JP2016219147A - Light source control circuit and illumination device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light source control circuit and illumination device that are capable of adjusting a light flux or color temperature of light emitted by a light source, with a simple circuit configuration.SOLUTION: A light source control circuit 3 includes: a power generation unit 5 for generating DC power to be supplied to an LED 21 and an LED 22 for emitting light having a color temperature different from that of the LED 21, from a commercial AC power source; and a color control setting circuit 71 that comprises a variable resistor 711 for distributing the power generated by the power generation unit 5 to the LED 21 and LED 22 in order to control light emitted by a light source 2 including the LED 21 and LED 22, and makes the sum of the current value of first supply current I1 supplied to the LED 21 and the current value of second supply current I2 supplied to the LED 22 be constant at least in a certain color temperature range even when the color temperature of controlled light has changed.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a light source control circuit and a lighting device for dimming a light beam emitted from a light source and for adjusting a color.

  There is known a light emitting diode (LED) illumination system in which the color temperature of light emitted from a light source changes according to a change in light intensity (for example, Patent Document 1).

JP 2014-216124 A

Conventionally, a circuit for adjusting the color of light emitted from a light source requires a circuit for driving light emitting elements having different emission colors. Therefore, the conventional circuit has a problem that the circuit configuration becomes complicated and the manufacturing cost increases.
An object of the present invention is to provide a light source control circuit and an illuminating device that can adjust the luminous flux and color temperature of light emitted from a light source with a simple circuit configuration.

A light source control circuit according to an aspect of the present invention includes a power generation unit that generates DC power supplied from a commercial AC power source to a first light emitting element and a second light emitting element that generates light having a color temperature different from that of the first light emitting element. And the first light emitting element for distributing the power generated by the power generation unit to the first light emitting element and the second light emitting element in order to adjust the light generated by the light source including the first and second light emitting elements. 1 variable resistor, and even if the color temperature of the toned light changes, at least in a certain color temperature range, the current value of the first supply current supplied to the first light emitting element and the second light emitting element And a toning setting circuit having a constant sum with a current value of the second supply current to be supplied.
An illumination device according to an aspect of the present invention includes the light source including the first and second light emitting elements connected in parallel, and the light source control circuit according to the above aspect.

  According to one embodiment of the present invention, the light flux and color temperature of light emitted from a light source can be adjusted with a simple circuit configuration while suppressing costs.

It is a circuit block diagram which shows an example of schematic structure of the light source control circuit and illuminating device by one Embodiment of this invention. It is a figure explaining the light source control circuit by one Embodiment of this invention, Comprising: It is a graph which shows an example of the relationship between a toning setting ratio and a current ratio. It is a figure explaining the light source control circuit by one Embodiment of this invention, Comprising: It is a graph which shows an example of the relationship between the resistance value of the synthetic | combination resistance of a light control setting circuit, and the light beam of a light source.

A light source control circuit and a lighting device according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a circuit block diagram illustrating an example of a schematic configuration of the light source control circuit 3 and the illumination device 1 according to the present embodiment.
As shown in FIG. 1, the illumination device 1 according to the present embodiment includes a light source 2 and a light source control circuit 3 that controls the light source 2. The light source 2 includes an LED (an example of a first light emitting element) 21 and an LED (an example of a second light emitting element) 22 connected in parallel to the LED 21. In the present embodiment, the LEDs 21 and 22 are used as the light emitting elements included in the light source 2. However, in addition to the LEDs, an organic electroluminescence element or a laser diode (semiconductor laser) may be used. The LED 21 and the LED 22 emit light having different color temperatures. For example, the LED 21 has a color temperature of 2700 K and is configured to emit light bulb-colored light. The LED 22 has a color temperature of, for example, 5700K and is configured to emit white light. For this reason, the illuminating device 1 can emit light of an intermediate color obtained by mixing a light bulb color, white color, and both colors.

The light source control circuit 3 according to the present embodiment is provided in front of the power generation unit 5 that generates DC power to be supplied to the LEDs 21 and 22 from AC 100 V (commercial AC power supply), and the toning setting circuit 71 and the toning setting circuit 71. And a light adjustment / color adjustment circuit 7 that adjusts the luminous flux and color temperature of the light emitted from the light source 2.
The power generation unit 5 controls an AC / DC (AC / DC) conversion circuit 51 that converts an AC voltage of 100 V into a DC voltage having a predetermined potential, an LED driver circuit 55 that drives the light source 2, and the LED driver circuit 55. The LED driver control circuit 53 and a feedback circuit 57 for feedback controlling the voltage output from the LED driver circuit 55 are provided.
The AC / DC converter circuit 51 includes a bridge rectifier circuit (not shown) that rectifies an AC voltage signal, a smoothing circuit (not shown) that smoothes the voltage signal rectified by the bridge rectifier circuit, and various other circuits (not shown). (Shown). The AC / DC conversion circuit 51 outputs the smoothed DC voltage signal and DC current signal to the LED driver circuit 55.

  The LED driver circuit 55 is configured to generate a drive voltage and a drive current that can drive the LED 21 and the LED 22 included in the light source 2 from the DC voltage signal and the DC current signal input from the AC / DC conversion circuit 51. ing. The LED driver circuit 55 includes, for example, a step-down converter (not shown) connected to the AC / DC conversion circuit 51. This step-down converter connects or disconnects a coil (not shown) that stores energy by a DC voltage signal and a DC current signal input from the AC / DC conversion circuit 51, and the coil and the AC / DC switching circuit 51. A first switch circuit (not shown), a second switch circuit (not shown) provided between a connection between the first switch circuit and the coil and the ground, and a DC signal output from the coil is smoothed And a smoothing circuit (not shown). The on / off state of the first switch circuit and the second switch circuit is controlled by an LED driver control circuit 53 described later. When the first switch circuit is on, the second switch circuit is off, and when the first switch circuit is off, the second switch circuit is on. The LED driver circuit 55 may include a diode in which the cathode is connected to the connection portion between the first switch circuit and the coil, and the anode is connected to the ground, instead of the second switch circuit.

  When the first switch circuit is controlled to be turned on and the second switch circuit is controlled to be turned off, the LED driver circuit 55 stores the DC voltage signal input from the AC / DC converter circuit 51 in the coil of the step-down converter. At the same time, a drive voltage and a drive current are generated from the DC voltage signal and output to the light source 2. As a result, the LED driver circuit 55 causes the light sources 2 to emit light by causing current to flow through the LEDs 21 and 22 and accumulates predetermined energy in the coil of the step-down converter.

  When the first switch circuit is controlled to be turned off and the second switch circuit is controlled to be turned on, the LED driver circuit 55 is disconnected from the AC / DC conversion circuit 51, and the step-down converter includes a coil, a smoothing circuit, and A closed circuit is formed by the second switch circuit. Thereby, the LED driver circuit 55 can discharge the energy accumulated in the coil of the step-down converter to the light source 2. When the first switch circuit provided in the LED driver circuit 55 is in the OFF state and the second switch circuit is in the ON state, the induced electromotive force generated based on the DC voltage applied to the coil is the LED 21, 22. Becomes a driving voltage for driving. In this case, the induced current generated in the coil based on the direct current input to the step-down converter becomes the drive current for driving the LEDs 21 and 22. When the first switch circuit is switched to the OFF state, the current path of the current input from the AC / DC conversion circuit 51 to the LED driver circuit 55 is interrupted. For this reason, since the LED driver circuit 55 cannot store energy in the coil of the step-down converter during the period when the first switch circuit is switched to the OFF state, the coil energy gradually decreases, and the drive voltage output from the coil The voltage value and the current value of the drive current gradually decrease.

  The LED driver control circuit 53 controls the LED driver circuit 55 so as to output a desired drive voltage and drive current to the light source 2. The LED driver control circuit 53 controls the on / off states of the first and second switch circuits provided in the LED driver circuit 55. When the voltage output from the LED driver circuit 55 becomes lower than a predetermined voltage, the LED driver control circuit 53 switches the first switch circuit provided in the LED driver circuit 55 to the on state again and turns off the second switch circuit. Switch to state. As a result, the LED driver circuit 55 outputs the DC voltage signal input from the AC / DC conversion circuit 51 to the LEDs 21 and 22 again to cause the light source 2 to emit light, and uses this DC voltage signal to the coil of the step-down converter. Accumulate energy. As described above, the LED driver control circuit 53 drives the on-state and the off-state of the first and second switch circuits provided in the LED driver circuit 55 by pulse width modulation (PWM) to drive the LED driver circuit 55. And the LED driver circuit 55 generates a predetermined drive voltage and drive current.

  The LED driver control circuit 53 is configured to perform feedback control of the on-state period of the MOSFET based on the feedback signal input from the feedback circuit 57. Although details will be described later, the feedback signal is a signal based on the drive voltage output from the LED driver circuit 55. When the LED driver control circuit 53 compares the feedback signal with a predetermined reference signal and determines that the voltage value of the feedback signal is lower than the voltage value of the reference signal, the LED driver control circuit 53 controls the MOSFET to be on longer. . As a result, the energy accumulated in the step-down converter of the LED driver circuit 55 increases, the induced electromotive force generated in the coil of the step-down converter increases, and the induced current increases. For this reason, the drive voltage of the LEDs 21 and 22 increases and the drive current increases.

On the other hand, when the LED driver control circuit 53 determines that the voltage value of the feedback signal is higher than the voltage value of the reference signal, the LED driver control circuit 53 performs control so that the period of the ON state of the MOSFET is shortened. As a result, the energy accumulated in the step-down converter of the LED driver circuit 55 is reduced, the induced electromotive force generated in the coil of the step-down converter is reduced, and the induced current is reduced. For this reason, the drive voltage of the LEDs 21 and 22 decreases and the drive current decreases.
As described above, the LED driver control circuit 53 is configured to feedback control the drive voltage and the drive current for driving the LEDs 21 and 22 using the feedback signal based on the drive voltage output from the LED driver circuit 55. Thereby, the LED driver control circuit 53 can maintain the voltage value of the drive voltage output from the LED driver circuit 55 and the current value of the drive current at a constant value.

  The feedback circuit 57 is configured to generate a feedback signal based on the drive voltage output from the LED driver circuit 55 and at least one of the cathode side voltages of the LEDs 21 and 22. The feedback circuit 57 outputs a voltage signal of a difference between the drive voltage output from the LED driver circuit 55 and at least one of the cathode side voltages of the LEDs 21 and 22 to the LED driver control circuit 53 as a feedback signal. ing. In the present embodiment, the feedback circuit 57 also functions as a protection circuit for the light source 2.

  The light adjustment / color adjustment circuit 7 provided in the light source control circuit 3 includes a power supply voltage application terminal 777 to which an output voltage of the LED driver circuit 55 serving as a power supply voltage of the light adjustment / color adjustment circuit 7 is applied, and a reference potential ( For example, a light control setting circuit 77 including a reference potential application terminal 779 to which a ground potential is applied is provided. The dimming setting circuit 77 includes a resistor 771, a resistor 773, and a variable resistor (an example of a second variable resistor) 775 that are connected in series between the power supply voltage application terminal 777 and the reference potential application terminal 779. . The variable resistor 775 is provided to increase or decrease the luminous flux of light generated from the light source 2 and toned by a toning setting circuit 71 (details will be described later). The variable resistor 775 has one terminal provided on the later-described current input terminal 715 side and the other terminal provided on the reference potential application terminal 779 side. The variable resistor 775 is connected to the anodes of the LEDs 21 and 22 through a resistor 773, a resistor 771, and a power supply voltage application terminal 777. One terminal of the resistor 771 is connected to the power supply voltage application terminal 777, and the other terminal of the resistor 771 is connected to one terminal of the resistor 773. One terminal of the variable resistor 775 is connected to the other terminal of the resistor 773, and the other terminal of the variable resistor 775 is connected to the reference potential application terminal 779. The resistor 773 is provided to prevent a power supply voltage application terminal 777, which will be described later, from being directly connected to the reference potential application terminal 779 even when the resistance value of the variable resistor 775 is set to 0Ω. An output voltage of the LED driver circuit 55 is applied to the resistor 771, and a reference potential is applied to the variable resistor 775. Here, dimming means changing the luminous flux of the entire light source by adjusting the current flowing through the light emitting element. In the present embodiment, the current flowing through the LED 21 and the LED 22 is adjusted to adjust the light flux of the entire light source 2. That is, in the present embodiment, the luminance of the entire light source 2 is dimmed by adjusting the currents flowing through the LEDs 21 and 22 respectively. The dimming setting circuit 77 is connected to the LEDs 21 and 22 in parallel with respect to the output of the LED driver circuit 55.

  The light control / color control circuit 7 according to the present embodiment supplies the first current adjustment circuit 73 that adjusts the current value of the first supply current I1 supplied to the LED 21 and the LED 22 that emits light having a color temperature different from that of the LED 21. And a second current adjustment circuit 75 that adjusts the current value of the second supply current I2. The light adjustment / color adjustment circuit 7 includes a color adjustment setting circuit 71 including a variable resistor (an example of a first variable resistor) 711. Even if the color temperature of the toned light changes, the toning setting circuit 71 has a current value of the first supply current I1 supplied to the LED 21 and a second supply current I2 supplied to the LED 22 at least within a certain color temperature range. The sum of the current value and the current value is constant. The variable resistor 711 is provided for distributing the power generated by the power generation unit 5 to the LEDs 21 and 22 in order to adjust the light generated by the light source 2 including the LEDs 21 and 22. The variable resistor 711 has, for example, three terminals: both terminals (one terminal and another terminal) and a tap for setting a resistance value. One terminal (an example of one terminal) of the variable resistor 711 is connected to the first current adjustment circuit 73, and the other terminal (an example of another terminal) of the variable resistor 711 is connected to the second current adjustment circuit 75. Has been. Here, toning refers to changing the emission color of the entire light source by adjusting the current flowing through two light emitting elements having different color temperatures. In the present embodiment, the currents flowing through the LED 21 that emits light bulb color light and the LED 22 that emits white light are adjusted to adjust the emission color of the entire light source 2.

  The toning setting circuit 71 includes a reference potential application terminal 716 to which a reference potential (for example, ground potential) is applied, and a current input terminal (third supply current) to which the third supply current I3 supplied from the power generation unit 5 is input. An example of an input terminal) 715. The third supply current I3 is a part of the current generated by the power generation unit 5. A voltage having a higher potential than the reference potential is applied to the current input terminal 715. The reference potential application terminal 716 is connected to the reference potential application terminal 779. The current input terminal 715 is connected to the dimming setting circuit 77. More specifically, the current input terminal 715 is connected to a connection point between the resistor 771 and the resistor 773 provided in the dimming setting circuit 77. The current input terminal 715 has a resistor 771, a resistor 773, and a variable resistor 775 (hereinafter referred to as “a potential difference between a drive voltage output from the LED driver circuit 55 and a reference potential” applied to the power supply voltage application terminal 777. The voltage divided by the resistance is applied in some cases (referred to as “combined resistance of dimming setting circuit 77”).

  The toning setting circuit 71 includes a resistor (an example of a first resistor) 712 connected between the current input terminal 715 and one terminal of the variable resistor 711, a current input terminal 715, and a variable resistor 711. And a resistor (an example of a second resistor) 713 connected to the other terminal. Further, the toning setting circuit 71 includes a resistor 714 connected between the tap of the variable resistor 711 and the reference potential application terminal 716. The resistor 714 is provided so that the terminal on which the tap is moved is not directly connected to the reference potential application terminal 716 even if the tap of the variable resistor 711 is moved to one terminal or the other terminal. The third supply current I3 input to the current input terminal 715 flows into the reference potential application terminal 716 through the resistors 712, 713, the variable resistor 711, and the resistor 714 connected in parallel, and flows to the ground.

  The first current adjustment circuit 73 includes an amplifier (an example of a first amplifier) 731 that amplifies the voltage applied to one terminal of the variable resistor 711, and the first supply current I1 based on the amplified voltage amplified by the amplifier 731. It has an Nch (N-channel) FET (an example of a first transistor) 733 for adjusting the current value, and a resistor 735 connected to the source terminal S of the FET 733. More specifically, the non-inverting input terminal (+) of the amplifier 731 is connected to one terminal of the variable resistor 711, that is, a connection point between the one terminal of the variable resistor 711 and the resistor 712, and the inverting input terminal of the amplifier 731. (−) Is connected to the source terminal S of the FET 733, and the output terminal of the amplifier 731 is connected to the gate terminal G of the FET 733. The drain terminal D of the FET 733 is connected to the cathode of the LED 21. One terminal of the resistor 735 is connected to the source terminal S of the FET 733, and the other terminal of the resistor 735 is connected to the ground that is the reference potential.

  The non-inverting input terminal (+) of the amplifier 731 has a potential difference between the potential of the current input terminal 715 and the potential of the reference potential application terminal 716, a resistance between the resistor 712 and one terminal of the variable resistor 711 and the tap. (Hereinafter referred to as “one-terminal-side resistor”) and the resistor 714 are applied with a resistance-divided voltage. For this reason, the voltage input to the non-inverting input terminal (+) of the amplifier 731 is changed according to the resistance value of the one-terminal resistance of the set variable resistor 711. Since the amplifier 731 is configured to function as a voltage follower circuit, the voltage input to the non-inverting input terminal (+) is output to the gate terminal G of the FET 733. In the FET 733, the drain-source current changes according to the voltage input to the gate terminal G. Since the resistor 735 is a fixed resistor, the potential of the source terminal S is constant regardless of the gate voltage applied to the gate terminal G of the FET 733. Since the FET 733 is an Nch transistor, when the voltage value of the gate voltage input to the gate terminal G increases, the current value of the drain-source current increases.

  The combined resistance of the resistors 712, 713, the variable resistor 711, and the resistor 714 (hereinafter referred to as “the combined resistor of the toning setting circuit 71”) is not changed even if the tap position of the variable resistor 711 is changed. Therefore, when the resistance value set by the variable resistor 775 of the dimming setting circuit 77 (hereinafter, the resistance value set by the variable resistor 711 or the variable resistor 775 is referred to as “set resistance value”) is not changed. The current value of the third supply current I3 input to the current input terminal 715 is constant regardless of the tap position of the variable resistor 711. For this reason, when the set resistance value of the variable resistor 775 is not changed, the voltage of the current input terminal 715 does not fluctuate and remains at a predetermined value even if the tap position of the variable resistor 711 is changed. The voltage value at the connection point between one terminal of the variable resistor 711 and the resistor 712 varies depending on the tap position of the variable resistor 711.

  When the tap of the variable resistor 711 is brought closer to the other terminal side, the resistance value of the combined resistance of the one-terminal resistance of the variable resistor 711 and the resistor 714 increases. As a result, the voltage value at the connection point between one terminal of the variable resistor 711 and the resistor 712 is high when the set resistance value of the variable resistor 775 is fixed, that is, when the variable resistor 775 is not moved. For this reason, the voltage value of the voltage input to the non-inverting input terminal (+) of the amplifier 731 is increased, and the output voltage of the amplifier 731 and the voltage value of the gate voltage input to the gate terminal G of the FET 733 are also increased. Thereby, the current value of the drain-source current of the FET 733 increases. Since the FET 733 and the LED 21 are connected in series, the drain-source current of the FET 733 becomes the first supply current I1 supplied to the LED 21. Therefore, when the current value of the drain-source current of the FET 733 increases, the current value of the first supply current I1 supplied to the LED 21 also increases.

  On the other hand, when the tap of the variable resistor 711 is brought closer to one terminal side, the resistance value of the combined resistance of the resistor 714 and the resistance between the one terminal and the tap of the variable resistor 711 becomes low. As a result, the voltage value at the connection point between one terminal of the variable resistor 711 and the resistor 712 is low when the set resistance value of the variable resistor 775 is fixed, that is, when the variable resistor 775 is not moved. For this reason, the voltage value of the voltage inputted to the non-inverting input terminal (+) of the amplifier 731 is lowered, and the output voltage of the amplifier 731 and the voltage value of the gate voltage inputted to the gate terminal G of the FET 733 are also lowered. As a result, the current value of the drain-source current of the FET 733 decreases, and the current value of the first supply current I1 supplied to the LED 21 also decreases.

  The second current adjustment circuit 75 includes an amplifier (an example of a second amplifier) 751 that amplifies the voltage applied to the other terminal of the variable resistor 711, and the second supply current I2 based on the amplified voltage amplified by the amplifier 751. It has FET (an example of a 2nd transistor) 753 which adjusts an electric current value, and the resistance 755 connected to the source terminal S of FET753. More specifically, the non-inverting input terminal (+) of the amplifier 751 is connected to the other terminal of the variable resistor 711, that is, the connection point between the other terminal of the variable resistor 711 and the resistor 713, and the inverting input terminal of the amplifier 751. (−) Is connected to the source terminal S of the FET 753, and the output terminal of the amplifier 751 is connected to the gate terminal G of the FET 753. The drain terminal D of the FET 753 is connected to the cathode of the LED 22. One terminal of the resistor 755 is connected to the source terminal S of the FET 753, and the other terminal of the resistor 755 is connected to the ground that is the reference potential.

  The non-inverting input terminal (+) of the amplifier 751 has a potential difference between the potential of the current input terminal 715 and the potential of the reference potential application terminal 716, and a resistance between the resistor 713 and the other terminal of the variable resistor 711 and the tap. (Hereinafter referred to as “other terminal side resistor”) and the resistor 714 are applied with a resistance-divided voltage. For this reason, the voltage input to the non-inverting input terminal (+) of the amplifier 751 is changed in accordance with the resistance value of the other-terminal resistance of the variable resistor 711 that has been set. Since the amplifier 751 is configured to function as a voltage follower circuit, the voltage input to the non-inverting input terminal (+) is output to the gate terminal G of the FET 753. In the FET 753, the drain-source current changes according to the voltage input to the gate terminal G. Since the resistor 755 is a fixed resistor, the potential of the source terminal S is constant regardless of the gate voltage applied to the gate terminal G of the FET 753. Since the FET 753 is an Nch transistor, when the voltage value of the gate voltage input to the gate terminal G increases, the current value of the drain-source current increases.

  As described above, when the set resistance value of the variable resistor 775 is not changed, the current value of the third supply current I3 input to the current input terminal 715 is constant regardless of the tap position of the variable resistor 711. Become. For this reason, when the set resistance value of the variable resistor 775 is not changed, the voltage of the current input terminal 715 does not fluctuate and remains at a predetermined value even if the tap position of the variable resistor 711 is changed. The voltage value at the connection point between the other terminal of the variable resistor 711 and the resistor 713 varies depending on the tap position of the variable resistor 711.

  When the tap of the variable resistor 711 is brought closer to one terminal side, the resistance value of the combined resistance of the other terminal side resistor of the variable resistor 711 and the resistor 714 increases. As a result, the voltage value at the connection point between one terminal of the variable resistor 711 and the resistor 713 is high when the set resistance value of the variable resistor 775 is fixed, that is, when the variable resistor 775 is not moved. For this reason, the voltage value of the voltage input to the non-inverting input terminal (+) of the amplifier 751 is increased, and the output voltage of the amplifier 751 and the voltage value of the gate voltage input to the gate terminal G of the FET 753 are also increased. As a result, the current value of the drain-source current of the FET 753 increases. Since the FET 753 and the LED 22 are connected in series, the drain-source current of the FET 753 becomes the second supply current I2 supplied to the LED 22. Therefore, when the current value of the drain-source current of the FET 753 increases, the current value of the second supply current I2 supplied to the LED 22 also increases.

  On the other hand, when the tap of the variable resistor 711 is brought closer to the other terminal side, the resistance value of the combined resistance of the other terminal side resistor of the variable resistor 711 and the resistor 714 becomes lower. As a result, the voltage value at the connection point between the other terminal of the variable resistor 711 and the resistor 713 is low when the set resistance value of the variable resistor 775 is fixed, that is, when the variable resistor 775 is not moved. For this reason, the voltage value of the voltage inputted to the non-inverting input terminal (+) of the amplifier 751 is lowered, and the output voltage of the amplifier 751 and the voltage value of the gate voltage inputted to the gate terminal G of the FET 733 are also lowered. Thereby, the current value of the drain-source current of the FET 753 is reduced, and the current value of the second supply current I2 supplied to the LED 22 is also reduced.

  When the tap of the variable resistor 711 approaches the other terminal side, the resistance value of the one-terminal resistance of the variable resistor 711 increases, and the resistance value of the other-terminal resistance of the variable resistor 711 decreases. On the other hand, when the tap of the variable resistor 711 approaches the one terminal side, the resistance value of the one-terminal side resistance of the variable resistor 711 decreases and the resistance value of the other-terminal side resistance of the variable resistor 711 increases. As described above, the resistance value of the one-terminal resistance of the variable resistor 711 and the resistance value of the other-terminal resistance of the variable resistor 711 are changed in conjunction with each other according to the tap position. Therefore, according to the change of the tap of the variable resistor 711, the voltage input to the second current adjustment circuit 75 decreases as the voltage input to the first current adjustment circuit 73 increases, and the voltage input to the first current adjustment circuit 73 decreases. The voltage input to the second current adjustment circuit 75 increases as the voltage to be applied decreases. The tap of the variable resistor 711 can be operated by the user of the lighting device 1. Therefore, the user adjusts the current value of the first supply current I1 supplied to the LED 21 and the current value of the second supply current I2 supplied to the LED 22 by operating the tap of the variable resistor 711. In addition, the emission color of the light source 2 can be set to a desired color.

  Even if the tap position of the variable resistor 714 is the same, the voltage input to the first and second current adjustment circuits 73 and 75 becomes higher when the voltage value of the current input terminal 715 is higher, and the voltage value of the current input terminal 715 becomes higher. Low is low. Since the resistance value of the combined resistance of the toning setting circuit 71 is constant, the voltage value of the current input terminal 715 increases as the current value of the third supply current I3 input to the current input terminal 715 increases, and the current input terminal 715 increases. As the current value of the third supply current I3 input to the voltage decreases, the current value decreases. The current value of the current input from the power generation unit 5 to the power supply voltage application terminal 777 is substantially constant. For this reason, the current value of the third supply current I3 varies according to the set resistance value of the variable resistor 775.

  When the set resistance value of the variable resistor 775 is increased, the resistance value of the combined resistor of the resistor 773 and the variable resistor 775 is relatively increased. As a result, the current input to the power supply voltage application terminal 777 is less likely to flow to the resistor 773 and the variable resistor 775 side, but easily flows to the current input terminal 715 side. On the other hand, when the set resistance value of the variable resistor 775 becomes low, the resistance value of the combined resistance of the resistor 773 and the variable resistor 775 becomes relatively low. As a result, the current input to the power supply voltage application terminal 777 tends to flow toward the resistor 773 and the variable resistor 775 side, but hardly flows toward the current input terminal 715 side. For this reason, the current value of the third supply current I3 increases as the set resistance value of the variable resistor 775 increases, and decreases as the set resistance value of the variable resistor 775 decreases. As a result, the voltage at the connection point between the resistor 771 and the resistor 773, that is, the voltage applied to the current input terminal 715 becomes higher when the set resistance value of the variable resistor 775 is high, and the set resistance value of the variable resistor 775 becomes higher. Low is low.

  Therefore, when the set resistance value of the variable resistor 775 is set to a relatively high value, the light control / color control circuit 7 increases the luminous flux relatively in a state where the color temperature of the light emission color of the light source 2 is fixed. can do. Further, when the set resistance value of the variable resistor 775 is set to a relatively low value, the light adjustment / color adjustment circuit 7 reduces the luminous flux relatively in a state where the color temperature of the light emission color of the light source 2 is fixed. can do. The third supply current I3 exhibits a function as a bias current that increases or decreases the light flux of the toned light. For example, light with a low color temperature tends to have less luminous flux than light with a high color temperature. For this reason, when the color temperature of the toned light is relatively low, the luminous flux of the toned light is increased by increasing the current amount of the third supply current I3, and the set light can be relatively brightened. it can.

  The variable resistor 714 and the variable resistor 775 can be operated by the user of the lighting device 1. For this reason, the user can set the emission color of the light source 2 to a desired color temperature by operating the variable resistor 714 and operate the variable resistor 775 to maintain the set color temperature. The luminous flux of the LED and the luminous flux of the LED 22 can be increased or decreased in conjunction with each other. The light source control circuit 3 according to the present embodiment includes the color adjustment setting circuit 71 and the light adjustment setting circuit 77 configured by resistors and variable resistors, so that the color temperature and light flux of the light source 2 can be changed with a simple circuit configuration. .

  Here, the relationship between the set resistance value of the variable resistor 711 and the first and second supply currents I1 and I2 will be described with reference to FIG. FIG. 2 shows the first and second supply currents I1 with respect to the current value of the total supply current Isum obtained by adding the set resistance value of the variable resistor 711 and the first and second supply currents I1 and I2 supplied to the LEDs 21 and 22. , I2 is a graph showing an example of the relationship with the current ratio. The horizontal axis indicates the toning setting ratio. The toning setting ratio is the resistance value of one terminal side resistance of the variable resistor 711 (hereinafter referred to as “one terminal side resistance value VR1”) and the resistance value of the other terminal side resistance (hereinafter referred to as “other terminal side resistance value VR2”). ")"). The vertical axis represents the current ratio Ix / Isum between the current value of the total supply current Isum and the current value of one of the first and second supply currents I1 and I2 (x is 1 or 2). ing. “L1” shown in FIG. 2 represents a current ratio characteristic in the first supply current I1, “L2” represents a current ratio characteristic in the second supply current I2, and “Lsum” represents the total supply current Isum. Represents the characteristics.

  As shown in FIG. 2, the current ratio L1 in the first supply current I1 and the current ratio L2 in the second supply current I2 both have a characteristic that increases and decreases linearly by changing the toning setting ratio. . When the toning setting ratio is “one-terminal-side resistance value VR1: other-terminal-side resistance value VR2 = 0: 10”, the current ratio L1 in the first supply current I1 is set to 0.1, and the second supply current I2 The current ratio L2 is set to 0.9. The light adjustment / color adjustment circuit 7 includes a resistor 714 connected to the reference potential application terminal 716 in the color adjustment setting circuit 71. For this reason, even if the one-terminal resistance value VR1 of the variable resistor 711 is set to 0Ω, a predetermined voltage is generated at the connection point between the one-terminal resistance of the variable resistor 711 and the resistor 712. Thereby, a gate voltage is applied to the gate terminal G of the FET 733 with a current ratio I1 / Isum of the current value of the first supply current I1 to the current value of the total supply current Isum being 0.1. On the other hand, the light adjustment / color adjustment circuit 7 has a resistor 713 connected to the current input terminal 715 in the color adjustment setting circuit 71. For this reason, even if the one-terminal resistance value VR1 of the variable resistor 711 is set to 0Ω and the other-terminal resistance value VR2 is set to the maximum resistance value, the other-terminal resistance and the resistance 713 of the variable resistor 711 A predetermined voltage lower than the voltage applied to the current input terminal 715 is generated at the connection point. As a result, a gate voltage with a current ratio I2 / Isum of the current value of the second supply current I2 to the current value of the total supply current Isum being 0.9 is applied to the gate terminal G of the FET 753. In this case, the luminous flux of the LED 21 is the minimum value within the settable range, and the luminous flux of the LED 22 is the maximum value within the settable range. For this reason, the light emission color of the entire light source 2 becomes white because the color of the light emitted from the LED 22 is dominant.

  When the toning setting ratio is “one-terminal-side resistance value VR1: other-terminal-side resistance value VR2 = 1: 1”, the current ratio L1 in the first supply current I1 is 0.5, and the current ratio in the second supply current I2 L2 is 0.5. In this case, the luminous flux of the LED 21 is ½ of the settable range, and the luminous flux of the LED 22 is ½ of the settable range. For this reason, the color of light emitted from the LED 21 and the color of light emitted from the LED 22 are almost equally mixed and become an intermediate color.

  When the toning setting ratio is “one-terminal-side resistance value VR1: other-terminal-side resistance value VR2 = 10: 0”, the current ratio L1 in the first supply current I1 is set to 0.9, and the second supply current I2 The current ratio L2 is set to 0.1. Even if the resistance value VR2 on the other terminal side of the variable resistor 711 is set to 0Ω, a predetermined voltage is generated at the connection point between the resistance on the other terminal side of the variable resistor 711 and the resistor 713. As a result, a gate voltage with a current ratio I2 / Isum of the current value of the second supply current I2 to the current value of the total supply current Isum being 0.1 is applied to the gate terminal G of the FET 753. On the other hand, the light adjustment / color adjustment circuit 7 has a resistor 712 connected to the current input terminal 715 in the color adjustment setting circuit 71. For this reason, even if the other-terminal resistance value VR2 of the variable resistor 711 is set to 0Ω and the one-terminal resistance value VR1 is set to the maximum resistance value, the one-terminal resistance of the variable resistor 711 and the resistance 712 A predetermined voltage lower than the voltage applied to the current input terminal 715 is generated at the connection point. As a result, a gate voltage is applied to the gate terminal G of the FET 733 with a current ratio I1 / Isum of the current value of the first supply current I1 to the current value of the total supply current Isum being 0.9. In this case, the luminous flux of the LED 21 is the maximum value within the settable range, and the luminous flux of the LED 22 is the minimum value within the settable range. For this reason, the color of light emitted from the LED 21 is dominant and the color of light emitted from the entire light source 2 becomes a light bulb color.

  Even if the toning setting ratio is changed, since the current value of one of the first supply current I1 and the second supply current I2 increases and the other current value decreases, the current value of the total supply current Isum is It becomes constant. In addition, since the toning setting circuit 71 includes the resistor 714 (see FIG. 1), even if one of the one-terminal side resistance value VR1 and the other-terminal side resistance value VR2 is set to “0”, the first and Since a voltage is input to the second current adjustment circuits 73 and 75, a current is always supplied to the LED 21 or the LED 22. Therefore, the toning setting circuit 71 sets the toning setting ratio to “one terminal side resistance value VR1: other terminal side resistance value VR2 = 0: 10” or “one terminal side resistance value VR1: other terminal side resistance value VR2 = 10: 0 ”, the current ratio L1 in the first supply current I1 or the current ratio L2 in the second supply current I2 is set not to“ 0 ”but to“ 0.1 ”. .

  Next, the relationship between the resistance value of the combined resistance of the dimming setting circuit 77 and the luminous flux of the light source 2 will be described with reference to FIG. FIG. 3 illustrates the combined resistance of the dimming setting circuit 77 in a state where the toning setting ratio of the variable resistor 711 is set to any value and is not changed (hereinafter referred to as “fixed state of toning setting ratio”). It is a graph which shows an example of the relationship between resistance value and the light beam of the light source 2 whole. The luminous flux of the entire light source 2 is a luminous flux obtained by combining the luminous flux of the LED 21 and the luminous flux of the LED 22. The horizontal axis indicates the ratio (%) of the set resistance value to the maximum resistance value of the combined resistance of the dimming setting circuit 77, and the vertical axis indicates the luminous flux (lm) of the entire light source 2.

  As shown in FIG. 3, the luminous flux of the entire light source 2 has a characteristic that increases or decreases linearly by changing the ratio of the set resistance value to the maximum resistance value of the combined resistance of the dimming setting circuit 77. Yes. When the set resistance value of the variable resistor 775 is set to 0Ω, the luminous flux of the entire light source 2 becomes the minimum value (min) in the fixed state of the toning setting ratio. The dimming setting circuit 77 has a resistor 773 connected between the resistor 771 and the variable resistor 775. For this reason, even if the setting resistance value of the variable resistor 775 is set to 0Ω, the resistance value of the combined resistance of the dimming setting circuit 77 is not 0% of the maximum value of the combined resistance of the dimming setting circuit 77. For example, the value is 5%. For this reason, even if the set resistance value of the variable resistor 775 is set to 0Ω, all of the current input to the power supply voltage application terminal 777 does not flow to the variable resistor 775 side but also flows to the current input terminal 715 side. For this reason, a predetermined voltage is generated at the connection point between the resistor 771 and the resistor 773, and this predetermined voltage is applied to the current input terminal 715. Thereby, a voltage at which the FET 733 and the FET 751 are turned on is applied to the respective gate terminals G of the FET 733 and the FET 751. However, since the resistance value of the combined resistance of the dimming setting circuit 77 in this case is the minimum value in the fixed state of the toning setting ratio, the voltages applied to the gate terminals G of the FET 733 and the FET 751 are also the minimum value. Become. Thereby, since the current values of the first supply current I1 and the second supply current I2 become the minimum values in the fixed state of the toning setting ratio, the LED 21 and the LED 22 emit light, but the light flux of the entire light source 2 This is the minimum value when the setting ratio is fixed.

  When the set resistance value of the variable resistor 775 is set to the maximum value, the luminous flux of the entire light source 2 becomes the maximum value (max) in the fixed state of the toning setting ratio. When the setting resistance value of the variable resistor 775 is set to the maximum value, the resistance value of the combined resistance of the dimming setting circuit 77 becomes the maximum value. Therefore, the resistance value of the combined resistance of the dimming setting circuit 77 when the set resistance value of the variable resistor 775 is the maximum value is equal to the maximum value of the combined resistance of the dimming setting circuit 77, and the ratio of both resistance values is 100. %. Thereby, when the set resistance value of the variable resistor 775 is set to the maximum value, the current value of the current flowing to the current input terminal 715 side (ie, the third supply current I3) among the currents input to the power supply voltage application terminal 777. Is the maximum. For this reason, the maximum voltage in a fixed state of the toning setting ratio is generated at the connection point between the resistor 771 and the resistor 773, and this maximum voltage is applied to the current input terminal 715. For this reason, the voltage applied to each gate terminal G of FET733 and FET751 becomes the maximum value in the fixed state of the toning setting ratio. As a result, the current values of the first supply current I1 and the second supply current I2 become the maximum values in the fixed state of the toning setting ratio, so that the luminous flux of the entire light source 2 is the maximum value in the fixed state of the toning setting ratio. (Max).

  If the setting resistance value of the variable resistor 775 of the dimming setting circuit 77 is changed without changing the toning setting ratio of the variable resistor 711 of the toning setting circuit 71, the value of the toning setting ratio of the variable resistor 711 is changed. Regardless, the relationship between the resistance value of the combined resistance of the dimming setting circuit 77 and the luminous flux of the light source 2 is the characteristic shown in FIG. When the light adjustment setting circuit 77 (see FIG. 1) adjusts the light flux of the light source 2 to be small, the absolute value of the total supply current Isum decreases, but the color adjustment setting ratio shown in FIG. The relationship with the current ratio remains the same. Further, when dimming is performed by the dimming setting circuit 77 so that the constraint of the light source 2 is increased, the absolute value of the total supply current Isum increases, but the relationship between the toning setting ratio and the current ratio shown in FIG. Will not change.

  Next, operation | movement of the illuminating device 1 is demonstrated, referring FIG. As shown in FIG. 1, when an AC voltage of 100 V is applied to the lighting device 1, the AC 100 V is converted into a DC voltage by an AC / DC conversion circuit 51. When the LED driver control circuit 53 switches the switch circuit provided in the LED driver circuit 55 to the on state and switches the second switch circuit to the off state, the LED driver circuit 55 receives the direct current input from the AC / DC conversion circuit 51. The drive voltage and drive current generated from the voltage signal are output to the light source 2. As a result, the first and second supply currents are supplied to the LEDs 21 and 22, so that the light source 2 emits light with a predetermined luminance and a predetermined color according to the magnitudes of the first and second supply currents I1 and I2. To do. At this time, the LED driver circuit 55 stores the DC voltage input from the AC / DC conversion circuit 51 in the coil of the step-down converter. When the LED driver control circuit 53 switches the first switch circuit from the on state to the off state and switches the second switch circuit from the off state to the on state, the LED driver circuit 55 releases the energy accumulated in the coil of the step-down converter. The driving voltage and driving current are output to the light source 2. As described above, the LED driver circuit 55 can output the drive voltage and the drive current to the light source 2 even when disconnected from the AC / DC conversion circuit 51. Therefore, the first and second supply currents I1, I2 are supplied to the LEDs 21, 22. Is supplied. Thereby, the light source 2 maintains light emission with a predetermined luminance and a predetermined color according to the magnitudes of the first and second supply currents.

When the voltage of the step-down converter coil is lower than a predetermined voltage, the LED driver control circuit 53 switches the first switch circuit provided in the LED driver circuit 55 from the off state to the on state, and turns the second switch circuit on. Switch from off to off. Thereby, the LED driver circuit 55 is connected again to the AC / DC conversion circuit 51, and outputs the drive voltage and drive current generated from the DC voltage signal and the DC current signal input from the AC / DC conversion circuit 51 to the light source 2. At the same time, accumulation of energy is started in the coil of the step-down converter. As a result, the first and second supply currents I1 and I2 are supplied to the LEDs 21 and 22, so that the light source 2 has a predetermined luminance and a predetermined value according to the magnitudes of the first and second supply currents I1 and I2. Maintains light emission in color. The lighting device 1 repeats the above operation.
When the user of the lighting device 1 operates the variable resistor 711 while the lighting device 1 is operating, the color temperature of the emission color of the entire light source 2 changes. Further, when the user of the lighting device 1 operates the variable resistor 775 while the lighting device 1 is operating, the light flux of the entire light source 2 changes.

  As described above, the light source control circuit 3 according to the present embodiment includes the LED 21 and the power generation unit 5 that generates DC power supplied from the commercial AC power source to the LED 22 that generates light having a color temperature different from that of the LED 21, the LED 21, A variable resistor 711 for distributing the power generated by the power generation unit 5 to the LED 21 and the LED 22 to adjust the light generated by the light source 2 including the LED 22 is provided, and the color temperature of the toned light changes. Even at least in a certain color temperature range, the toning setting circuit 71 in which the sum of the current value of the first supply current I1 supplied to the LED 21 and the current value of the second supply current I2 supplied to the LED 22 is constant. Have. The light source control circuit 3 changes the current amount of the first and second supply currents I1 and I2 in association with only the change of the resistance value setting in the variable resistor 711 without using a microcomputer, and the light source 2 emits light. You can adjust the color of light. Thus, according to this embodiment, since the color of the light emitted from the light source 2 can be adjusted with a simple circuit configuration that does not use a microcomputer or the like, the circuit configuration of the light source control circuit 3 and the illumination device 1 including them can be adjusted. In addition to simplification, the cost can be reduced.

  The light control / color control circuit 7 provided in the light source control circuit 3 according to the present embodiment has a light control setting circuit 77 electrically connected to the positive side of the LEDs 21 and 22. The dimming setting circuit 77 changes the current values of the first and second supply currents I1 and I2 flowing through the LEDs 21 and 22 only by changing the setting resistance value of the variable resistor 775 provided in the dimming setting circuit 77, respectively. By changing, the light flux of the entire light source 2 can be changed. Thus, according to this embodiment, since the light flux of the light source 2 can be adjusted with a simple circuit configuration that does not use a microcomputer or the like, the circuit configuration of the light source control circuit 3 and the illumination device 1 including them can be simplified. Cost reduction can be achieved.

The present invention is not limited to the above embodiment, and various modifications can be made.
For example, the variable resistor provided in the toning setting circuit may be a double variable resistor. In this case, the toning setting circuit is configured to connect the other terminal of the other variable resistor to the second current adjustment circuit, assuming that one terminal of one variable resistor is connected to the first current adjustment circuit. The In this case, when the setting of the resistance value of the two variable resistors is changed, the resistance value of the other variable resistor decreases as the resistance value of one variable resistor increases. Accordingly, as the voltage value of the voltage input to the first current adjustment circuit becomes higher, the voltage value of the voltage input to the second current adjustment circuit becomes lower and vice versa, so the supply supplied to the two LEDs The increase / decrease of the current can be changed in conjunction with each other, and the same effect as the above embodiment can be obtained.

  The light adjustment / color adjustment setting circuit according to the above embodiment is configured such that the light adjustment setting circuit and the color adjustment setting circuit control a common FET, but the present invention is not limited to this. The light adjustment / color adjustment setting circuit may be configured such that the light adjustment setting circuit and the color adjustment setting circuit control different FETs. In this case, the FET controlled by the dimming setting circuit and the FET controlled by the toning setting circuit are connected in series to the cathode of the LED, for example. In this case, even if the voltage divided by the dimming setting circuit is applied to the voltage application terminal of the toning setting circuit, the voltage divided by the resistance setting circuit, for example, the LED driver circuit An output voltage may be applied.

The LED driver circuit 55 according to the above embodiment includes a step-down converter, but the present invention is not limited to this. Even if the LED driver circuit 55 includes, for example, any one of two converters, a step-up / step-down converter, and a flyback converter instead of the step-down converter, the same effect as in the above embodiment can be obtained.
The above embodiment exemplifies an apparatus for embodying the technical idea of the present invention. The technical idea of the present invention is the following in terms of the material, shape, structure, arrangement, etc. of components. It is not something specific. The technical idea of the present invention can be variously modified within the technical scope defined by the claims described in the claims.

DESCRIPTION OF SYMBOLS 1 Illuminating device 2 Light source 3 Light source control circuit 5 Electric power generation part 7 Dimming / toning circuit 21, 22 LED
51 AC / DC Converter 53 LED Driver Control Circuit 55 LED Driver Circuit 57 Feedback Circuit 71 Toning Setting Circuit 73 First Current Adjustment Circuit 75 Second Current Adjustment Circuit 77 Dimming Setting Circuits 711 and 775 Variable Resistors 712 and 713 714, 735, 755, 771, 773 Resistor 715 Current input terminal 716, 779 Reference potential application terminal 731, 751 Amplifier 733, 735 FET
777 Power supply voltage application terminal

Claims (6)

A power generator that generates DC power supplied from a commercial AC power source to a second light emitting element that generates light having a color temperature different from that of the first light emitting element and the first light emitting element;
A first variable for distributing the power generated by the power generation unit to the first light emitting element and the second light emitting element in order to adjust the light generated by the light source including the first and second light emitting elements. A resistor is provided, and the current value of the first supply current supplied to the first light emitting element and the second light emitting element are supplied at least within a certain color temperature range even if the color temperature of the toned light changes. A light source control circuit having a toning setting circuit having a constant sum with a current value of the second supply current. The light source control according to claim 1, further comprising: a dimming setting circuit that is provided in a preceding stage of the toning setting circuit and includes a second variable resistor for increasing or decreasing a luminous flux of the light toned by the toning setting circuit. circuit. The toning setting circuit includes:
A reference potential application terminal to which a reference potential is applied;
A third supply current input terminal to which a third supply current supplied from the power generation unit is input;
A first resistor connected between the third supply current input terminal and one terminal of the first variable resistor;
The light source control circuit according to claim 2, further comprising: a second resistor connected between the third supply current input terminal and the other terminal of the first variable resistor. The dimming setting circuit includes:
The light source control circuit according to claim 3, further comprising: a second variable resistor including one terminal provided on the third supply current input terminal side and the other terminal provided on the reference potential application terminal side. . A first current adjustment comprising: a first amplifier that amplifies a voltage applied to the one terminal; and a first transistor that adjusts a current value of the first supply current based on an amplified voltage amplified by the first amplifier. Circuit,
A second amplifier for amplifying a voltage applied to the other terminal; and a second transistor for adjusting a current value of the second supply current based on the amplified voltage amplified by the second amplifier. The light source control circuit according to claim 3, further comprising: a circuit. The light source including the first and second light emitting elements connected in parallel;
An illumination device comprising: the light source control circuit according to any one of claims 1 to 5.

Images