JP6311232B2 - Lighting device - Google Patents

Description

  The present invention relates to a lighting device having a continuous light control function and a color variable function.

  A conventional lighting device includes an interface for inputting a PWM (Pulse Width Modulation) signal for continuous light control and a PWM signal for color adjustment. Therefore, the user changes the PWM signal input to the lighting device by operating the continuous light control controller connected to each interface and the color adjustment controller, and the light adjustment and color adjustment of the light source in the lighting device (For example, Patent Document 1).

JP2011-258515A

  However, the lighting device disclosed in Patent Document 1 has a problem in that it requires a dimming controller and a toning controller and is expensive.

  Further, if the dimming controller and the toning controller are combined into one controller, the dimming and the toning are executed at the same time, and only one of the dimming or the toning cannot be executed.

  In order to solve the above-described problem, a lighting device according to the present invention has one interface connected to a controller and to which a PWM signal is input, and is intended to enable dimming and toning separately. .

The lighting device of the present invention is a lighting circuit for lighting a first light source that is turned on according to a current supplied from an external power source and a second light source that is turned on at a different color temperature from the first light source. One interface for inputting a pulse signal, a first lighting control signal for adjusting a current supplied to the first light source in accordance with a change amount of the pulse signal inputted from the interface, and a second light source A control circuit for generating a second lighting control signal for adjusting the supplied current, and a first lighting control circuit for adjusting the current supplied to the first light source based on the first lighting control signal And a second lighting control circuit that adjusts a current supplied to the second light source based on the second lighting control signal, wherein the control circuit includes the first light source and the second light source. Current supplied to the light source The amount of change in the current supplied to the first light source and the second light source is different from the first operation mode for generating the first lighting control signal and the second lighting control signal so that the amount of change is equal. And a second operation mode for generating a first lighting control signal and a second lighting control signal, and a stop time from when a power switch connected to the external power source is turned off to when it is turned on. reset a timer for measuring the a shall comprise a counter for counting the number of times the stop time is equal to or less than the threshold value, the said control circuit, said if the stop time is greater than the threshold value of the counter and, when the counter if the value has reached the threshold and operation mode is said first mode switches the first operation mode to said second operation mode, or the value of the counter threshold Reached a lighting device and switches the second operation mode to said first mode of operation when the case and the operation mode is the second operation mode.
It is characterized by switching.

  The lighting device according to the present invention is configured to switch between the continuous dimming mode and the toning mode based on the number of times the power switch is turned off / on and the time interval from off to on. Dimming and toning can be performed individually without providing a plurality.

1 is a configuration diagram of a lighting device according to Embodiment 1. FIG. The figure explaining on-duty ratio. 3 is an operation flowchart of the lighting device according to the first embodiment. The figure which shows the relationship between the light output at the time of the continuous light control mode in the lighting device which concerns on Embodiment 1, and a PWM signal. FIG. 3 shows an example of light control in the lighting device according to Embodiment 1. FIG. The figure which shows the relationship between the light output at the time of the color variable mode in the lighting device which concerns on Embodiment 1, and a PWM signal. FIG. 3 shows an example of toning in the lighting device according to Embodiment 1. FIG. 4 is an operation flowchart when the operation mode of the control circuit according to the first embodiment is switched. 3 is an operation flowchart in a continuous light control mode of the control circuit according to the first embodiment. 4 is an operation flowchart in a color variable mode of the control circuit according to the first embodiment.

Embodiment 1
Hereinafter, the configuration of the lighting device according to Embodiment 1 will be described with reference to FIG.

  The lighting device 1 according to Embodiment 1 includes a diode bridge 11, a step-up chopper circuit 12, a control power supply circuit 15, an AC detection circuit 14, a PWM signal conversion circuit 16, a control circuit 17, a lighting circuit 13a, 13b. Further, the lighting device 1 is supplied with electric power from an AC power source (external power source (AC)) 2 when the power switch 5 is turned on by a user operation, and the light source module 4a (first light source) and the light source module 4b (first light source module 4b) Turn on the second light source. Further, the lighting device 1 receives the PWM signal (pulse signal) output from the controller 3 from the interface 18, and adjusts the current supplied to the light source modules 4a and 4b based on the PWM signal, thereby adjusting the current. Light or toning. The PWM signal is an electrical signal that repeatedly turns on and off. The dimming is to adjust the light output (the dimming degree) of the entire light source unit 4. Toning is to adjust the color temperature (light color) of light emitted from the entire light source unit 4.

  The diode bridge 11 is a circuit that rectifies an alternating current input from the alternating current power source 2 into a direct current.

  The boost chopper circuit 12 is a circuit that boosts the voltage of the direct current output from the diode bridge (DB) 11. The step-up chopper circuit 12 includes resistors R1, R2, Rs, an inductor L1, a diode D1, a MOS-FET Q1, an electrolytic capacitor C1, and a PFC control circuit 121. The resistors R1 and R2 detect the voltage waveform of the output voltage output from the diode bridge 11. The inductor L1 stores the output voltage of the diode bridge 11 as magnetic energy. The diode D1 is provided so that the boosted output voltage does not flow backward. The MOS-FET Q1 controls charging / discharging of the inductor L1 by turning on / off. The electrolytic capacitor C1 smoothes the output voltage. The PFC control circuit 121 controls on / off of the MOS-FET Q1. The resistor Rs detects a current flowing through the MOS-FET Q1.

  The lighting circuit 13 a adjusts the current supplied to the light source module 4 a based on the first lighting control signal output from the control circuit 17. Here, the first lighting control signal is a signal output from the control circuit 17 and represents a light output of the light source module 4a. The lighting circuit 13a includes an inductor L2a, a MOS-FET Q2a, a lighting control circuit 131a, an electrolytic capacitor C2a, a resistor R5a, and a diode D2a. The resistor R5a detects a current flowing through the light source module 4a. The MOS-FET Q2a controls charging / discharging of the inductor L2a and the capacitor C2a by turning on / off. The inductor L2a and the electrolytic capacitor C2a are connected to the output of the MOS-FET Q2a, output the output voltage, and step down and smooth the output voltage. The lighting control circuit 131a receives the first lighting control signal from the control circuit 17, and controls on / off of the MOS-FET Q2a. The diode D2a is for flowing a current according to the electromotive force generated when the inductor L2a keeps the current when the MOS-FET Q2a is off.

  The lighting circuit 13b adjusts the current supplied to the light source module 4b based on the second lighting control signal output from the control circuit 17. Here, the second lighting control signal is a signal output from the control circuit 17 and represents a light output of the light source module 4b. The lighting circuit 13b includes an inductor L2b, a MOS-FET Q2b, a lighting control circuit 131b, an electrolytic capacitor C2b, a resistor R5b, and a diode D2b. The resistor R5b detects a current flowing through the light source module 4b. The MOS-FET Q2b controls charging / discharging of the inductor L2b and the capacitor C2b by turning on / off. The inductor L2b and the electrolytic capacitor C2b are connected to the output of the MOS-FET Q2b, output the output voltage, and step down and smooth the output voltage. The lighting control circuit 131b receives the second lighting control signal from the control circuit 17, and controls on / off of the MOS-FET Q2b. The diode D2b is for flowing a current corresponding to the electromotive force generated when the inductor L2b keeps the current when the MOS-FET Q2b is off.

  The AC detection circuit 14 includes a diode D3 connected to the high potential side of the diode bridge 11 and resistors R6 and R7. The AC detection circuit 14 divides the pulsating current rectified by the diode bridge 11 by the resistors R 6 and R 7, and outputs the divided voltage to the control circuit 17.

  The control power supply circuit 15 supplies the control power supply Vcc to the PWM signal conversion circuit 16, the control circuit 17, and the lighting control circuits 131a and 131b.

  The PWM signal conversion circuit 16 generates a DC voltage corresponding to the on-duty ratio of the PWM signal input from the controller 3, and outputs the generated DC voltage to the control circuit 17. Here, as shown in FIG. 2, the on-duty ratio is a period from on to off with respect to a time T (time of one cycle) from when the PWM signal is turned on to when it is next turned on. The ratio of time t, specifically, on-duty ratio = (t / T) × 100 holds. The on-duty ratio is changed by the user operating the controller 3.

  Based on the DC voltage of the PWM signal conversion circuit 16, the control circuit 17 outputs a first lighting control signal to the lighting control circuit 131a and outputs a second lighting control signal to the lighting control circuit 131b. The control circuit 17 has two operation modes, a continuous light control mode (first operation mode) and a color variable mode (second operation mode), and the first lighting control is performed according to the operation mode. Adjust the value of the signal and the second lighting control signal. Further, the control circuit 17 can determine on / off of the power switch 5 based on the divided voltage output from the AC detection circuit 14. That is, the control circuit 17 determines that the power switch 5 is on when the divided voltage is supplied, and determines that the power switch 5 is off when the divided voltage is not supplied. The operation mode of the control circuit 17 is switched based on the number of times the power switch 5 is turned off / on and the time interval from off to on. The control circuit 17 corresponds to, for example, a microcomputer. The control circuit 17 can continue to operate for a certain period of time because the control power circuit 15 operates due to the residual charge of the electrolytic capacitor C1 even when the power from the AC power source 2 input to the lighting device 1 is cut off. Shall. Further, the operation for switching the operation mode by the on / off operation of the power switch 5 is referred to as a pullless operation in the following description.

  The light source unit 4 is a light emitting device capable of toning and dimming. The light source unit 4 includes light source modules 4a and 4b.

  The light source module 4a receives the current output from the lighting circuit 13a and emits light with a light output corresponding to the current. For example, the light source module 4a includes a plurality of LEDs (Light Emitting Diodes) connected in series, and is white with a color temperature of 5000K.

  The light source module 4b receives the current output from the lighting circuit 13b and emits light with a light output corresponding to the current. For example, the light source module 4b includes a plurality of LEDs connected in series, and the emission color is white with a color temperature of 3500K.

  Thus, since the color temperatures of the light source modules 4a and 4b are different from each other, the light source unit 4 as a whole can achieve toning by adjusting the current value input to the light source modules 4a and 4b. The light source unit 4 can realize dimming by equalizing the amount of change in the current value input to the light source modules 4a and 4b.

  In the description of the lighting device 1 according to Embodiment 1, the light source modules 4a and 4b are assumed to be five LEDs connected in series. However, the present invention is not limited to this, and an arbitrary number of LEDs are connected in series. It may be. The light source modules 4a and 4b may be configured by connecting LEDs in parallel. Further, the light emission color of the light source module 4a is 5000K white, and the light emission color of the light source module 4b is 3500K white. However, the present invention is not limited to this, and the light emission modules 4a and 4b may have different emission colors. Good. The light emission color of the LEDs of the light source modules 4a and 4b is not limited to white of 5000K or 3500K, and may be a different color temperature such as 6000K, or may be a single color such as red, green, or blue. Furthermore, although the light source unit 4 is composed of two light source modules, the light source modules 4a and 4b, the present invention is not limited to this, and it may be composed of two or more light source modules. The color temperature is a numerical value (K) representing the color of the light source. As the value becomes smaller, the color becomes closer to red (for example, a light bulb color), and as the value becomes larger, the color becomes closer to blue (for example, , Daylight color).

  Hereinafter, the operation of the lighting device according to Embodiment 1 will be described with reference to FIGS. 3 to 10. FIG. 3 is an operation flowchart of the lighting device according to the first embodiment. In the following description, it is assumed that the color temperature of the light source module 4a is 5000K, and the color temperature of the light source module 4b is 3500K.

  In the starting operation, when the user operates the power switch 5 outside the lighting device 1, an alternating current is supplied from the controller 3 to the lighting device 1. The power switch 5 may be an embedded switch provided on the wall of the room, or may be operated by a remote controller or the like. The supplied alternating current is rectified into a direct current by the diode bridge 11 and supplied to the step-up chopper circuit 12.

  In ST1, the boost chopper circuit 12 boosts the voltage of the supplied direct current and outputs it to the control power supply circuit 15, the MOS-FET Q2a of the lighting circuit 13a, and the MOS-FET Q2b of the lighting circuit 13b.

  The control power supply circuit 15 receives the direct current supplied from the step-up chopper circuit 12 and outputs it to the PWM signal conversion circuit 16, the control circuit 17, and the lighting control circuits 131a and 131b. As described above, the PWM signal conversion circuit 16, the control circuit 17, and the lighting control circuits 131a and 131b are operated by the power supplied from the control power supply circuit 15.

  In ST2, the control circuit 17 reads the current setting values of the light source modules 4a and 4b from an internal memory (not shown), and outputs a first lighting control signal and a second lighting control signal. Here, the set value indicates the light output of the light source modules 4a and 4b when the user lastly turned on the light source modules 4a and 4b. This set value is composed of dimming setting information or color variable setting information. The dimming setting information represents the light output of the light source modules 4a and 4b set last by the user's operation of the controller 3 when the operation mode is the continuous dimming mode. The color variable setting information represents the light output of the light source modules 4a and 4b set last by the user's operation of the controller 3 in the color variable mode.

  The lighting control circuit 131a controls on / off of the MOS-FET Q2a (controls the on-duty ratio of the MOS-FET Q2a) based on the first lighting control signal, and controls the DC current supplied from the boost chopper circuit 12. The current value is adjusted, and the adjusted direct current is supplied to the light source module 4a.

  Further, the lighting control circuit 131b controls the MOS-FET Q2b (controls the on-duty ratio of the MOS-FET Q2b) based on the second lighting control signal, and determines the current value of the direct current supplied from the boost chopper circuit 12. The adjusted direct current is supplied to the light source module 4b. The light source modules 4a and 4b are lit with an optical output corresponding to the supplied current value.

  In ST3, the user performs a dimming operation on the light source unit 4 that is turned on. In ST3, the operation mode of the control circuit 17 is assumed to be a dimming mode. A PWM signal is input from the controller 3 to the lighting device 1 by the operation of the controller 3 by the user. The input PWM signal is converted into a DC voltage corresponding to the on-duty ratio of the PWM signal by the PWM signal conversion circuit 16 and input to the control circuit 17.

  In ST4, the control circuit 17 outputs the first lighting control signal to the lighting control circuit 131a and the second lighting control circuit 131b to the lighting control circuit 131b according to the DC voltage corresponding to the on-duty ratio of the PWM signal. Since the operation is similar to that of the lighting control circuits 131a and 131b in ST2, the description thereof is omitted.

  Here, the relationship between the PWM signal in the continuous light control mode and the light source unit 4 will be described. FIG. 4A is a diagram showing a relationship between the light output and the PWM signal in the continuous light control mode in the light source module 4a according to the first embodiment. FIG. 4B is a diagram illustrating a relationship between the light output and the PWM signal in the continuous light control mode in the light source module 4b according to the first embodiment. FIG. 4C is a diagram showing a relationship between the light output and the PWM signal in the continuous light control mode in the light source unit 4 according to the first embodiment. As shown in FIGS. 4A and 4B, when the control circuit 17 is in the continuous light control mode, the amount of change in the light output of the light source module 4a and the light source module 4b is the same. For example, when the on-duty ratio indicated by the PWM signal is 90%, the light outputs of the light source modules 4a and 4b are assumed to be 10% of the maximum value. When the on-duty ratio is changed to 5% by the controller 3, the light output of the light source module 4a becomes 50% (FIG. 4A), and the light output of the other light source module 4b also becomes 50% (FIG. 4B). )).

  A change in light of the entire light source unit 4 at this time will be described with reference to FIG. For example, FIG. 5A is an example in which a PWM signal indicating an on-duty ratio of 90% is input to the lighting device 1. As described with reference to FIG. 4, when the on-duty ratio of the PWM signal is 90%, the light source modules 4a and 4b are respectively turned on with an optical output of 10%. Therefore, the light output (dimming degree) of the entire light source unit 4 in FIG. 5A is 20%. The color temperature is an intermediate color between the color temperatures of the light source module 4a and the light source module 4b.

  On the other hand, when a PWM signal having an on-duty ratio of 5% is input (FIG. 5B), the light source modules 4a and 4b are turned on with an optical output of 50%. Accordingly, the light output (dimming degree) of the entire light source unit 4 in FIG. 5B is 100% (FIG. 4C). The color temperature is an intermediate color between the color temperatures of the light source module 4a and the light source module 4b as in the case of FIG. In this manner, the lighting device 1 can realize light control by controlling the light output of the light source modules 4a and 4b according to the value of the PWM signal.

  In ST5, the user performs an operation mode switching operation. Switching of the operation mode is realized by a pullless operation of the power switch 5. For example, when the user repeatedly turns off / on the power switch 5 from the on state (the interval between the off and on is within 2 seconds) four times, the control circuit 17 executes switching of the operation mode. The control circuit 17 can detect OFF / ON by the divided voltage output from the AC power supply detection circuit 14. Further, the control circuit 17 can detect the OFF / ON interval by an internal timer (not shown).

  In ST6, the user performs a toning operation of the light source unit 4. It is assumed that the operation mode of the control circuit 17 is switched to the color variable mode by the user's pullless operation in ST5. A PWM signal is input from the controller 3 to the lighting device 1 by the operation of the controller 3 by the user. The input PWM signal is converted into a DC voltage corresponding to the on-duty ratio of the PWM signal by the PWM signal conversion circuit 16 and input to the control circuit 17.

  In ST7, the control circuit 17 outputs the first lighting control signal to the lighting control circuit 131a and the second lighting control circuit 131b to the lighting control circuit 131b according to the DC voltage corresponding to the on-duty ratio of the PWM signal. Since the operation is similar to that of the lighting control circuits 131a and 131b in ST2 and ST4, the description thereof is omitted.

  Here, the relationship between the PWM signal and the light source unit 4 in the color variable mode will be described. FIG. 6A is a diagram showing the relationship between the light output and the PWM signal in the color variable mode in the light source module 4a according to the first embodiment. FIG. 6B is a diagram illustrating a relationship between the light output and the PWM signal in the color variable mode in the light source module 4b according to the first embodiment. FIG. 6C is a diagram showing the relationship between the light output and the PWM signal in the color variable mode in the light source unit 4 according to the first embodiment. As shown in FIGS. 6A and 6B, when the control circuit 17 is in the color variable mode, the control circuit 17 increases the light of the light source module 4a when the on-duty ratio indicated by the received PWM signal increases. A first lighting control signal is output so that the output increases. On the other hand, the control circuit 17 outputs the second lighting control signal so that the light output of the light source module 4b decreases when the on-duty ratio indicated by the PWM signal increases.

  For example, when the light output (dimming degree) of the entire light source unit 4 is 100% and the on-duty ratio of the PWM signal is 90%, the light output of the light source module 4a is 90% and the light output of the light source module 4b is 10%. %. At this time, if the on-duty of the PWM signal is changed to 5% by the user's operation of the controller 3, the light output of the light source module 4a is reduced to 10% (FIG. 6 (a)). On the other hand, the light output of the light source module 4b increases to 90% (FIG. 6B).

  Changes in the light of the entire light source unit 4 at this time will be described with reference to FIG. For example, FIG. 7A shows an example in which a PWM signal having an on-duty ratio of 90% is input to the lighting device 1. As described with reference to FIG. 6, when the on-duty ratio of the PWM signal is 90%, the light source module 4a is turned on with an optical output of 90%, and the light source module 4b is turned on with an optical output of 10%. Accordingly, the light output (dimming degree) of the entire light source unit 4 in FIG. 7A is 100%. The color temperature is an intermediate color between 90% of the color temperature 5000K of the light source module 4a and 10% of the color temperature 3500K of the light source module 4b. In other words, the color temperature in this case is closer to 5000K.

  On the other hand, as shown in FIG. 7B, when a PWM signal having an on-duty ratio of 5% is input, the light source module 4a is turned on with an optical output of 10% and the light source module 4b is turned on with an optical output of 90%. At this time, the light output (dimming degree) of the entire light source unit 4 is 100%, which is the same as the light output (dimming degree) of the entire light source unit 4 shown in FIG. On the other hand, the color temperature is an intermediate color between 10% of the color temperature 5000K of the light source module 4a and 90% of the color temperature 3500K of the light source module 4b. That is, the color temperature of the entire light source unit 4 in FIG. 7B is closer to 3500 K than the color temperature of the light source unit 4 in FIG. Thus, in the color variable mode, the color temperature of the entire light source unit 4 can be changed by changing the on-duty ratio of the PWM signal output from the controller 3.

  In the color variable mode, when the on-duty ratio indicated by the PWM signal is decreased, the light output of the light source module 4a is decreased and the light output of the light source module 4b is increased. The light output of the light source module 4b may be decreased. The light source unit 4 has been described with respect to the case where the light output of the light source module 4b decreases when the light output of the light source module 4a increases. However, the increase rate of the light output of the light source module 4a and the light output of the light source module 4b are described. If the increase rate of the light source module 4a is different, the color temperature can be changed even if the light output of the light source module 4b is increased as the light output of the light source module 4a increases. Furthermore, the increase rate and the decrease rate of the light outputs of the light source modules 4a and 4b may be at least different and are not limited to the numerical values described in the present embodiment. 4 and 6, the light output of one of the light source module 4a and the light source module 4b may be 0%. In this case, the light source module that is not 0% of the light source module 4a and the light source module 4b can have a light output of 100%.

  In the ending operation, when the user turns off the power switch 5, the lighting device 1 turns off the light source unit 4 after the power supplied from the AC power supply 2 is cut off.

  With the above operation, a series of operations of the lighting device 1 according to Embodiment 1 is completed.

Note that the order of the ST3 light adjustment operation and ST6 light adjustment operation in the description of FIG. 3 is not limited to this, and the color adjustment operation is performed first, and then the operation mode switching operation (ST5) is performed, followed by the light adjustment operation of ST3 An operation may be performed.

  Next, the operation of the control circuit 17 during the operation mode switching described in ST5 will be described in detail with reference to FIG. FIG. 8 is an operation flowchart when the operation mode of the control circuit according to the first embodiment is switched. In the description of the operation flowchart of FIG. 8, it is assumed that the control circuit 17 starts the operation when power is supplied from the power supply control circuit 15.

  In ST51, the control circuit 17 resets an internal counter (not shown) (n = 0). The value n of the counter indicates the number of times that the power switch 5 is turned off / on by the user within 2 seconds.

In ST52, the control circuit 17 determines the presence or absence of AC power supply based on the divided voltage output from the AC detection circuit 14. If it is determined that AC power is not supplied, the process proceeds to ST53. That is, when the power switch 5 is turned off by the user, the process proceeds to ST53. In ST 52, if it is determined that AC power supply, until it is determined that there is no AC power supply, repeated ST52.

In ST53, the control circuit 17 counts the AC power supply stop time T after the internal timer determines that there is no AC power supply in ST52. The AC power supply output stop time T here refers to the time from when it is determined that there is no AC power supply in ST52 until it is determined that there is AC power supply in ST54 described later.

  In ST54, the control circuit 17 determines again whether or not AC power is supplied. If it is determined that there is AC power feeding, the process proceeds to ST55. That is, when the user turns on the power switch 5 again, the process proceeds to ST54.

  In ST55, when the output stop time T counted by the timer is 2 seconds or less, the control circuit 17 proceeds to ST56. On the other hand, when the output stop time T counted by the timer is longer than 2 seconds, the control circuit 17 resets the timer output stop time T and the counter value n (ST51), and returns to ST52.

  In ST56, the control circuit 17 adds 1 to the counter value (n = n + 1).

  In ST57, the control circuit 17 performs switching determination of the operation mode. Specifically, control circuit 17 determines that the operation mode is to be switched when counter value n = 4, and proceeds to ST58. Here, the counter value n = 4 means that the power switch 5 is operated by the user at intervals of 2 seconds or less between OFF and ON, and this operation is performed four times. If the counter value n is less than 4, the timer output stop time T is reset, the process returns to ST52, and ST52 to ST57 are repeated until the counter value n = 4.

  In ST58, the control circuit 17 determines the current operation mode. If the current operation mode is the continuous light control mode, the process proceeds to ST59a. If the current operation mode is the color variable mode, the process proceeds to ST59b.

  In ST59a, the control circuit 17 switches the operation mode to the color variable mode and ends the operation.

  In ST59b, the control circuit 17 switches the operation mode to the continuous light control mode and ends the operation.

  In FIG. 8, the description has been given by using an example in which OFF / ON is repeated four times at intervals of 2 seconds or less (stop time T) when switching the operation mode. However, the present invention is not limited to this, and the control according to the present embodiment is performed. In the circuit, an arbitrary stop time T and the number of times of off / on can be set. For example, if the control circuit 17 is to switch the operation mode when the off / on interval is 3 seconds or less and the operation is switched twice, the condition of the stop time T in ST55 is set to 3 seconds or less, and the counter of ST57 The condition for the value n may be n = 2.

  Next, the operation of the control circuit 17 in the continuous dimming mode described in ST3 will be described in detail with reference to FIG. FIG. 9 is an operation flowchart in the continuous dimming mode of the control circuit according to the first embodiment. In the operation flowchart of FIG. 9, the control circuit 17 starts the operation when the operation mode is switched from the color variable mode to the continuous light control mode.

  In ST31, the control circuit 17 reads the color variable setting information from the memory.

  In ST32, the control circuit 17 generates a first lighting control signal and a second lighting control signal based on the color variable setting information. When a PWM signal is input to the lighting device 1 from the controller 3, the first lighting control signal and the second lighting control signal are generated based on the color variable setting information and the on-duty ratio of the PWM signal.

  In ST33, the control circuit 17 outputs the generated first lighting control signal to the first lighting control circuit 131a, and outputs the second lighting control signal to the second lighting control circuit 131b.

  In ST34, the control circuit 17 determines whether or not the operation mode is switched by the user's pullless operation. If the operation mode is switched, the process proceeds to ST35. If the operation mode is not switched, the process returns to ST32.

  In ST35, the control circuit 17 executes ST58 and ST59a in FIG. 8 and switches the operation mode to the color variable mode.

  In ST36, the control circuit 17 stores the on-duty ratio corresponding to the PWM signal input to the lighting device 1 in ST32 in the memory, and ends the operation. In ST32, when the PWM signal is not input from the controller 3, the value of the color variable setting information read in ST31 is stored in the memory as the dimming setting information.

  Next, the operation of the control circuit 17 in the color variable mode described in ST6 will be described in detail with reference to FIG. FIG. 10 is an operation flowchart in the color variable mode of the control circuit according to the first embodiment. In the operation flowchart of FIG. 10, the control circuit 17 starts the operation when the operation mode is switched from the continuous light control mode to the color variable mode.

  In ST61, the control circuit 17 reads the dimming setting information from the memory. This dimming setting information is information stored in the memory in ST36 of FIG.

  In ST62, the control circuit 17 generates a first lighting control signal and a second lighting control signal based on the dimming setting information. When a PWM signal is input to the lighting device 1 from the controller 3, the first lighting control signal and the second lighting control signal are generated based on the dimming setting information and the on-duty ratio of the PWM signal.

  Since ST63 and ST64 are the same operations as ST33 and ST34 of FIG. 9, description thereof is omitted.

In ST65, the control circuit 17 performs the ST58 and ST59 b in FIG. 8, switches the operation mode to continuous dimming mode.

In ST66, the control circuit 17 stores the on-duty ratio corresponding to the PWM signal input to the lighting device 1 in ST62 in the memory, and ends the operation. Further, in ST62, stores the controller 3 when the PWM signal is not input, the memory value of the read-out light control setting information in ST 6 1 as the color variable setting information.

  Although the control circuit 17 according to the first embodiment has the continuous light control mode and the color variable mode, the present invention is not limited to this, and as long as it has at least the continuous light control mode and the color variable mode. Of course, other operation modes may be added. For example, a step dimming mode that performs dimming step by step may be provided.

  As described above, the lighting device 1 according to the first embodiment includes the control circuit 17 having the continuous light control mode and the color variable mode, and the operation mode of the control circuit 17 is switched by the pullless operation of the power switch 5. Therefore, continuous light control and color adjustment can be realized without providing a plurality of interfaces to which PWM signals are input.

  DESCRIPTION OF SYMBOLS 1 Lighting device, 2 AC power supply, 3 Controller, 4 Light source unit, 4a Light source module, 4b Light source module, 5 Power switch, 12 Boost chopper circuit, 13a Lighting circuit, 13b Lighting circuit, 14 AC detection circuit, 15 Control power supply circuit, 16 PWM signal conversion circuit, 17 control circuit, 18 interface, 121 PFC control circuit, 131a lighting control circuit, 131b lighting control circuit.

Claims (2)

In a lighting circuit for lighting a first light source that lights in response to a current supplied from an external power source and a second light source that lights at a different color temperature from the first light source,
One interface for inputting pulse signals from outside,
According to the change amount of the pulse signal input from the interface,
A control circuit for generating a first lighting control signal for adjusting the current supplied to the first light source and a second lighting control signal for adjusting the current supplied to the second light source;
A first lighting control circuit for adjusting a current supplied to the first light source based on the first lighting control signal;
A second lighting control circuit for adjusting a current supplied to the second light source based on the second lighting control signal;
With
The control circuit includes:
A first operation mode for generating the first lighting control signal and the second lighting control signal so that the amount of change in current supplied to the first light source and the second light source is equal;
A second operation mode for generating a first lighting control signal and a second lighting control signal so that the amount of change in current supplied to the first light source and the second light source is different;
A timer for measuring a stop time from when the power switch connected to the external power source is turned off to when it is turned on;
A counter that counts the number of times the stop time is equal to or less than a threshold;
A shall include a,
The control circuit resets the value of the counter when the stop time is larger than a threshold,
When the value of the counter reaches a threshold and the operation mode is the first mode, the first operation mode is switched to the second operation mode, or the value of the counter reaches the threshold When the operation mode is the second operation mode, the lighting device is characterized in that the second operation mode is switched to the first operation mode .
The control circuit includes a memory that stores an on-duty ratio of the pulse signal corresponding to the first lighting control signal and the second lighting control signal when the switching of the operation mode is completed. The lighting device according to claim 1.

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