JP5383872B2 - Light source lighting device and lighting fixture - Google Patents

Description

  The present invention relates to a light source lighting device and a lighting fixture.

  Conventionally, in a LED lighting apparatus having a plurality of light sources having different emission colors or color temperatures, for example, light emitting diodes (LEDs) as light sources, the color temperature and the light amount are arbitrarily set by adjusting the current value supplied to each LED. An LED lighting device that can be used is known (see, for example, Patent Document 1). Also, an apparatus for changing the color temperature using a constant current source has been invented (see, for example, Patent Document 2).

JP 2007-200723 A JP 2009-9817 A JP 2010-140675 A JP 2010-200403 A JP 2010-110037 A JP 2004-266984 A

  However, for example, in the lighting device of Patent Document 1, a plurality of LEDs of each color temperature or each emission color are connected in parallel from a constant voltage power source, and the LEDs are turned on via a current limiting resistor. . Therefore, it is difficult to apply to high-power LED lighting fixtures.

  In order to solve this, for example, the lighting device of Patent Document 2 is highly efficient because it is driven by a constant current power source. However, since the current supplied to the LED is turned on / off by PWM control, the LED current is pulsed. It becomes a waveform and flickers easily occur. In addition, the LED current includes a high frequency component current, and the light source lighting device itself becomes a noise source, which may adversely affect other devices.

  Therefore, if a dedicated constant current circuit is provided for each light source having a different emission color or color temperature and the direct current is set to an arbitrary current value, an arbitrary color temperature can be obtained without performing PWM control as shown in Patent Document 2. Can be obtained.

  However, since a plurality of constant current circuits are used, there is a possibility that the timing of starting the lighting of each light emitting color LED will be slightly different when the power is turned on due to variations in characteristics and constants of electronic components used in each circuit. is there.

  In addition, when the power is shut off, the timing at which the LEDs are turned off may be shifted by the LEDs of the respective light emission colors.

  An object of this invention is to provide the light source lighting device which can light each LED at the same timing, when a constant current circuit is used for every LED.

The light source lighting device of the present invention is
A converter that converts an AC voltage from a commercial AC power source into a DC voltage and outputs the converted DC voltage;
A constant current power supply unit connected to the conversion unit, a light source is connected and a constant current power supply unit that outputs a direct current to the connected light source by receiving drive control;
A drive unit that drives and controls the constant current power supply unit by receiving a supply of control power;
When the commercial AC power source is turned on, a control power source circuit unit that starts based on the commercial AC power source and starts generating the control power source based on the commercial AC power source;
A control power supply control unit that starts supplying the control power generated by the control power supply circuit unit to the drive unit when detecting the turning on of the commercial AC power supply,
The drive unit is
An integration circuit for continuously inputting a target signal indicating a target value of a direct current to be supplied to the light source connected to the constant current power supply unit, and outputting an output value corresponding to the target signal continuously input; ,
A comparison unit that compares a detection value corresponding to a direct current flowing through the light source connected to the constant current power supply unit and the output value of the integration circuit;
A control unit that drives and controls the constant current power supply unit based on a comparison result between the detection value and the output value by the comparison unit;
The control power supply controller is
Continuously outputting the target signal to the integration circuit of the drive unit,
The timing at which the output of the target signal is started by the control power supply control unit to the integration circuit of the drive unit is as follows:
It is after the start of supply of the control power generated by the control power supply circuit unit to the drive unit.

  According to the present invention, it is possible to reduce stress on the electric element used in the constant current power supply unit by a so-called “soft start effect”.

FIG. 3 is a circuit diagram of the light source lighting device 110 according to the first embodiment. FIG. 3 is an operation timing chart of the light source lighting device 110 according to the first embodiment. FIG. 4 is a circuit diagram of a light source lighting device 120 according to a second embodiment. FIG. 10 is an operation timing chart of the light source lighting device 120 according to the second embodiment. FIG. 10 is a side sectional view of lighting apparatus 200 according to Embodiment 3.

Embodiment 1 FIG.
The light source lighting device 110 according to the first embodiment will be described with reference to FIG. In the first embodiment, description will be made using an LED (light emitting diode) as a light source.
FIG. 1 is a circuit diagram of the light source lighting device 110. The light source lighting device 110 is a device that receives power from the commercial AC power source 1 and lights the LEDs 8a and 8b each including a plurality of LED elements. In FIG. 1, components other than the commercial AC power source 1, the LEDs 8 a and 8 b, and the color temperature / dimming controller 16 are components of the light source lighting device 110.

(Configuration of light source lighting device 110)
The light source lighting device 110 includes an AC-DC converter 29 (converter), a first step-down chopper circuit 30 (constant current power supply unit), a second step-down chopper circuit 31 (constant current power supply unit), and a drive circuit 10a (drive unit). , A drive circuit 10b (drive unit), a control power supply circuit 11 (control power supply circuit unit), a cutoff switch 12, and a control circuit 13 (control power supply control unit).
(1) The AC-DC converter 29 includes the rectifier circuit 2, the first smoothing capacitor 3, and the commercial power supply detection circuit 14.
(2) The first step-down chopper circuit 30 includes a switching element 4a, a free wheeling diode 5a, an inductor 6a, a second smoothing capacitor 7a, an LED current detection resistor 9a, and an insulating circuit 15a.
(3) The second step-down chopper circuit 31 has the same configuration as the first step-down chopper circuit 30.
(4) The drive circuit 10 a drives the switching element 4 a of the first step-down chopper circuit 30.
(5) The drive circuit 10 b drives the switching element 4 b of the second step-down chopper circuit 31.
(6) The control power supply circuit 11 supplies control power to the drive circuits 10a and 10b.
(7) The cutoff switch 12 controls the supply / cutoff of the control power.
(8) The control circuit 13 outputs on / off control of the cutoff switch 12 and an LED current target signal for instructing the target LED current to the drive circuits 10a and 10b. The control circuit 13 uses, for example, a microcomputer.

(Step-down chopper circuit and light source)
The first step-down chopper circuit 30 and the second step-down chopper circuit 31 share the AC-DC converter 29. A first step-down chopper circuit 30 and a second step-down chopper circuit 31 are connected in parallel to the first smoothing capacitor 3. LEDs having different color temperatures are connected to each step-down chopper circuit. For example, in the first embodiment, the LED 8a having a color temperature of 3000K is connected to the first step-down chopper circuit 30, and the LED 8b having a color temperature of 5000K is connected to the second step-down chopper circuit 31. Thus, by mixing the light output from the LED 8a having a color temperature of 3000K and the light output from the LED 8b having a color temperature of 5000K, mixed color light having an intermediate color temperature can be obtained. Then, by changing the output ratio of the direct current output from the first step-down chopper circuit 30 and the second step-down chopper circuit 31, the mixed color light can be adjusted to an arbitrary color temperature.

(AC-DC converter 29)
The rectifier circuit 2 performs full-wave rectification on the AC voltage supplied from the commercial AC power supply 1. The first smoothing capacitor 3 smoothes the voltage converted into a direct current by the rectifier circuit 2 and keeps the voltage constant. In the first embodiment, a capacitor input type rectifier circuit including the rectifier circuit 2 and the first smoothing capacitor 3 is configured as the AC-DC converter 29. However, when power factor improvement is required, a power factor correction circuit composed of, for example, a rectifier circuit and a step-up chopper circuit is used as the AC-DC converter 29, and the first step-down chopper circuit 30 and the second step-down chopper circuit are provided at the subsequent stage. 31 may be connected.

(Feedback control)
In the first step-down chopper circuit 30, the switching element 4a is driven by the drive circuit 10a, and supplies current to the LED 8a. The current supplied to the LED 8a is detected by the LED current detection resistor 9a and converted into a voltage signal (hereinafter, this voltage signal is referred to as an LED current detection signal). The detected signal is input to the drive circuit 10a. On the other hand, the control circuit 13 outputs a signal indicating the target value of the LED current determined by the signal input from the color temperature / dimming controller 16 (hereinafter, this signal is referred to as the LED current target signal), and the drive circuit 10a. Is input. The drive circuit 10a compares the LED current detection signal with the LED current target signal, adjusts the duty ratio of the switching element 4a in the direction in which both match, and performs feedback control.

(Insulation circuit 15a)
A signal for driving the switching element 4a output from the driving circuit 10a is input to the gate of the switching element 4a (here, for example, a MOS-FET). In the first embodiment, since the switching element 4a is provided on the high voltage side, the drive signal is electrically insulated and transmitted by the insulation circuit 15a. The insulation circuit 15a uses, for example, a transformer or a photocoupler for signal insulation.

(Second step-down chopper circuit 31)
In the first embodiment, the second step-down chopper circuit 31 controlled by the drive circuit 10b is provided for the purpose of supplying current to the LED 8b. The configuration and control principle are the same as those of the first step-down chopper circuit 30 and the drive circuit 10a described above, and thus description thereof is omitted.

(Control power circuit 11)
The control power supply circuit 11 is a circuit that generates a control power supply for supplying power to the drive circuits 10a and 10b. When the commercial AC power supply 1 is turned on, the control power supply circuit 11 is activated based on the commercial AC power supply 1 and starts generating a control power supply based on the commercial AC power supply 1. That is, the control power supply circuit 11 starts up using the commercial AC power supply 1 as a power supply, and generates a control power supply from the commercial AC power supply 1. Although the circuit configuration is not illustrated, for example, a voltage dividing resistor and a Zener diode are connected from the first smoothing capacitor 3 to reduce the voltage to the required voltage, or the first smoothing capacitor 3 is converted to an appropriate voltage via a switching power supply. A method is conceivable. The control power supply circuit 11 converts the commercial AC power supply 1 into an appropriate voltage and then supplies it to the drive circuits 10a and 10b.

(Cutoff switch 12)
The cutoff switch 12 controls the cutoff / supply of the control power to the drive circuits 10a, 10b. The cutoff switch 12 is provided in a common power supply path for the drive circuits 10a and 10b, and can be simultaneously cut off and supplied to the drive circuits 10a and 10b by the control of the cutoff switch 12. On / off control of the cutoff switch 12 is performed by the control circuit 13.

(Color temperature / dimming controller 16)
The color temperature / dimming controller 16 is provided outside the light source lighting device 110 and is a setting device for the user to set the lighting fixture to an arbitrary color temperature and dimming rate. The color temperature / dimming controller 16 is, for example, a volume provided on a wall or a remote controller. The desired color temperature and dimming rate are set by operating the volume and remote control. The color temperature / dimming controller 16 outputs a signal indicating the set dimming rate / color temperature or a signal indicating the current values of the LEDs 8a and 8b. The signal output from the color temperature / dimming controller 16 is input to the control circuit 13. The control circuit 13 outputs each LED current target signal of the LED 8a and the LED 8b based on the input signal.

(Description of operation)
The configuration of the light source lighting device 110 according to the first embodiment has been described above. Next, the operation of the light source lighting device 110 according to the first embodiment will be described with reference to FIG.
FIG. 2 is an operation timing chart of the light source lighting device 110. The horizontal axis in FIG. 2 is all time t.
FIG. 2A shows a commercial power supply detection signal detected by the commercial power supply detection circuit 14 and input to the control circuit 13.
FIG. 2B shows the output voltage of the control power supply circuit 11.
FIG. 2C shows the on / off state of the cutoff switch 12.

  When the commercial AC power source 1 is turned on to the light source lighting device 110, the commercial power source detection circuit 14 detects the commercial AC power source 1 being turned on (time t1), and a commercial power source detection signal is input to the control circuit 13. The rectifier circuit 2 rectifies the AC voltage supplied from the commercial AC power source 1 and converts it into a DC voltage. The first smoothing capacitor 3 is charged by the obtained DC voltage, and the control power supply circuit 11 is activated (time t1). Although the output voltage of the control power supply circuit 11 is zero immediately after startup, the power supply is supplied to the drive circuits 10a and 10b. At this time (time t1 to t2), the cutoff switch 12 is in a cutoff state (off state), and no control power is supplied to the drive circuits 10a and 10b.

  Next, when the output voltage of the control power supply circuit 11 reaches a sufficiently stable voltage state over time, that is, after a predetermined time elapses after the commercial power supply detection is detected by the commercial power supply detection circuit 14, the control circuit 13 The cutoff switch 12 is turned on (time t2), and the control power is turned on to the drive circuits 10a and 10b. That is, the control circuit 13 has a clock function, and when the commercial AC power supply is detected, the control circuit 13 turns on the cutoff switch 12 after a predetermined period (time t1 to t2) has elapsed. Here, the cutoff switch 12 is provided in a common power supply path for the drive circuits 10a and 10b. For this reason, when the cutoff switch 12 is turned on, control power is applied to the drive circuits 10a and 10b at the same timing. Thus, immediately after the commercial AC power is turned on (time t1), the control circuit 13 does not apply the control power to the drive circuits 10a and 10b and stands by for a predetermined period. Thus, the control power supply is applied to the drive circuits 10a and 10b at the same timing in a state where the control voltage is sufficiently stabilized (after time t2).

(Simultaneous lighting of LEDs 8a and 8b)
The control power supply circuit 11 starts to operate after the commercial AC power supply 1 is applied, but the voltage output from the control power supply circuit 11 gradually increases. For this reason, if there is a variation in the voltage at which the operation is started between the drive circuit 10a and the drive circuit 10b, the timing at which the drive circuit 10a and the drive circuit 10b start is shifted. Along with this, there is a possibility that the timing at which the LEDs 8a and 8b are turned on may be shifted. Here, since the control power is supplied to the drive circuits 10a and 10b at the same timing (time t2) after the control power supply voltage is sufficiently stabilized, the start-up voltages of these drive circuits vary. However, a voltage exceeding that is instantaneously applied. Therefore, the first step-down chopper circuit 30 and the second step-down chopper circuit 31 can be activated at substantially the same timing.

(Operation of the first step-down chopper circuit 30)
When the first step-down chopper circuit 30 starts operation, current starts to flow through the LED 8a. The operation of the first step-down chopper circuit 30 is as follows. When the switching element 4a is turned on, a current flows through a path of the first smoothing capacitor 3, the switching element 4a, the inductor 6a, the second smoothing capacitor 7a, and the first smoothing capacitor 3, and energy is stored in the inductor 6a. When the switching element 4a is turned off, the energy stored in the inductor 6a is released, and a current flows through the path of the inductor 6a → the second smoothing capacitor 7a → the freewheeling diode 5a → the inductor 6a. A current is supplied from the second smoothing capacitor 7a to the LED 8a. At this time, the second smoothing capacitor 7a serves to suppress and smooth the pulsation of the LED current. By adjusting the on-duty ratio of the switching element 4a, the current flowing through the LED 8a can be adjusted.

(Operation of feedback control)
When a current starts to flow through the LED 8a, the current flowing through the LED 8a is detected by being converted into a voltage signal by the LED current detection resistor 9a. The detected signal is input to the drive circuit 10a as an LED current detection signal and compared with the LED current target signal. For example, when the LED current target signal is larger than the LED current detection signal, the signal output from the drive circuit 10a to the switching element 4a via the insulating circuit 15a is a signal that increases the on-duty ratio of the switching element 4a. The current flowing through the LED 8a increases. Conversely, when the LED current detection signal is larger than the LED current target signal, the on-duty ratio of the switching element 4a decreases and the current flowing through the LED 8a decreases. In this way, the drive circuit 10a compares the LED current detection signal with the LED current target signal, and controls the duty ratio of the switching element 4a in such a direction that the difference between the two becomes smaller, thereby performing constant current feedback control. Since the operations of the second step-down chopper circuit 31 and the drive circuit 10b are the same as those of the first step-down chopper circuit 30 and the drive circuit 10a, description thereof is omitted.

  Here, the control circuit 13 determines a current value (LED current target signal) to be supplied to the LED 8a having a color temperature of 3000K and the LED 8b having a color temperature of 5000K in accordance with a signal input from the color temperature / dimming controller 16. To do. The control circuit 13 gives each LED current target signal to the drive circuits 10a and 10b. Thereby, the electric current set to LED8a and LED8b is supplied, and the light of arbitrary color temperature and a light control rate can be obtained by mixing of light.

(When commercial AC power supply 1 is shut off)
Next, consider the case where the commercial AC power supply 1 is shut off. The light source lighting device 110 is connected to the first smoothing capacitor 3, and the control power supply circuit 11 normally has a smoothing capacitor, although not shown. For this reason, since the step-down chopper circuit continues to operate immediately after the commercial AC power supply 1 is shut off, the LEDs 8a and 8b are not turned off immediately after the commercial AC power supply 1 is shut off. Here, consider a case where the number of connected lamps of the LED 8a is different from the number of connected lamps of the LED 8b. For example, assuming that the number of connected lamps of the LED 8a is smaller, the first step-down chopper circuit 30 can be lit at a lower voltage. When the voltage decreases, the LED 8a that requires a smaller output voltage continues to be lit longer than the LED 8b. Therefore, when the commercial AC power supply 1 is shut off, the timing for turning off the 3000K and 5000K LEDs is shifted.

  Therefore, in the light source lighting device 110 of the first embodiment, as shown in FIG. 2, when the commercial AC power source 1 is shut off (time t3), the commercial power source detection circuit 14 detects the cutoff of the commercial AC power source 1. The detection signal is input to the control circuit 13. When the control circuit 13 detects the interruption of the commercial AC power supply 1, the control circuit 13 immediately turns off the interruption switch 12 and interrupts the supply of the control power to the drive circuits 10a and 10b. Since the cutoff switch 12 is provided in a common power supply path for the drive circuits 10a and 10b, the operations of the first step-down chopper circuit 30 and the second step-down chopper circuit 31 can be stopped simultaneously. Thereby, the LED 8a and the LED 8b can be turned off at the same time (time t3).

  As described above, in the light source lighting device 110 in which LEDs having different color temperatures are connected to the step-down chopper circuits, when the commercial AC power supply 1 is turned on, the control power supply is delayed for a predetermined period, and the control power supply voltage is stabilized. The control power supply is turned on to the drive circuit 10a and the drive circuit 10b at the same timing. Therefore, the LEDs connected to each step-down chopper circuit can be turned on at the same time.

  Further, in the light source lighting device 110, when the commercial AC power source 1 is shut off, it detects that the power source has been shut off, and shuts off the control power source to the drive circuit 10a and the drive circuit 10b at the same timing. Therefore, the first step-down chopper circuit 30 and the second step-down chopper circuit 31 stop operating simultaneously, and the LEDs 8a and 8b can be turned off at the same timing.

  Therefore, it is possible to suppress the deviation of the timing of starting lighting when the commercial AC power supply 1 is turned on or the timing of turning off when the power is shut off between the 3000K LED 8a and the 5000K LED 8b. Therefore, it is possible to suppress the flickering feeling that occurs when the timing of turning on / off slightly deviates between the 3000K LED and the 5000K LED.

  In the first embodiment, LEDs having different color temperatures of 3000K and 5000K are connected to the first step-down chopper circuit 30 and the second step-down chopper circuit 31, respectively. However, the present invention is not limited to this. You may connect LED of color temperature, or LED of the same color temperature. An example in which LEDs having the same color temperature are connected to the first step-down chopper circuit 30 and the second step-down chopper circuit 31 will be described below. In a high-power / large LED lighting fixture, the number of LED connections increases, so the number of LEDs in series increases. Accordingly, it is necessary to increase the output voltage of the light source lighting device 110, but there is a limit to the voltage that can be output depending on the power supply voltage and circuit method. Therefore, as described in the first embodiment, by providing two step-down chopper circuit portions, the output voltage per circuit can be kept low. Even in such a case, the operation of the first step-down chopper circuit 30 and the second step-down chopper circuit 31 can be started and stopped at the same time when the commercial AC power supply 1 is turned on and when the commercial AC power supply 1 is turned off. It can be turned on and off at the same time.

  Further, the step-down chopper circuit is used as a circuit for supplying current to the LED, but other circuit methods may be used as long as the circuit method can supply a constant current to the LED, for example, a flyback converter.

(Type of light source)
Furthermore, although Embodiment 1 has been described using an LED as a light source, for example, an organic EL may be used as the type of light source. In this case, the same color temperature variable control can be performed by connecting organic ELs having different color temperatures to each step-down chopper circuit. And, in the same way as when using LEDs, when the power is turned on and off, the organic EL connected to each step-down chopper circuit suppresses the flickering feeling caused by the timing of turning on / off each step-down chopper circuit. can do.

Embodiment 2. FIG.
Next, the light source lighting device 120 according to the second embodiment will be described with reference to FIG. In the second embodiment, description will be made using an LED as a light source.
FIG. 3 is a circuit diagram of the light source lighting device 120. In FIG. 3, components other than the commercial AC power source 1, the LED 8 a, the LED 8 b, and the color temperature / dimming controller 16 are components of the light source lighting device 120. The difference from FIG. 1 of the first embodiment is that
(1) an error amplifier composed of an operational amplifier in the drive circuit;
(2) an integrating circuit (RC integrating circuit) comprising a resistor 25 and a capacitor 26 at the non-inverting input terminal of the operational amplifier;
(3) The capacitor discharge switch 27 is provided, and the description of the same parts as those in the first embodiment is omitted.

  The drive circuit 10a is provided at a control IC 20a (control unit) that drives the switching element 4a, an error amplifier (comparison unit) composed of an operational amplifier 22a, a capacitor 23a, and a resistor 24a, and a non-inverting input terminal of the operational amplifier 22a. An integrating circuit including a resistor 25a and a capacitor 26a, and a discharge switch 27a (short-circuit switch) connected in parallel to the capacitor 26a are provided. For example, a semiconductor switch is used as the discharge switch 27a, and a transistor is used here. The output terminal of the operational amplifier 22 a is input to the control IC 20 a that drives the switching element 4 a of the first step-down chopper circuit 30. The control IC 20a determines the duty ratio of the switching element according to the output voltage of the operational amplifier 22a. The drive circuit 10b has the same configuration as the drive circuit 10a, and a description thereof will be omitted.

  The control circuit 13 performs on / off control of the discharge switches 27a and 27b. Further, an LED current target signal is output from the control circuit 13 in accordance with a signal output from the color temperature / dimming controller 16. The LED current target signal is a DC voltage signal or a PWM signal, and is input to the non-inverting input terminal of the operational amplifier 22a. The non-inverting input terminal of the operational amplifier has an integrating circuit composed of a resistor 25a and a capacitor 26a for the purpose of removing noise or smoothing to a DC voltage when the LED current target signal from the control circuit 13 is a PWM signal. It is connected.

The configuration of the light source lighting device 120 according to the second embodiment has been described above. Next, the operation of the light source lighting device 120 according to the second embodiment will be described with reference to FIG.
FIG. 4 is an operation timing chart of the light source lighting device 120.
The horizontal axis in FIG. 4 is all time t.
FIG. 4A shows a commercial power supply detection signal detected by the commercial power supply detection circuit 14 and input to the control circuit 13.
FIG. 4B shows the output voltage of the control power supply circuit 11.
FIG. 4C shows the on / off state of the cutoff switch 12.
FIG. 4 (d) shows the LED current target signal for a 3000K light source.
FIG. 4 (e) shows the LED current target signal for a 5000K light source.
FIG. 4F shows the on / off states of the discharge switches 27a and 27b.
FIG. 4G shows the voltage of the capacitor 26a.
FIG. 4H shows the voltage of the capacitor 26b.
Note that description of operations similar to those of the first embodiment is omitted.

  When the commercial AC power supply 1 is turned on, the control power supply circuit 11 starts to be activated (time t1 in (b)). When the control circuit 13 detects that the commercial AC power supply 1 is turned on via the commercial power supply detection circuit 14, the control circuit 13 turns on the cutoff switch 12 (time t2 in (c)) after a predetermined period has elapsed (time t1 to t2). Then, control power is supplied to “control IC 20a and control IC 20b” and “op-amp 22a and op-amp 22b” at the same time (time t2). As a result, the drive circuit 10a and the drive circuit 10b start to start from time t2, but the control circuit 13 outputs each LED current target signal ((d), (e)) during the period from time t2 to t3. Is zero. That is, when the control circuit 13 detects that the commercial AC power source 1 is turned on, the control circuit 13 turns on the cutoff switch 12 after a lapse of a predetermined period (after the time t1 to t2), and from the time t2 when the cutoff switch 12 is turned on to the time t3. The LED current target signal is set to zero. Then, the control circuit 13 outputs each LED current target signal after time t3. The time t2 to t3 may be 0 seconds or more. That is, the output of each LED current target signal by the control circuit 13 is after the cutoff switch 12 is turned on (after time t2, after the start of supply of control power). Note that “on and after” includes the case where the cutoff switch 12 is turned on simultaneously (when the time t2 to t3 is zero seconds). In the period from time t2 to time t3, the first step-down chopper circuit 30 and the second step-down chopper circuit 31 thereby have zero output current to the LED, that is, the light-off state (step-down chopper circuit operation stop).

  Next, at time t3, the LED current target signals for 3000K and 5000K determined by the setting of the color temperature / dimming controller 16 from the control circuit 13 are simultaneously sent to the non-inverting input terminals of the operational amplifier 22a and the operational amplifier 22b. Respectively (time t3 in (d) and (e)). As a result, the first step-down chopper circuit 30 and the second step-down chopper circuit 31 supply current to the LEDs at the same timing, and the LEDs 8a and 8b start to light simultaneously. That is, the LED current detection signal is compared with the LED current target signal by each error amplifier. Then, the control ICs 20a and 20b control the duty ratios of the switching elements 4a and 4b in a direction in which the voltage levels of the two match, so that the LED current matches the target current.

  The drive circuit 10a will be specifically described. The integration circuit of the drive circuit 10a (the RC integration circuit of the resistor 25a and the capacitor 26a) is an LED that indicates a target value of the current that should flow through the LED 8a connected to the first step-down chopper circuit 30. When the current target signal (target signal) is continuously input from the control circuit 13, a voltage (output value) corresponding to the LED current target signal is output ((g) in FIG. 4). On the other hand, the error amplifier of the drive circuit 10a compares the detection value (detection value corresponding to the LED current of the LED 8a) detected by the LED current detection resistor 9a with the output voltage of the integration circuit. The control IC 20a controls switching of the switching element 4a of the first step-down chopper circuit 30 based on the comparison result between the detection value by the error amplifier and the output voltage. The operation of the drive circuit 10b is the same as that of the drive circuit 10a. In the operation of this drive circuit, the control circuit 13 starts the supply of the control power generated by the control power circuit 11 (at the same time as time t2 or after time t2), and the LED current to the integration circuit of each drive circuit. Start outputting the target signal.

(Integration circuit)
In the second embodiment, an integrating circuit including resistors 25a and 25b and capacitors 26a and 26b is connected to the non-inverting input terminals of the operational amplifiers 22a and 22b for the purpose of removing noise. Thereby, noise superimposed on the LED current target signal is removed. When the control circuit 13 outputs a PWM signal as the LED current target signal, the control circuit 13 plays a role of smoothing the PWM signal and converting it into a DC voltage. In this case, the voltage level (output value corresponding to the target signal) of the LED current target signal input to the non-inverting input terminal of the operational amplifier increases or decreases according to the increase or decrease of the duty ratio of the PWM signal.

(Soft start)
In this way, an integration circuit, that is, a circuit having a time constant determined by the resistance value and the capacitor capacity is provided at the reference voltage input terminal portion of the error amplifier, and immediately after the commercial AC power supply 1 is turned on, a predetermined period after the cutoff switch 12 is turned on. (Time t2 to t3), the LED current target signal output from the control circuit 13 is set to zero. Then, when the LED current target signal determined by the control circuit 13 based on the set value of the color temperature / dimming controller 16 is input to the non-inverting input terminals of the operational amplifiers 22a and 22b from time t3, it is input to the non-inverting input terminal based on the time constant. As shown in (g) and (h) of FIG. 4, the applied voltage gradually increases from zero with time. Along with this, the LED current gradually increases from zero. Therefore, a so-called “soft start effect” can be obtained that reduces stress on the switching elements 4 a and 4 b of the first step-down chopper circuit 30 and the second step-down chopper circuit 31. That is, the timing at which the LED current target signal starts to be output from the control circuit 13 to the integration circuit of each drive circuit is after the start time t2 of the supply of the control power generated by the control power supply circuit 11 to each drive circuit. . In this way, each step-down chopper circuit is in a state of being driven immediately in response to the output from the error amplifier, but the voltage input to the non-inverting input terminal of the error amplifier gradually increases from time t3. A “soft start” is possible in which the LED current supplied to the LEDs 8a and 8b by the chopper circuit gradually increases.

(When AC power is cut off)
Next, with reference to FIG. 4, the case where the commercial AC power supply 1 is cut off will be described.

(The shutoff switch 12 is turned off)
When the commercial AC power source 1 is shut off, the commercial power source detection circuit 14 detects that the commercial AC power source 1 is shut off as in the first embodiment (time t4 in (a)). Is input. The control circuit 13 determines that the commercial AC power supply 1 has been cut off, immediately turns off the cut-off switch 12 (time t4 in (c)), and cuts off the supply of control power. Since the cutoff switch 12 is provided in a common path in series with the drive circuit 10a and the drive circuit 10b, the first step-down chopper circuit 30 and the second step-down chopper circuit 31 operate simultaneously when the cutoff switch 12 is turned off. Stops. Thereby, LED8a and LED8b can be light-extinguished simultaneously.

(Turn on the discharge switch)
Here, in the second embodiment, the control circuit 13 turns off the cut-off switch 12 and turns on the discharge switches 27a and 27b only between times t4 and t5. Thereby, both ends of the capacitors 26a and 26b are short-circuited, and the electric charge stored in the capacitors 26a and 26b is discharged when the commercial AC power supply 1 is shut off. The reason why the discharge switches 27a and 27b are turned off at time t5 is that the LED current target signal is input to the integration circuit when the commercial AC power supply 1 is turned on again. By short-circuiting the capacitors 26a and 26b by the discharge switches 27a and 27b, for example, when the power is turned on immediately after the power is turned off, it is possible to prevent the capacitors 26a and 26b from being left with electric charge. If the control power is turned on to the drive circuit 10a and the drive circuit 10b with the electric charge remaining in the capacitors 26a and 26b, even if the LED current target signal from the control circuit 13 is set to zero, the non-inverting input terminal of the operational amplifier In this case, the residual charges of the capacitors 26a and 26b are given as the LED current target signal. For this reason, an electric current will flow into LED. Therefore, the soft start function by the integration circuit cannot be obtained, the stress of the switching element increases when the step-down chopper circuit starts up, and the rating may be exceeded when a switching element with a small current and voltage rating is used. .

  Therefore, in the second embodiment, since the electric charges of the capacitors 26a and 26b are instantaneously extracted simultaneously with the interruption of the commercial AC power supply 1, even after the commercial AC power supply 1 is turned off, the capacitor 26a, In this state, the electric charge of 26b is extracted. Therefore, when the LED current target signal is output from the control circuit 13, the voltages at the inverting input terminals of the operational amplifiers 22a and 22b gradually increase due to the time constant of the integration circuit, and similarly a soft start effect can be obtained. . Incidentally, the resistors 28a and 28b limit the current value so that the discharge current from the capacitor does not exceed the rating of the transistor when a transistor is used as the discharge switches 27a and 27b. The resistance value is less than that of the resistors 25a and 25b. The value is sufficiently small.

(When receiving a light off signal)
Further, not only when the commercial AC power supply 1 is shut off, but also when, for example, a turn-off signal instructing turn-off is output from the color temperature / dimming controller 16, the control circuit 13 recognizes that the turn-off signal has been input. At the same time as turning off the cutoff switch 12, the discharge switches 27a and 27b are turned on for a predetermined period of time t4 to t5. As a result, the drive circuits 10a and 10b stop operating and the LEDs are turned off, and at the same time, the capacitors 26a and 26b are instantly extracted. For this reason, even if a signal for instructing lighting is input from the color temperature / dimming controller 16 immediately after the extinguishing signal is input, since the charges of the capacitors 26a and 26b have already been extracted, the soft start effect is similarly obtained. Can be obtained. The turn-off signal output from the color temperature / dimming controller 16 may be a turn-off signal for all LEDs (a turn-off signal for both the LED 8a and LED 8b), or a turn-off signal for one of the LEDs (for example, a turn-off signal for only the LED 8a). ).

  As described above, in the light source lighting device 120, the first step-down chopper circuit 30 and the second step-down chopper circuit 31 are connected to the LEDs 8a and 8b having different color temperatures and independently supply an arbitrary current. The light source lighting device 120 is configured to wait for lighting for a predetermined period when the commercial AC power supply 1 is turned on, and simultaneously turn on the control power to the drive circuit 10a and the drive circuit 10b after the control power supply voltage is stabilized. Therefore, the LEDs connected to each step-down chopper circuit can be turned on at the same time.

  Further, when the control power is turned on, the LED target current value is set to zero, so that soft start can be realized by the action of the integrating circuit connected to the inverting input terminal of the operational amplifier.

  Further, when the commercial AC power supply 1 is cut off, it is detected at the same time in order to detect that the power supply has been cut off and cut off the control power supply to the drive circuits 10a and 10b at the same time and stop the operation of the step-down chopper circuit. LEDs with different color temperatures can be turned off.

  Furthermore, since the light source lighting device 120 draws out the charge of the capacitor of the time constant circuit (integration circuit) provided in the error amplifier simultaneously with the interruption of the control power supply, even when the power is turned on immediately after the power supply is turned off, A soft start can be achieved.

  Therefore, when the commercial AC power supply 1 is turned on, it is possible to suppress the timing to start lighting for each LED of each emission color or to suppress the timing to turn off when the power is turned off for each LED of each emission color. A flickering feeling caused by a slight shift in timing can be suppressed. Moreover, the current / voltage stress to the switching element can be reduced by the soft start function.

  In the second embodiment, the case where 3000K and 5000K LEDs are connected to the first step-down chopper circuit 30 and the second step-down chopper circuit 31, respectively, has been described. You may connect LED.

  An example of connecting LEDs having the same color temperature will be described below. In a high-power / large LED lighting fixture, the number of LED connections increases, so the number of LEDs in series increases. Accordingly, it is necessary to increase the output voltage of the light source lighting device 120, but there is a limit to the voltage that can be output depending on the power supply voltage and circuit method. Therefore, as described in the second embodiment, by providing two step-down chopper circuit portions, the output voltage per circuit can be kept low. Even in such a case, the operation of the first step-down chopper circuit 30 and the second step-down chopper circuit 31 can be started and stopped at the same time when the commercial AC power supply 1 is turned on and when the commercial AC power supply 1 is turned off. It can be turned on and off at the same time.

  Further, the step-down chopper circuit is used as a circuit for supplying current to the LED, but other circuit methods may be used as long as the circuit method can supply current to the LED, for example, a flyback converter.

  Furthermore, although Embodiment 2 has been described using an LED as a light source, for example, an organic EL may be used. In this case, the same color temperature variable control can be performed by connecting organic ELs having different color temperatures to each step-down chopper circuit. Further, it is possible to suppress flickering feeling caused by the timing at which the organic EL connected to each step-down chopper circuit is turned on / off for each step-down chopper when the power is turned on and when the power is turned off. Moreover, the current / voltage stress to the switching element can be reduced by the soft start function.

Embodiment 3 FIG.
FIG. 5 is a side cross-sectional view of lighting apparatus 200 according to Embodiment 3.
The light source lighting device 110 or the light source lighting device 120 described in any of the first and second embodiments is housed in the lighting fixture body 40, and the light source lighting device is commercially available via the power line 42 and the connector 43. Connected to AC power supply 1. The mounting substrate 45 on which the LED packages 44a and 44b having different color temperatures are mounted is mounted on the light emitting surface of the lighting fixture body 40 and connected to the light source lighting device 110 (or the light source lighting device 120) by the wiring 46. Form.
Although not shown, the light source lighting device includes a dimming signal line connector and is connected to a color temperature / dimming controller provided outside.

  According to the lighting fixture 200 according to the third embodiment, the light source lighting device described in each embodiment can be incorporated. The lighting fixture 200 incorporating the light source lighting device can suppress the deviation of the “lighting start timing or light extinction timing” of the light sources connected to the respective constant current power supply units. Therefore, the lighting fixture 200 can suppress the flickering feeling that is felt when it is turned on or off. In addition, although LED is used as a light source in this Embodiment 3, you may use organic EL and another light source.

In the above embodiment, the following light source lighting devices have been described.
A converter that converts an AC voltage from a commercial AC power source into a DC voltage and outputs the converted DC voltage;
A plurality of constant current power supply units connected in parallel to the conversion unit, the corresponding light sources being connected, and a plurality of constant currents outputting a direct current to the corresponding connected light sources by receiving drive control A power supply,
A plurality of drive units that are provided corresponding to the plurality of constant current power supply units, and that drive-control the plurality of constant current power supply units by receiving supply of control power;
When the commercial AC power source is turned on, a control power source circuit unit that starts based on the commercial AC power source and starts generating the control power source based on the commercial AC power source;
A control power supply control unit that starts supply of the control power generated by the control power supply circuit unit to the plurality of driving units when a predetermined period has elapsed when the commercial AC power supply is detected. ,
Each drive unit of the plurality of drive units,
Integration for continuously inputting a target signal indicating a target value of a direct current to be supplied to the light source connected to the corresponding constant current power supply unit and outputting an output value corresponding to the continuously input target signal Circuit,
A comparison unit that compares a detection value corresponding to a direct current flowing through the light source connected to the corresponding constant current power supply unit and the output value of the integration circuit;
A control unit that drives and controls the corresponding constant current power supply unit based on a comparison result between the detection value and the output value by the comparison unit;
The control power supply controller is
Continuously output the target signal to the integration circuit of each drive unit,
The timing at which the target power is started to be output to the integration circuit of each drive unit by the control power supply control unit is as follows:
The light source lighting device after the start of supply of the control power generated by the control power supply circuit unit to the plurality of drive units.

In the above embodiment, the following light source lighting devices have been described.
The integration circuit of each drive unit is
RC integration circuit consisting of a resistor and a capacitor;
A shorting switch that short-circuits both ends of the capacitor by receiving control;
The control power supply controller is
When detecting the interruption of the commercial AC power supply, the light source lighting device is characterized in that both ends of the capacitor are short-circuited by the short-circuit switch of the integration circuit of each drive unit.

In the above embodiment, the following light source lighting devices have been described.
The control power supply controller is
When an extinction signal that instructs to turn off the light source corresponding to any one of the constant current power supply units is input, the integration circuit of the drive unit that drives the constant current power supply unit corresponding to the light source instructed to be turned off A light source lighting device characterized in that both ends of the capacitor are short-circuited by the short-circuit switch.

In the above embodiment, the following light source lighting devices have been described.
The light source lighting device is:
A light source lighting device using at least one of a light emitting diode and an organic EL (Electro Luminescence) as the light source.

In the above embodiment, the following light source lighting devices have been described.
Each constant current power supply unit of the plurality of constant current power supply units,
The light source lighting device, wherein the light source having a color temperature different from that of the other constant current power supply unit is connected as the light source.

  In the above embodiment, the lighting fixture provided with one of said light source lighting devices was demonstrated.

  DESCRIPTION OF SYMBOLS 1 Commercial alternating current power supply, 2 Rectifier circuit, 1st smoothing capacitor, 4a, 4b switching element, 5a, 5b diode, 6a, 6b inductor, 7a, 7b 2nd smoothing capacitor, 8a, 8b LED, 9a, 9b LED current detection Resistance, 10a, 10b Drive circuit, 11 Control power supply circuit, 12 Shut-off switch, 13 Control circuit, 14 Commercial power supply detection circuit, 15a, 15b Insulation circuit, 16 Color temperature / dimming controller, 20a, 20b Control IC, 21a, 21b Diode, 22a, 22b operational amplifier, 23a, 23b capacitor, 24a, 24b resistor, 25a, 25b resistor, 26a, 26b capacitor, 27a, 27b discharge switch, 28a, 28b resistor, 29 AC-DC converter, 30 first step-down converter Chopper circuit, 31 2nd step-down Chopper circuit, 40 lighting fixture body, 41 light source lighting device 42 power line, 43 connector, 44 LED packages 45 mounted substrate, 110, 120 light source lighting device 200 luminaire.

Claims (5)

A converter that converts an AC voltage from a commercial AC power source into a DC voltage and outputs the converted DC voltage;
A constant current power supply unit connected to the conversion unit, a light source is connected and a constant current power supply unit that outputs a direct current to the connected light source by receiving drive control;
A drive unit that drives and controls the constant current power supply unit by receiving a supply of control power;
When the commercial AC power source is turned on, a control power source circuit unit that starts based on the commercial AC power source and starts generating the control power source based on the commercial AC power source;
A control power supply control unit that starts supplying the control power generated by the control power supply circuit unit to the drive unit when detecting the turning on of the commercial AC power supply,
The drive unit is
An integration circuit for continuously inputting a target signal indicating a target value of a direct current to be supplied to the light source connected to the constant current power supply unit, and outputting an output value corresponding to the target signal continuously input; ,
A comparison unit that compares a detection value corresponding to a direct current flowing through the light source connected to the constant current power supply unit and the output value of the integration circuit;
A control unit that drives and controls the constant current power supply unit based on a comparison result between the detection value and the output value by the comparison unit;
The control power supply controller is
With dimming controller inputs a signal to be output to the signal the integrator circuit to continue to input the target signal the driver in accordance with the signal triggered by the output from the dimming controller, before the opening Hajimesu Ru timing the output of the target signal to the integrating circuit of the serial driver, even when inputting the signal from the dimming controller, wherein the control power generated by the control power supply circuit unit A light source lighting device , wherein a predetermined period of time exceeding zero seconds has elapsed from the start of supply to the drive unit. The integrating circuit of the driving unit is:
RC integration circuit consisting of a resistor and a capacitor;
A shorting switch that short-circuits both ends of the capacitor by receiving control;
The control power supply controller is
2. The light source lighting device according to claim 1, wherein when the interruption of the commercial AC power supply is detected, both ends of the capacitor are short-circuited by the short-circuit switch of the integration circuit of the drive unit. The integrating circuit of the driving unit is:
RC integration circuit consisting of a resistor and a capacitor;
A shorting switch that short-circuits both ends of the capacitor by receiving control;
The control power supply controller is
3. The light source lighting according to claim 1, wherein when a turn-off signal instructing turn-off of the light source is input, both ends of the capacitor are short-circuited by the short-circuit switch of the integration circuit of the driving unit. apparatus. The light source lighting device is:
The light source lighting device according to any one of claims 1 to 3, wherein at least one of a light emitting diode and an organic EL (Electro Luminescence) is used as the light source.   An illumination fixture comprising the light source lighting device according to any one of claims 1 to 4.

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