount of light does not fluctuate.

The characteristics of the PWM dimming table according to the first embodiment have been described above with reference to FIG. According to the first embodiment, when a plurality of luminaires 2 are connected to the first dimmer 3 and the second dimmer 4, even if the power supply characteristics vary between the luminaires 2, the illuminating is performed. Variations in toning (variations in light color) are unlikely to occur between the fixtures 2. Alternatively, it becomes easy to match the light colors between the luminaires 2.

Specifically, the determination of the duty ratio D of the PWM signal by the control unit 212 may vary between the lighting fixtures 2. If the determination of the duty ratio D of the PWM signal by the control unit 212 varies between the luminaires 2, the same light color may not be obtained between the luminaires 2. On the other hand, according to the PWM dimming table according to the first embodiment, even if the duty ratio D fluctuates within the adjustment width W, the amount of light does not fluctuate. Therefore, even if the determination of the duty ratio D of the PWM signal varies between the lighting fixtures 2, the light color is unlikely to vary between the lighting fixtures 2. Alternatively, even if the determination of the duty ratio D of the PWM signal varies between the lighting fixtures 2 and the light color does not match (color shift) between the lighting fixtures 2, the light color can be easily changed between the lighting fixtures 2. Can be matched. Specifically, even if the determination of the duty ratio D of the PWM signal varies, the adjustment width W is set for each light amount (discrete value), so that the duty ratio D of the PWM signal is adjusted to the desired light amount W. Can be easily accommodated within the range of. Therefore, the light colors can be easily matched between the lighting fixtures 2. Similarly, variations in light color are less likely to occur between different lighting control systems 1. Alternatively, it becomes easy to match the light colors between different lighting control systems 1.

The characteristics of the PWM dimming table are not limited to the characteristics shown in FIG. For example, the PWM dimming table having the characteristics shown in FIG. 3 shows 6 light intensity values, but the number of light intensity values indicated by the PWM dimming table may be more than 6 or less than 6. May be good.

Further, in the characteristics shown in FIG. 3, the adjustment width W of the duty ratio D is constant, but as shown in FIG. 4, for example, the adjustment width W of the duty ratio D does not have to be constant. FIG. 4 is a diagram showing other characteristics of the PWM dimming table. In FIG. 4, the horizontal axis represents the duty ratio D of the PWM signal, and the vertical axis represents the amount of light.

Further, in the characteristics shown in FIG. 3, the amount of change H of the amount of light (interval between adjacent values of the amount of light) is constant, but as shown in FIG. 4, for example, the amount of change H of the amount of light does not have to be constant.

[Embodiment 2]
Subsequently, the second embodiment of the present invention will be described with reference to FIG. However, matters different from those of the first embodiment will be described, and explanations of the same matters as those of the first embodiment will be omitted. The second embodiment is different from the first embodiment in that the lighting control system 1 includes the output rating value adjuster 6.

FIG. 5 is a diagram showing a lighting control system 1 according to the second embodiment. As shown in FIG. 5, the lighting control system 1 according to the second embodiment further includes an output rating value adjuster 6.

The output rated value adjuster 6 outputs a rated value adjusting signal for adjusting the output rated value x of the power supply circuit 21. The rated value adjustment signal can be, for example, a PWM signal. The output rated value adjuster 6 includes a user interface that can be operated by the user, similarly to the first dimmer 3 and the second dimmer 4. The user can adjust the output rated value x by operating the user interface of the output rated value adjuster 6. Specifically, when the rated value adjustment signal is a PWM signal, the duty ratio D of the rated value adjustment signal (PWM signal) changes when the user operates the user interface of the output rated value adjuster 6. The duty ratio D of the rated value adjustment signal indicates the output rated value x.

A rated value adjustment signal is input from the output rated value adjuster 6 to the control unit 212 according to the second embodiment. The control unit 212 sets (adjusts) the output rated value x based on the rated value adjusting signal. For example, the control unit 212 sets the output rated value x with reference to the output rated value adjusting table that defines the relationship between the duty ratio D of the rated value adjusting signal (PWM signal) and the output rated value x.

The power supply circuit 21 and the luminaire 2 according to the second embodiment have been described above with reference to FIG. According to the second embodiment, the output rated value x can be adjusted. Therefore, the output rated value x can be reduced to reduce the maximum output value z of the second current described with reference to FIG. As a result, it is possible to further suppress the output of an excessive current from the power supply circuit 21 at the time of color mixing. Alternatively, the output rated value x can be increased to increase the maximum output value z of the second current. As a result, the adjustment range of the amount of light generated from the second light source unit 24 at the time of color mixing can be expanded.

Further, when the lighting control system 1 includes a plurality of lighting fixtures 2, by inputting a rated value adjustment signal to each lighting fixture 2, variation in the output rated value x between the power supply circuits 21 of each lighting fixture 2 is suppressed. can do. As a result, it is possible to suppress variations in the light color of the light emitted from each luminaire 2. Alternatively, it becomes easy to match the light colors between the luminaires 2. Similarly, variations in light color are less likely to occur between different lighting control systems 1. Alternatively, it becomes easy to match the light colors between different lighting control systems 1.

[Embodiment 3]
Subsequently, the third embodiment of the present invention will be described with reference to FIG. However, the matters different from those of the first and second embodiments will be described, and the same matters as those of the first and second embodiments will be omitted. The third embodiment is different from the first and second embodiments in that the luminaire 2 includes two power supply circuits.

FIG. 6 is a diagram showing a lighting control system 1 according to the third embodiment. As shown in FIG. 6, the luminaire 2 according to the third embodiment includes a first power supply circuit 21a and a second power supply circuit 21b. The first power supply circuit 21a includes a first current generation unit 211a, a first control unit 212a, and a first lighting unit 213a, and the second power supply circuit 21b includes a second current generation unit 211b, a second control unit 212b, and A second lighting unit 213b is provided.

The first current generation unit 211a and the second current generation unit 211b are connected to an external AC power supply 5. The first current generation unit 211a and the second current generation unit 211b are configured in the same manner as the current generation unit 211 described with reference to FIG. The first current generation unit 211a is controlled by the first control unit 212a to generate a current to be passed through the first light source unit 23. Further, the second current generation unit 211b is controlled by the second control unit 212b to generate a current to be passed through the second light source unit 24.

The first lighting unit 213a controls the current output from the first current generation unit 211a to generate a current (first current) for lighting the first light source unit 23. Specifically, the first lighting unit 213a is controlled by the first control unit 212a. A first PWM signal is input from the first dimmer 3 to the first control unit 212a. Similar to the control unit 212 of the first embodiment, the first control unit 212a stores a PWM dimming table (PWM dimming table for the first current), and is based on the duty ratio D of the first PWM signal. The output value (current amount) of the current (first current) output from the first lighting unit 213a is set.

The second lighting unit 213b controls the current output from the second current generation unit 211b to generate a current (second current) for lighting the second light source unit 24. Specifically, the second lighting unit 213b is controlled by the second control unit 212b.

A second PWM signal is input from the second dimmer 4 to the second control unit 212b. Further, a first PWM signal is input from the first dimmer 3 to the second control unit 212b. The second control unit 212b executes the second output value setting process described with reference to FIG. 2 in the same manner as the control unit 212 of the first embodiment.

Specifically, the second control unit 212b specifies the first output value based on the first PWM signal. Further, the second control unit 212b has a second output value (current amount of the second current) based on the output rated value x of the second power supply circuit 21b, the first output value, and the duty ratio D of the second PWM signal. ) Is set.

Specifically, the second control unit 212b sets the maximum output value z based on the output rated value x of the second power supply circuit 21b and the first output value. The second control unit 212b stores a reference PWM dimming table (a table corresponding to the PWM dimming table for the first current), and when the maximum output value z is set, it copies from the reference PWM dimming table. Generate a table. Then, the second control unit 212b modifies the copy table based on the maximum output value z to generate a PWM dimming table for the second current. The second control unit 212b determines the duty ratio D of the second PWM signal, refers to the PWM dimming table for the second current, and sets the second output value.

The power supply circuit (power supply circuit composed of the first power supply circuit 21a and the second power supply circuit 21b) and the lighting fixture 2 according to the third embodiment have been described above with reference to FIG. According to the third embodiment, as in the first and second embodiments, a signal for controlling the amount of light of each color is given to a lighting fixture (lighting fixture 2) including lighting elements of two colors that generate light having different light colors from each other. In the lighting control system (lighting control system 1) to which (PWM signal) is input, an excessive amount of current is output from the power supply circuit (power supply circuit composed of the first power supply circuit 21a and the second power supply circuit 21b). Can be suppressed.

Further, the first control unit 212a and the second control unit 212b store the PWM dimming table having the characteristics described with reference to FIGS. 3 and 4 as in the first embodiment, thereby causing the first control unit 212a and the second control unit 212b. Even if the determination of the duty ratio D of the first PWM signal varies between the 212a and the second control unit 212b, it is possible to suppress the output of an excessive amount of current from the power supply circuit.

In the configuration shown in FIG. 6, the second control unit 212b specified the first output value based on the first PWM signal input from the first dimmer 3, but the first control unit 212a set the first output value. One output value may be output from the first control unit 212a to the second control unit 212b.

Further, although the second control unit 212b generates the copy table, the first control unit 212a may generate the copy table and output it to the second control unit 212b. In this case, the reference PWM dimming table may be omitted.

Further, the lighting control system 1 according to the third embodiment may include an output rating value adjuster 6 as in the second embodiment. When the lighting control system 1 includes the output rated value adjuster 6, the rated value adjusting signal is input to the second control unit 212b. According to this configuration, the output rated value x can be reduced to reduce the maximum output value z of the second current described with reference to FIG. Therefore, it is possible to further suppress the output of an excessive current from the power supply circuit at the time of color mixing. Alternatively, the output rated value x can be increased to increase the maximum output value z of the second current. Therefore, it is possible to expand the adjustment range of the amount of light generated from the second light source unit 24 at the time of color mixing.

Further, the rated value adjustment signal can be input to the first control unit 212a in addition to the second control unit 212b. By inputting the rated value adjustment signal to the first control unit 212a and the second control unit 212b, the output rated values of the first power supply circuit 21a and the second power supply circuit 21b can be made uniform. According to this configuration, the heat dissipation design of the luminaire 2 becomes easy.

The embodiments of the present invention have been described above with reference to the drawings. However, the present invention is not limited to the above-described embodiment, and can be implemented in various embodiments without departing from the gist thereof.

For example, in the embodiment according to the present invention, the commercial AC power source is illustrated as the AC power source 5, but the AC power source 5 is not limited to the commercial AC power source, and may be a private power generator or the like.

Further, in the embodiment according to the present invention, the first light source unit 23 and the second light source unit 24 are mounted on one substrate, but the present invention is not limited to this embodiment. The substrate on which the first light source unit 23 is mounted and the substrate on which the second light source unit 24 is mounted may be separate bodies.

Further, in the embodiment according to the present invention, the configuration in which the amount of light increases as the duty ratio D of the PWM signal increases (see FIGS. 3 and 4) has been described, but the present invention is not limited to this embodiment. The amount of light may decrease as the duty ratio D of the PWM signal increases.

Further, in the embodiment according to the present invention, the first light source unit 23 generates light having a light color different from that of the second light source unit 24, but the first light source unit 23 emits light having the same light color as the second light source unit 24. May be generated.

Further, in the embodiment according to the present invention, the PWM dimming table shows the amount of light discretely, but the PWM dimming table may show the amount of light continuously. In other words, the relationship between the duty ratio D of the PWM signal and the amount of light may be 1: 1.

Further, in the embodiment according to the present invention, the configuration in which the lighting control system 1 includes two dimmers (first dimmer 3 and second dimmer 4) has been described, but the present invention is not limited to this mode. .. The first PWM signal and the second PWM signal may be output from one dimmer.

Further, in the embodiment according to the present invention, a PWM signal is input to the luminaire 2 as a control signal for controlling the amount of light, but the present invention is not limited to this embodiment. As the control signal for controlling the amount of light, for example, a signal whose conduction angle is controlled (so-called phase dimming signal) or a digital signal such as a DALI signal may be used.

Further, in the embodiment according to the present invention, the PWM signal is input to the luminaire 2 as the rated value adjustment signal, but the present invention is not limited to this embodiment. As the rated value adjustment signal, for example, a signal whose conduction angle is controlled (so-called phase dimming signal) or a digital signal such as a DALI signal may be used.

Further, in the embodiment according to the present invention, the dimmer (first dimmer 3 and second dimmer 4) and the output rated value adjuster (output rated value adjuster 6) are separate bodies. The dimmer and the output rated value adjuster can be integrally formed.

1 Lighting control system 2 Lighting equipment 3 1st dimmer 4 2nd dimmer 6 Output rated value adjuster 21 Power supply circuit 21a 1st power supply circuit 21b 2nd power supply circuit 23 1st light source 24 2nd light source 211 Current Generation unit 211a 1st current generation unit 211b 2nd current generation unit 212 Control unit 212a 1st control unit 212b 2nd control unit 213a 1st lighting unit 213b 2nd lighting unit

Claims (6)

A first current for lighting the first light source unit is generated based on the first control signal output from the first dimmer, and a second current is generated based on the second control signal output from the second dimmer . A power supply circuit that generates a current that lights the light source.
Before Symbol a first current, a front Symbol lighting unit for generating a second current,
Before Symbol first control signal, before SL on the basis of a second control signal, and a control unit for controlling the lighting unit,
The first control signal is a signal that controls the amount of light generated from the first light source unit.
The second control signal is a signal that controls the amount of light generated from the second light source unit.
The control unit
The output value of the first current is set based on the first control signal, and the output value is set.
The maximum output value of the second current is set based on the preset output rated value and the output value of the first current.
A power supply circuit that sets an output value of the second current based on the second control signal and the maximum output value of the second current. The first control signal and the second control signal indicate control values that indicate the amount of light.
The control unit stores a table that defines the relationship between the amount of light and the control value.
The power supply circuit according to claim 1, wherein the table discretely indicates the amount of light. The power supply circuit according to claim 1 or 2, wherein the first control signal and the second control signal are pulse width modulated signals. The first light source unit that generates light and
The second light source that generates light and
A lighting fixture comprising the power supply circuit according to any one of claims 1 to 3. The lighting fixture according to claim 4, wherein the light generated from the first light source unit exhibits a light color different from the light generated from the second light source unit. A first current for lighting the first light source unit is generated based on the first control signal output from the first dimmer, and a second current is generated based on the second control signal output from the second dimmer . It is a control method of a power supply circuit that generates a second current that lights the light source unit.
Before SL on the basis of the first control signal, a step of setting an output value of said first current,
A step of setting the maximum output value of the second current based on the preset output rated value and the output value of the first current, and
Encompasses the previous SL second control signal, based on the maximum output value of the second current, and setting the output value of the second current,
The first control signal is a signal that controls the amount of light generated from the first light source unit.
The power supply control method , wherein the second control signal is a signal for controlling the amount of light generated from the second light source unit.

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