JP2018097911A - Controller, lighting device, luminaire and lighting control method - Google Patents

Abstract

Provided are a control device, a lighting device, a lighting fixture, and a lighting control method capable of more appropriately performing dimming control when a solid-state light source that is turned off is turned on. A storage unit 332 includes a time sequence in which a dimming level instruction value X1 is input to a conversion circuit 32 until a physical quantity reaches a predetermined value after the dimming level instruction value X1 reaches a lighting threshold value. Is stored as a stored value S2. The control unit 30 controls on / off of the switching element Q2 based on the dimming level instruction value X1 until the physical quantity reaches a predetermined value. After the physical quantity reaches a predetermined value, the control unit 30 controls on / off of the switching element Q2 based on the stored value S2 according to a temporal order. [Selection] Figure 1

Description

  The present invention relates to a control device, a lighting device, a lighting fixture, and a lighting control method, and more particularly to a control device, a lighting device, a lighting fixture, and a lighting control method for lighting a solid light source.

  A light source lighting device described in Patent Document 1 is illustrated as a conventional example. The light source lighting device described in Patent Document 1 includes a DC / DC converter (power supply circuit), an LED current detection resistor, and a control circuit. The DC / DC converter has a switching element connected in series to the LED module (solid light source) and a smoothing capacitor connected in parallel to the LED module. The DC / DC converter supplies a current to the LED module and causes the LED module to emit light. The LED current detection resistor detects a current flowing through the LED module. A dimming signal indicating a target current value to be passed through the LED module is input to the control circuit. The control circuit compares the current detected by the LED current detection resistor with the target current value of the LED module indicated by the dimming signal, and turns on / off the switching element so that the current flowing through the LED module becomes the target current value. Control off. Thereby, dimming control for the LED module is performed.

JP 2012-222322 A

  As described above, in the light source lighting device described in Patent Document 1, the smoothing capacitor is connected in parallel to the LED module. For this reason, when lighting the LED module in the off state, it takes time until the voltage applied to the LED module reaches the voltage necessary for lighting the LED module after the smoothing capacitor is completely charged. Cost. Therefore, when the dimming signal is changed with time, the dimming control at the start of lighting of the LED module is different from the dimming signal initially input to the control circuit when the LED module is turned off. The light control is based on the optical signal. For example, when a dimming signal is input so that the target current value increases smoothly from zero when the LED module is turned off, the dimming signal input at the start of lighting of the LED module is zero. Instead, a target current value that is somewhat large is indicated. Since the control circuit controls on / off of the switching element so that the current flowing through the LED module becomes such a target current value, the LED module is not brightened smoothly from the extinguished state, but rapidly brightened. Light. As described above, in the light source lighting device described in Patent Document 1, since the dimming control based on the dimming signal first input to the control circuit cannot be performed, the dimming control at the start of lighting may not be appropriate. there were.

  It is an object of the present invention to provide a control device, a lighting device, a lighting fixture, and a lighting control method that can more appropriately perform dimming control when a solid light source that is turned off is turned on.

  In order to solve the above problems, a control device according to one embodiment of the present invention is a control device that controls a power supply circuit to control a dimming level of a solid-state light source. The power supply circuit includes a capacitor and a switching element. The solid-state light source is connected in parallel to the capacitor. The switching element increases or decreases the power supplied to the solid state light source by turning on and off. The control device includes an input unit, an acquisition unit, a storage unit, and a control unit. The input unit accepts continuous or intermittent input of a dimming level instruction value. The dimming level instruction value indicates the dimming level. The acquisition unit acquires a physical quantity. The physical quantity corresponds to a voltage applied to the solid state light source. The storage unit holds at least a time order in which the dimming level instruction values are input to the input unit until the physical quantity reaches a predetermined value after the dimming level instruction value reaches a lighting threshold. Is stored as a stored value. The lighting threshold indicates the smallest dimming level in a range where the solid light source is turned on. The predetermined value corresponds to a lighting voltage of the solid light source. The controller controls on / off of the switching element based on the dimming level instruction value until the physical quantity reaches the predetermined value. The control unit controls on / off of the switching element based on the stored value in accordance with the temporal order after the physical quantity reaches the predetermined value.

  A lighting device according to an aspect of the present invention includes the control device and the power supply circuit.

  The lighting fixture which concerns on 1 aspect of this invention is equipped with the said control apparatus, the said power supply circuit, and the said solid light source.

  A lighting control method according to one aspect of the present invention is a lighting control method for controlling a light control level of a solid-state light source by controlling a power supply circuit. The power supply circuit includes a capacitor and a switching element. The solid-state light source is connected in parallel to the capacitor. The switching element increases or decreases the power supplied to the solid state light source by turning on and off. The lighting control method includes an input step, an acquisition step, a storage step, a first control step, and a second control step. In the input step, continuous or intermittent input of a dimming level instruction value is accepted. The dimming level instruction value indicates the dimming level. In the acquisition step, a physical quantity is acquired. The physical quantity corresponds to a voltage applied to the solid state light source. In the storing step, at least until the physical quantity reaches a predetermined value after the dimming level instruction value reaches the lighting threshold, the dimming level instruction value is kept in the temporal order input in the input step. Is stored as a stored value. The lighting threshold indicates the smallest dimming level in a range where the solid light source is turned on. The predetermined value corresponds to a lighting voltage of the solid light source. In the first control step, on / off of the switching element is controlled based on the dimming level instruction value until the physical quantity reaches the predetermined value. In the second control step, after the physical quantity reaches the predetermined value, on / off of the switching element is controlled based on the stored value according to the temporal order.

  In the control device, the lighting device, the lighting fixture, and the lighting control method according to one embodiment of the present invention, it is possible to more appropriately perform dimming control when the solid light source in the off state is turned on.

FIG. 1 is a circuit diagram of a lighting fixture according to Embodiment 1 of the present invention. FIG. 2 is a graph showing the correspondence between the dimming level instruction value and the dimming level in the same lighting fixture. FIG. 3A is a graph showing control values in the above-described lighting apparatus. FIG. 3B is a graph showing a voltage applied to a solid-state light source in the lighting fixture same as above. FIG. 3C is a graph showing a current flowing through a solid-state light source in the lighting fixture same as above. FIG. 4 is a perspective view of the same lighting fixture. FIG. 5 is a block diagram of a lighting system including a plurality of the lighting fixtures. FIG. 6A is a graph showing control values in the lighting fixture according to Embodiment 2 of the present invention. FIG. 6B is a graph showing a voltage applied to a solid-state light source in the lighting fixture same as above. FIG. 6C is a graph showing a current flowing through a solid-state light source in the lighting fixture same as above. FIG. 7 is a circuit diagram of a lighting fixture according to Embodiment 3 of the present invention.

(Embodiment 1)
Hereinafter, the control device, the lighting device, the lighting fixture, and the lighting control method according to the first embodiment will be described with reference to FIGS.

  The lighting fixture 4 of this embodiment has the lighting device 2 and the solid light source 40, as shown in FIG. The solid-state light source 40 includes a plurality (only two are shown in FIG. 1) of LED (Light Emitting Diode) elements 41. However, the number of LED elements 41 is not limited to two, and may be one or three or more. Moreover, it can replace with the LED element 41 and can also use an organic electroluminescent element or a laser diode element.

  The lighting device 2 of the present embodiment includes a control device 1, an input filter 11, a rectifier circuit 12, a step-up chopper circuit 13, and a step-down chopper circuit 14 (power supply circuit).

  The control device 1 of the present embodiment includes a control unit 3 and a detection circuit 21 (acquisition unit). The control unit 3 includes a control unit 30, a boost control circuit 31, a conversion circuit 32 (input unit), a storage unit 332, and an A / D conversion port 333. The control unit 30 includes a step-down control circuit 34, a processing unit 331, and a signal transmission unit 334. The processing unit 331 is configured by, for example, a CPU (Central Processing Unit). The signal transmission unit 334 has a plurality of output terminals (not shown). The processing unit 331, the storage unit 332, the A / D conversion port 333, and the signal transmission unit 334 constitute a microcomputer 33 (hereinafter referred to as the microcomputer 33).

  The input filter 11 removes unnecessary frequency components such as noise from the AC power input from the commercial power supply 100.

  The rectifier circuit 12 outputs a rectified voltage obtained by rectifying (full-wave rectification or half-wave rectification) the AC voltage input via the input filter 11. The rectifier circuit 12 is configured by a diode bridge, for example.

  The step-up chopper circuit 13 includes an insulating transformer T1 having an inductor L1 and a diode D1. One end of the inductor L1 is connected to the output terminal on the high potential side of the rectifier circuit 12, and the other end is connected to the anode of the diode D1. Further, the step-up chopper circuit 13 has a series circuit of a switching element Q1 and a resistor R1. For example, an n-channel enhancement type field effect transistor is used as the switching element Q1. The drain of the switching element Q1 is connected to a connection point between the inductor L1 and the diode D1. One end of the resistor R1 is connected to the source of the switching element Q1, and the other end is connected to the output terminal on the low potential side of the rectifier circuit 12. Further, the step-up chopper circuit 13 has a capacitor C1 connected to the cathode of the diode D1 and the output terminal on the low potential side of the rectifier circuit 12. In the step-up chopper circuit 13, the switching element Q1 is turned on / off, whereby a step-up voltage is generated between both ends of the capacitor C1 (two output ends of the step-up chopper circuit 13).

  The step-down chopper circuit 14 includes a switching element Q2, an insulating transformer T2 having an inductor L2, a capacitor C2, and a resistor R2. The switching element Q2, the inductor L2, the capacitor C2, and the resistor R2 are connected in series between both ends of the capacitor C1 of the boost chopper circuit 13 in this order. For example, an n-channel enhancement type field effect transistor is used as the switching element Q2. The drain of the switching element Q2 is connected to the high potential side of the capacitor C1, and the source of the switching element Q2 is connected to the inductor L2. Further, the step-down chopper circuit 14 has a regenerative diode D2 connected in parallel to a series circuit of an inductor L2 and a capacitor C2. The anode of the diode D2 is connected to the connection point between the capacitor C2 and the resistor R2. In the step-down chopper circuit 14, when the switching element Q2 is turned on / off, a step-down voltage is generated between both ends of the capacitor C2 (two output ends of the step-down chopper circuit 14).

  A solid light source 40 is connected between both ends of the capacitor C <b> 2 of the step-down chopper circuit 14. The electric power output from the step-up chopper circuit 13 is input to the step-down chopper circuit 14 and supplied to the solid state light source 40. The switching element Q2 increases or decreases the power supplied to the solid state light source 40 by turning on and off. Since the solid light source 40 is connected in parallel to the capacitor C2, the applied voltage Vo1, which is a voltage applied to the solid light source 40, has a waveform in which ripple is suppressed. That is, the capacitor C2 smoothes the applied voltage Vo1.

  When the step-down chopper circuit 14 is controlled by the control device 1, the dimming level of the solid light source 40 is controlled. The dimming level indicates the brightness of the solid light source 40. Details of the dimming control by the control device 1 will be described later.

  When the capacitor C2 is charged by the power supplied from the step-up chopper circuit 13 via the switching element Q2, and the applied voltage Vo1 (the voltage across the capacitor C2) reaches the lighting voltage VL1 (see FIG. 3B), the solid state light source 40 lights up. That is, the lighting voltage VL1 is a voltage at which the solid light source 40 starts to light. The lighting voltage VL1 of the solid light source 40 is determined by the forward voltage, the number, the arrangement, and the like of the plurality of LED elements 41 constituting the solid light source 40.

  The detection circuit 21 includes a series circuit of two resistors R3 and R4. One end of the resistor R3 is connected to the high potential side of the capacitor C2, and the other end is connected to the resistor R4 and the microcomputer 33 of the control unit 3. The end of the resistor R4 opposite to the side connected to the resistor R3 is grounded. The detection circuit 21 detects the applied voltage Vo1 applied to the solid-state light source 40 as a divided voltage of the two resistors R3 and R4 (acquisition step), and detects the detected voltage value (physical quantity) that is the detected voltage value. To the microcomputer 33.

  The storage unit 332 of the microcomputer 33 stores a predetermined voltage value (predetermined value). The predetermined voltage value is set to a value corresponding to the lighting voltage VL1 (see FIG. 3B). Specifically, the predetermined voltage value is set so that the applied voltage Vo1 becomes substantially equal to the lighting voltage VL1 when the detected voltage value becomes the predetermined voltage value. Since the detection voltage value is output to the microcomputer 33 as a value obtained by dividing the applied voltage Vo1 by the resistors R3 and R4 of the detection circuit 21, the predetermined voltage value is obtained by dividing the lighting voltage VL1 of the solid light source 40 by R3 and R4. Is set to be approximately equal to

  The step-up control circuit 31 of the control unit 3 performs current feedback control for determining the on-timing of the switching element Q1 by comparing the current value flowing through the inductor L1 detected by the isolation transformer T1 with a threshold value. The boost control circuit 31 detects the voltage across the resistor R1 (the value of the current flowing through the switching element Q1) and compares it with a threshold value to perform voltage feedback control that determines the off timing of the switching element Q1. The boost control circuit 31 outputs a PWM (Pulse Width Modulation) signal corresponding to the determined on timing and off timing to the gate of the switching element Q1. The step-up control circuit 31 controls the step-up operation of the step-up chopper circuit 13 by controlling the ON timing and the OFF timing of the switching element Q1 by the PWM signal. That is, the boost control circuit 31 controls the on / off of the switching element Q1 to control the boost voltage generated across the capacitor C1 to a predetermined voltage.

  The conversion circuit 32 of the control unit 3 accepts continuous or intermittent input of a dimming signal having a dimming level instruction value X1 (input step).

  As shown in FIG. 2, the dimming level instruction value X <b> 1 indicates the dimming level of the solid light source 40. The horizontal axis of FIG. 2 indicates the dimming level instruction value X1 of the dimming signal, and the vertical axis indicates the current that flows to the solid state light source 40 by the control device 1 after the dimming level instruction value X1 is input to the conversion circuit 32. Is adjusted as a percentage, with the maximum value of current being 100%. The light control level of the solid light source 40 becomes large, so that the electric current which flows into the solid light source 40 is large. The light control level is a value of 0 to 100%, and it is assumed that the solid light source 40 is lit brighter as the light control level is higher. When the dimming level instruction value X1 is 0%, the current flowing through the solid light source 40 is the minimum 0 [A], the dimming level is 0%, and the solid light source 40 is turned off. When the dimming level instruction value X1 is 100%, the current flowing through the solid light source 40 is maximum, the dimming level is 100%, and the solid light source 40 is fully lit. When the dimming level instruction value X1 is less than the lighting threshold value XT3, the dimming level is 0%. When the dimming level instruction value X1 is greater than or equal to the lighting threshold value XT3, the dimming level instruction value X1 increases as the dimming level instruction value X1 increases. The level is also great. The dimming signal is, for example, a DMX (Digital Multiplex) signal.

  As shown in FIG. 1, the conversion circuit 32 converts the dimming signal into a DC voltage V <b> 1 and inputs it to the A / D conversion port 333 of the microcomputer 33. As the dimming level instruction value X1 of the dimming signal is larger, the dimming signal is converted into a larger DC voltage V1.

  The A / D conversion port 333 performs A / D conversion on the DC voltage V1. Hereinafter, a DC voltage generated by A / D conversion of the DC voltage V1 at the A / D conversion port 333 is referred to as a DC voltage signal.

  The storage unit 332 of the microcomputer 33 stores in advance which value of the control value S1 the DC voltage signal corresponds to. Hereinafter, data indicating the correspondence between the DC voltage signal and the control value S1 stored in the storage unit 332 is referred to as a dimming table. The processing unit 331 of the microcomputer 33 refers to the dimming table and determines the control value S1 based on the DC voltage signal. The control value S1 is a value for determining the timing at which the step-down control circuit 34 turns on / off the switching element Q2. The processing unit 331 determines the control value S1 to be a larger value as the DC voltage signal is larger. The microcomputer 33 causes the signal transmission unit 334 to output the control value S1 to the step-down control circuit 34.

  The microcomputer 33 immediately outputs the control value S1 determined by the processing unit 331 to the step-down control circuit 34, and outputs a later-described stored value S2 that is the control value S1 stored in the storage unit 332 to the step-down control circuit 34. There is a case to do. Details will be described later.

  The step-down control circuit 34 of the control unit 30 controls on / off of the switching element Q2 based on the control value S1 determined based on the dimming level instruction value X1. That is, the step-down control circuit 34 determines the on timing and the off timing of the switching element Q2 based on the control value S1. Further, the step-down control circuit 34 performs current feedback control for adjusting the ON timing of the switching element Q2 by comparing the current value flowing through the inductor L2 detected by the isolation transformer T2 with a threshold value corresponding to the control value S1. Further, the step-down control circuit 34 detects the voltage across the resistor R2 (the current value flowing through the switching element Q2), and performs voltage feedback control for adjusting the OFF timing of the switching element Q2 by comparing with the threshold value. The step-down control circuit 34 outputs a PWM signal corresponding to the determined / adjusted on timing and off timing to the gate of the switching element Q2. The step-down control circuit 34 controls the step-down operation of the step-down chopper circuit 14 by controlling the ON timing and the OFF timing of the switching element Q2 by the PWM signal.

  More specifically, the step-down control circuit 34 outputs a PWM signal whose duty ratio is determined according to the control value S1 to the gate of the switching element Q2. As a result, the step-down control circuit 34 controls the duty ratio of the switching element Q2, and increases the current flowing through the solid-state light source 40 as the control value S1 increases. That is, as the dimming level instruction value X1 included in the dimming signal input to the conversion circuit 32 is larger, the current flowing through the solid light source 40 is larger. Thereby, the current flowing through the solid light source 40 is adjusted to a predetermined current corresponding to the dimming level indicated by the dimming level instruction value X1, so that the solid light source 40 is indicated by the dimming level instruction value X1. Dimming level.

  Dimming control for the solid-state light source 40 is possible by controlling on / off of the switching element Q2 of the step-up chopper circuit 13 in addition to controlling on / off of the switching element Q2 of the step-down chopper circuit 14 as described above. is there. That is, the step-up control circuit 31 controls the output current of the step-up chopper circuit 13 by increasing / decreasing the duty ratio of the PWM signal output to the switching element Q1 and increasing / decreasing the duty ratio of the switching element Q1. Dimming control can be performed.

  When the dimming level instruction value X1 indicates a dimming level that is larger (brighter) than the threshold, the control device 1 performs DC (direct current) dimming. That is, the control unit 30 controls the switching element Q2 to increase or decrease the amplitude of the current supplied to the solid state light source 40 according to the dimming level instruction value X1. On the other hand, when the dimming level instruction value X1 indicates a dimming level that is smaller (darker) than the threshold or equal to the threshold, the control device 1 performs burst dimming. That is, the control unit 30 controls the switching element Q2 to increase / decrease the ratio per unit time of the period in which the current supplied to the solid light source 40 is intermittently interrupted according to the dimming level instruction value X1.

  Incidentally, the storage unit 332 stores a control threshold value ST3. The control threshold value ST3 indicates the smallest (dark) dimming level in the range where the solid light source 40 is lit as the control value S1 determined based on the dimming level instruction value X1. That is, the control threshold value ST3 is equal to the control value S1 determined in the microcomputer 33 based on the lighting threshold value XT3 (see FIG. 2).

  Next, the operation of the control device 1 dimming the solid light source 40 when the solid light source 40 is turned on will be described.

  Until the detection voltage value detected by the detection circuit 21 reaches a predetermined voltage value, the microcomputer 33 immediately controls the control value S1 determined by the processing unit 331 based on the dimming level instruction value X1 as the control value S1. To the step-down control circuit 34 of the unit 30. Based on such control value S1, the step-down control circuit 34 controls on / off of the switching element Q2. In other words, until the detected voltage value reaches the predetermined voltage value, the step-down control circuit 34 is in real time in response to the dimming signal having the dimming level instruction value X1 being input to the conversion circuit 32. On / off control of the switching element Q2 based on X1 is performed (first control step).

  3A and 3B, at time t20 to t21, the dimming signal having the dimming level instruction value X1 corresponding to the control value S1 less than the control threshold ST3 is input to the conversion circuit 32 of the control unit 3. The microcomputer 33 outputs the control value S1 determined based on the dimming level instruction value X1 to the step-down control circuit 34 in real time. When the control value S1 is less than the control threshold ST3, the step-down control circuit 34 of the control unit 30 controls the application voltage Vo1 to the solid light source 40 to be less than the lighting voltage VL1 by controlling on / off of the switching element Q2. To do. In the present embodiment, when the control value S1 is less than the control threshold value ST3, on / off of the switching element Q2 is controlled such that the applied voltage Vo1 is 0 [V].

  Then, at time t21, the dimming level instruction value X1 of the dimming signal input to the conversion circuit 32 is controlled to be equal to or greater than the control threshold ST3 from the dimming level instruction value X1 corresponding to the control value S1 less than the control threshold ST3. It is assumed that the light control level instruction value X1 corresponding to the value S1 is changed. The microcomputer 33 determines the control value S1 based on such a dimming level instruction value X1, and outputs it to the step-down control circuit 34 in real time. The step-down control circuit 34 of the control unit 30 switches the switching element Q2 so that the current flowing through the capacitor C2 becomes larger according to the magnitude of the control value S1 than when the control value S1 less than the control threshold ST3 is inputted. Controls turning on / off. As a result, the step-down chopper circuit 14 increases the current flowing through the capacitor C2 after the control value S1 reaches the control threshold value ST3 and charges the capacitor C2, so that the voltage Vo1 applied to the solid light source 40 increases. Eventually, at time t22, the detection voltage value detected by the detection circuit 21 reaches a predetermined voltage value.

  The fact that the detected voltage value has reached the predetermined voltage value means that the applied voltage Vo1 (the voltage across the capacitor C2) to the solid light source 40 has reached the lighting voltage VL1, and thus the solid light source 40 is lit.

  In addition, after the control value S1 corresponding to the dimming level instruction value X1 of the dimming signal reaches the control threshold value ST3, the storage unit 332 inputs the dimming signal to the conversion circuit 32 continuously or intermittently. Correspondingly, the control value S1 determined every moment is stored as the storage value S2. The storage unit 332 holds the order in which the control values S1 are stored, for example, by setting the address for storing the control values S1 to a larger value as the storage order is later. That is, the storage unit 332 holds the control value S1 based on the dimming level instruction value X1 and the temporal order in which the dimming signal having the dimming level instruction value X1 is input to the conversion circuit 32, and stores the stored value S2 (Storing step). In FIG. 3A, after time t21, the storage unit 332 stores the control value S1 as the storage value S2.

  Here, after the time t22 when the solid light source 40 is turned on, similarly to the times t20 to t22, the control value determined based on the dimming level instruction value X1 of the dimming signal input to the conversion circuit 32 in real time. Consider a case where dimming control is performed using S1 (broken line portion in FIG. 3A). At this time, in FIG. 3A, the dimming level instruction value X1 of the dimming signal is set so that the control value S1 after time t22 is larger than the control value S1 at time t20 to t22. Therefore, when the solid-state light source 40 is turned on, the step-down control circuit controls ON / OFF of the switching element based on the control value S1 (the broken line portion in FIG. 3A) after time t22, thereby indicating the broken line in FIG. 3C. In addition, a large current suddenly flows through the solid light source 40.

  As described above, when the dimming control is performed using the input dimming signal in real time, the dimming level instruction value X1 of the dimming signal input when the solid light source 40 is turned off is the solid state that is lit. It cannot be used for dimming control with respect to the light source 40. Therefore, when the dimming signal is temporally changed before the solid light source 40 is turned on, the dimming input first to the conversion circuit when the solid light source 40 is turned off when the solid light source 40 is turned on. Dimming control based on a dimming signal different from the signal is performed. Therefore, the dimming control for the solid-state light source 40 may not be appropriate control in accordance with the intention.

  On the other hand, in this embodiment, when the detected voltage value reaches the predetermined voltage value (time t22), the microcomputer 33 is based on the dimming level instruction value X1 of the dimming signal input to the conversion circuit 32 in real time. The control value S1 determined in this way is not output to the step-down control circuit 34. Instead, the microcomputer 33 outputs the storage value S2 stored in the storage unit 332 (indicated by a solid line after time t22 in FIG. 3A) to the step-down control circuit 34 as the control value S1. In particular, the microcomputer 33 outputs the stored value S2 to the step-down control circuit 34 in accordance with the temporal order in which the dimming signal having the dimming level instruction value X1 is input to the conversion circuit 32. Therefore, the step-down control circuit 34 of the control unit 30 performs the switching element Q2 based on the stored value S2 stored in the storage unit 332 according to the time sequence after the detected voltage value reaches the predetermined voltage value (after time t22). Is controlled (second control step).

  That is, after the solid light source 40 is turned on (after time t22), the control value S1 (stored value S2) is determined based on the dimming level instruction value X1 of the dimming signal input after time t21. Based on this, dimming control is performed by the control device 1. In the example of FIG. 3A, the control value S1 gradually increases from a small value after time t21. That is, the storage value S2 (solid line portion in FIG. 3A) output to the step-down control circuit 34 after time t22 gradually increases from a small value. Accordingly, as shown in FIG. 3C, the step-down control circuit 34 controls on / off of the switching element Q2 so that the current flowing through the solid state light source 40 after time t22 gradually increases from a small value. Thereby, as for the solid light source 40, a light quantity increases gradually from the state with a small light quantity.

  As described above, in the dimming control by the control device 1 of the present embodiment, the dimming signal corresponding to the control value S1 greater than or equal to the control threshold ST3 is input to the conversion circuit 32 and then adjusted after the solid light source 40 is turned on. What is necessary is just to receive the input of the light control signal which has the light control level instruction value X1 according to the light control level. When the solid light source 40 is turned off, the control value S1 based on the dimming level instruction value X1 is stored in the storage unit 332 as the storage value S2. Then, after the solid light source 40 is turned on, dimming control based on the stored value S2 is performed. Therefore, the dimming control performed after the solid light source 40 is turned on is more appropriate control based on the dimming signal input since the solid light source 40 is turned off.

  As described above, the control device 1 of the present embodiment can perform dimming control by the dimming signal (dimming level instruction value X1) more appropriately when the solid light source 40 is turned on. It can be effectively used for lighting fixtures and other general lighting fixtures.

  Next, the lighting fixture 4 which concerns on this embodiment is demonstrated with reference to FIG. The luminaire 4 includes a light source unit 5 having a solid light source 40 (see FIG. 1) and a power supply unit 6 having a lighting device 2 (see FIG. 1).

  In the following description, in FIG. 4, front and rear, left and right, and up and down directions are defined. That is, in the direction in which the light source unit 5 and the power supply unit 6 are arranged, the light source unit 5 side is set to the upper side and the power supply unit 6 side is set to the lower side. In addition, a rotation axis direction in which the light source unit 5 rotates with respect to the power supply unit 6 around a knob bolt 62 described later is a left-right direction. Further, a direction orthogonal to both the direction in which the light source unit 5 and the power supply unit 6 are arranged and the direction of the rotation axis of the light source unit 5 is defined as the front-rear direction.

  The luminaire 4 is a so-called horizont light used for illuminating a background wall (horizont) such as a studio or a stage of a television station. However, the use of the lighting device 2 (see FIG. 1) is not limited to the horizont light, and can be used for various lighting fixtures such as a ceiling light, a base light, and a down light.

  The light source unit 5 includes four light source modules 50, a first housing 51, a reflecting plate block 52, and a heat radiating plate block 53. Each light source module 50 is configured by mounting a solid light source 40 (see FIG. 1) on the surface of a rectangular substrate.

  The 1st housing | casing 51 is formed in the rectangular parallelepiped shape with the metal plate. The first casing 51 has a rectangular window hole 510 on the front surface. Inside the first housing 51, four light source modules 50 are accommodated in two vertical rows and two horizontal rows so that the surface faces the window hole 510.

  The reflection plate block 52 includes a plurality of reflection plates 520 and a light shielding plate 521. The plurality of reflection plates 520 and the light shielding plate 521 are arranged in the first housing 51 between the window hole 510 and the surface of each light source module 50, and light distribution of light emitted from each light source module 50 is distributed. Is configured to control.

  The heat sink block 53 includes a plurality of heat sinks 530. The plurality of heat sinks 530 are arranged at regular intervals along the thickness direction. The heat sink block 53 is provided on the rear surface of the first housing 51. In addition, it is preferable that the heat sink block 53 is thermally coupled to the substrates of the four light source modules 50 in the first housing 51.

  The power supply unit 6 includes a lighting device 2 (see FIG. 1), a second housing 60 that houses the lighting device 2, and a pair of arms 61.

  The 2nd housing | casing 60 is formed in the flat rectangular parallelepiped shape with the metal plate. The pair of arms 61 are provided so as to rise upward from the left and right ends of the second housing 60. The pair of arms 61 are formed so as to gradually narrow the width dimension in the front-rear direction toward the tip (upper end). Insertion holes through which the bolts of so-called knob bolts 62 are inserted are provided at the tip portions of the respective arms 61. That is, the pair of arms 61 are configured to rotatably support the light source unit 5 by screwing bolts inserted through the insertion holes in the distal end portion into female screws provided on the left and right side surfaces of the first housing 51. Has been.

  The luminaire 4 is installed on a floor, for example, with the window hole 510 of the light source unit 5 facing the background wall surface and away from the background wall surface. The luminaire 4 can irradiate illumination light substantially uniformly from the lower part close to the floor of the background wall surface to the upper part.

  Next, the illumination system 7 will be described with reference to FIG. The lighting system 7 includes a plurality of lighting fixtures 4 and a dimming console 8 as a controller. The plurality of lighting fixtures 4 are sent and connected to the dimming console 8 via the communication cable 80. The dimming console 8 transmits a dimming signal having the dimming level instruction value X <b> 1 to the plurality of lighting fixtures 4 via the communication cable 80. The dimming level instruction value X1 transmitted from the dimming console 8 is input to the conversion circuit 32 (see FIG. 1) of the control unit 3 (see FIG. 1) of each lighting fixture 4.

  As described above, the control device 1 according to the present embodiment is a control device that controls the power control circuit (step-down chopper circuit 14) to control the dimming level of the solid-state light source 40. The power supply circuit includes a capacitor C2 and a switching element Q2. A solid light source 40 is connected in parallel to the capacitor C2. The switching element Q2 increases or decreases the power supplied to the solid state light source 40 by turning on and off. The control device 1 includes an input unit (conversion circuit 32), an acquisition unit (detection circuit 21), a storage unit 332, and a control unit 30. The conversion circuit 32 receives continuous or intermittent input of the dimming level instruction value X1. The dimming level instruction value X1 indicates the dimming level. The detection circuit 21 acquires a physical quantity (detection voltage value). The physical quantity corresponds to the voltage (applied voltage Vo1) applied to the solid light source 40. The storage unit 332 at least until the physical quantity reaches a predetermined value (predetermined voltage value) after the dimming level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3). The (control value S1) is stored as the storage value S2 while maintaining the temporal order input to the conversion circuit 32. The lighting threshold value XT3 indicates the smallest dimming level in the range where the solid light source 40 is turned on. The predetermined value corresponds to the lighting voltage VL1 of the solid light source 40. The control unit 30 controls on / off of the switching element Q2 based on the dimming level instruction value X1 (control value S1) until the physical quantity reaches a predetermined value. After the physical quantity reaches a predetermined value, the control unit 30 controls on / off of the switching element Q2 based on the stored value S2 according to a temporal order.

  By the way, the dimming level instruction value X1 may be input when the applied voltage Vo1 applied to the solid light source 40 is less than the lighting voltage VL1 and the solid light source 40 is turned off. When dimming control is performed using the dimming level instruction value X1 in real time in response to the input of the dimming level instruction value X1, the dimming level input when the solid-state light source 40 is turned off. The instruction value X1 cannot be used for dimming control.

  On the other hand, in the control device 1 according to the present embodiment, the storage unit 332 stores the dimming level instruction value X1 (control value S1) input to the input unit (conversion circuit 32) as the storage value S2. As for the stored value S2, a physical quantity (detection voltage value) corresponding to the applied voltage Vo1 corresponds to the lighting voltage VL1 after at least the dimming level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3). This is stored until the predetermined value (predetermined voltage value) is reached. That is, the storage unit 332 stores the dimming level instruction value X1 input to the conversion circuit 32 at least during the period when the solid light source 40 is turned off as the storage value S2. When the physical quantity reaches a predetermined value and the solid light source 40 is turned on, the control unit 30 controls the dimming level of the solid light source 40 by controlling on / off of the switching element Q2 based on the stored value S2. .

  Thus, in the control device 1 of the present embodiment, the dimming control when the solid light source 40 in the off state is turned on is performed based on the stored value S2, so that the input is performed when the solid light source 40 is off. The dimming control can be performed more appropriately using the dimming level instruction value X1. That is, as compared with the case where the dimming control when the solid state light source 40 in the off state is turned on is performed using the dimming level instruction value X1 in real time in response to the input of the dimming level instruction value X1. The light control can be performed more appropriately.

  For example, when the dimming level instruction value X1 (control value S1) is to be increased smoothly before the solid light source 40 is turned on, the storage unit 332 stores such dimming level instruction value X1 (control value S1). Is stored as a stored value S2. Therefore, when the solid light source 40 is turned on, the fade-in for smoothly increasing the light amount of the solid light source 40 can be performed based on the stored value S2.

  The lighting device 2 according to the present embodiment includes the control device 1 and a power supply circuit (step-down chopper circuit 14).

  With the above configuration, in the lighting device 2 of the present embodiment, the physical quantity (detected voltage value) is a predetermined value (at least) after the dimming level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3). Until the predetermined voltage value is reached, the storage unit 332 stores the dimming level instruction value X1 (control value S1) as the storage value S2. When the physical quantity reaches a predetermined value, the control unit 30 controls on / off of the switching element Q2 based on the stored value S2. Thereby, the dimming control when the solid light source 40 in the off state is turned on can be more appropriately performed.

  The lighting fixture 4 according to the present embodiment includes the control device 1, a power supply circuit (step-down chopper circuit 14), and a solid light source 40.

  With the above configuration, the lighting fixture 4 of the present embodiment can more appropriately perform dimming control when the solid-state light source 40 in the off state is turned on.

  Further, the lighting control method according to the present embodiment is a lighting control method for controlling the dimming level of the solid state light source 40 by controlling the power supply circuit (step-down chopper circuit 14). The power supply circuit includes a capacitor C2 and a switching element Q2. A solid light source 40 is connected in parallel to the capacitor C2. The switching element Q2 increases or decreases the power supplied to the solid state light source 40 by turning on and off. The lighting control method includes an input step, an acquisition step, a storage step, a first control step, and a second control step. In the input step, continuous or intermittent input of the dimming level instruction value X1 is accepted. The dimming level instruction value X1 indicates the dimming level. In the acquisition step, a physical quantity (detection voltage value) is acquired. The physical quantity corresponds to the voltage (applied voltage Vo1) applied to the solid light source 40. In the storing step, at least until the physical quantity reaches a predetermined value (predetermined voltage value) after the dimming level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3), the dimming level instruction value X1 ( The control value S1) is stored as the stored value S2 while maintaining the temporal order input in the input step. The control threshold value ST3 indicates the smallest dimming level in the range where the solid light source 40 is turned on. The predetermined value corresponds to the lighting voltage VL1 of the solid light source 40. In the first control step, on / off of the switching element Q2 is controlled based on the dimming level instruction value X1 (control value S1) until the physical quantity reaches a predetermined value. In the second control step, after the physical quantity reaches a predetermined value, on / off of the switching element Q2 is controlled based on the stored value S2 according to a temporal order.

  With the above method, in the lighting control method of the present embodiment, it is possible to more appropriately perform dimming control when the solid light source 40 in the off state is turned on.

  By the way, in this embodiment, after control value S1 reaches control threshold value ST3, the memory | storage part 332 memorize | stores control value S1 as memory value S2. On the other hand, the storage unit 332 may stop storing the control value S1 when a predetermined condition is satisfied after starting to store the control value S1. For example, after the microcomputer 33 monitors the temporal transition of the control value S1, the storage unit 332 stops storing the control value S1 after the control value S1 transitions substantially constant over time. May be. When the control unit 30 finishes the dimming control using the storage value S2 stored in the storage unit 332, the control unit 30 uses the dimming level instruction value X1 included in the dimming signal input to the control unit 30 instead of the stored value S2. It may be used in real time to control on / off of the switching element Q2.

  However, the storage unit 332 stores at least the control value S1 from the time when the control value S1 reaches the control threshold value ST3 until the detected voltage value reaches the predetermined voltage value, and the time order in which the dimming signal is input to the conversion circuit 32. Is stored as a stored value S2. That is, the storage unit 332 stores the control value S1 at least until the voltage Vo1 applied to the solid light source 40 reaches the lighting voltage VL1 and the solid light source 40 is turned on. Furthermore, the stored value S2 stored at least between the time t21 and the time t22 is output to the step-down control circuit 34 in accordance with the stored time sequence after the solid light source 40 is turned on (after the time t22). It is used for dimming control for the light source 40.

  In the present embodiment, the storage unit 332 stores the control value S1 after the control value S1 determined according to the dimming level instruction value X1 reaches the control threshold ST3, but the storage unit 332 stores the control value S1. The dimming level instruction value X1 itself may be stored as a stored value instead of S1. Then, after the detected voltage value reaches the predetermined voltage value, the control unit 30 switches the switching element based on a value (control value S1) based on the dimming level instruction value X1 (stored value) stored in the storage unit 332. What is necessary is just to control ON / OFF of Q2.

  Alternatively, the storage unit 332 may store a value generated based on the dimming level instruction value X1, such as the DC voltage V1 corresponding to the dimming level instruction value X1, as a stored value.

  In addition, the condition for the storage unit 332 to start storing the control value S1 or the dimming level instruction value X1 is that the control value S1 does not reach the control threshold value ST3 but the dimming level instruction value X1 is the lighting threshold value XT3 (FIG. 2). That is, the processing unit 331 may compare the dimming level instruction value X1 itself with the lighting threshold value XT3, or use the value (for example, the control value S1) generated based on the dimming level instruction value X1 as the lighting threshold value XT3. You may compare with control threshold value ST3 corresponding to.

  Even in each of these modified examples, the control device 1, the lighting device 2, the lighting fixture 4, and the lighting control method can more appropriately perform dimming control when the solid light source 40 in the off state is turned on. .

(Embodiment 2)
Next, a control device, a lighting device, and a lighting fixture according to the second embodiment will be described with reference to FIGS. In addition, about the structure similar to the control apparatus 1, the lighting device 2, and the lighting fixture 4 of Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 6A, the control device 1 according to the present embodiment controls the control value S1 after the control value S1 reaches the control threshold value ST3 (time t31) until the detected voltage value reaches a predetermined voltage value (time t32). The difference from Embodiment 1 is that the value of S1 is changed.

  The storage unit 332 of the present embodiment has a control value (corresponding to a predetermined dimming level instruction value X1) in addition to the correspondence (dimming table) between the DC voltage signal and the control value S1, the control threshold value ST3, and the predetermined voltage value. Hereinafter, the setting value S31) is stored in advance. From the time when the control value S1 reaches the control threshold value ST3 until the detected voltage value reaches the predetermined voltage value, the microcomputer 33 determines the control value S1 determined based on the dimming level instruction value X1 of the input dimming signal. Instead, the set value S31 is output to the step-down control circuit 34. The set value S31 functions as the control value S1. That is, the set value S31 is a value that indicates to the step-down control circuit 34 the timing at which the switching element Q2 is turned on / off. Therefore, after the control value S1 reaches the control threshold value ST3 (time t31) and until the detected voltage value reaches a predetermined voltage value (time t32), the step-down control circuit 34 of the control unit 30 performs switching based on the set value S31. The on / off of the element Q2 is controlled.

  The set value S31 is a constant value. The set value S31 is a value larger than the control threshold value ST3. The set value S31 is determined based on the dimming level instruction value X1 until the detected voltage value reaches a predetermined voltage value after the control value S1 reaches the control threshold value ST3 (broken line in FIG. 6A). Part) is preferable. That is, it is preferable that the set value S31 indicates a light control level that is greater (brighter) than the control value S1. As a result, the current flowing through the capacitor C2 increases and the capacitor C2 is made faster than when the control unit 30 controls on / off of the switching element Q2 based on the control value S1 based on the dimming level instruction value X1. Charged. That is, the applied voltage Vo1 to the solid light source 40 (shown by a solid line in FIG. 6B) is a case where the control unit 30 controls on / off of the switching element Q2 based on the control value S1 based on the dimming level instruction value X1 ( It increases faster than indicated by the dashed line in FIG. 6B. Thereby, the time required until the applied voltage Vo1 reaches the lighting voltage VL1 and the solid light source 40 is turned on (time t32) is shortened.

  Further, the set value S31 controls the on / off of the switching element Q2 based on the set value S31, so that the detected voltage value reaches the predetermined voltage value after the dimming level instruction value X1 reaches the control threshold value ST3. Is set to a value within a predetermined time. In other words, the set value S31 is such that the time required from when the control value S1 reaches the control threshold value ST3 until the solid light source 40 that is turned off is turned on (the time from time t31 to time t32) is within a predetermined time. Is set to a value. The predetermined time is, for example, 0.1 to 0.5 seconds.

  Similarly to the first embodiment, after the control value S1 reaches the control threshold value ST3 (after time t31), the storage unit 332 stores the control value S1 as the storage value S2. At this time, the control value S1 stored in the storage unit 332 is not the set value S31 but the control value S1 determined based on the dimming level instruction value X1 included in the dimming signal input to the conversion circuit 32 (FIG. 6A). The broken line portion). After time t32 when the detected voltage value reaches a predetermined voltage value, the step-down control circuit 34 of the control unit 30 performs switching based on the stored value S2 stored in the storage unit 332 (shown by a solid line after time t32 in FIG. 6A). The on / off of the element Q2 is controlled.

  As described above, in the control device 1 according to the present embodiment, the physical quantity (detection voltage value) is a predetermined value (predetermined voltage) after the dimming level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3). Until reaching (value), the control unit 30 controls on / off of the switching element Q2 based on the set value S31. The set value S31 indicates a dimming level greater than the dimming level instruction value X1 (control value S1). The set value S31 controls the on / off of the switching element Q2 based on the set value S31, so that the time from when the dimming level instruction value X1 reaches the lighting threshold value XT3 until the physical quantity reaches the predetermined value is a predetermined time. The value is within.

  With the above configuration, in the control device 1 according to the present embodiment, the physical quantity (detected voltage value) is a predetermined value (after the light control level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3)). Until the predetermined voltage value is reached, the control unit 30 controls on / off of the switching element Q2 based on the set value S31. The set value S31 indicates a dimming level that is greater (brighter) than the dimming level instruction value X1 (control value S1). As a result, the power supplied to the capacitor C2 under the control of the switching element Q2 increases, and the capacitor C2 is charged faster. That is, the time required for the applied voltage Vo1 to the solid state light source 40 in the extinguished state to reach the lighting voltage VL1 and the solid state light source 40 is turned on is shortened. Therefore, the time required for the input dimming level instruction value X1 to be reflected in the dimming level of the solid light source 40 is shortened. That is, the responsiveness of the light control level of the solid light source 40 to the input of the light control level instruction value X1 to the input unit (conversion circuit 32) is improved.

  In the control device 1 according to the present embodiment, the set value S31 is a constant value.

  Since the set value S31 is a constant value, the control device 1 stabilizes the length of time required until the applied voltage Vo1 of the solid light source 40 that has been turned off reaches the lighting voltage VL1 and the solid light source 40 is turned on. be able to.

  In the present embodiment, the set value S31 is a constant value. However, the set value S31 is a value that changes according to, for example, the control value S1 determined based on the dimming level instruction value X1 and the applied voltage Vo1. There may be.

  In the present embodiment, the control unit 30 uses the set value S31 as the control value S1 until the detected voltage value reaches a predetermined voltage value after the control value S1 reaches the control threshold value ST3. On the other hand, the condition that the control unit 30 starts using the set value S31 as the control value S1 is that the control value S1 does not reach the control threshold value ST3, but the dimming level instruction value X1 is the lighting threshold value XT3 (FIG. 2).

  Further, instead of using the set value S31 instead of the control value S1 based on the dimming level instruction value X1, a predetermined set value may be used instead of the dimming level instruction value X1 itself. The predetermined set value is greater (brighter) than the dimming level instruction value X1 from when the dimming level instruction value X1 reaches the lighting threshold value XT3 (see FIG. 2) until the detected voltage value reaches the predetermined voltage value. It is preferable to indicate the light level. The predetermined set value is controlled to turn on / off the switching element Q2 based on the predetermined set value, so that the detected voltage value becomes the predetermined voltage value after the dimming level instruction value X1 reaches the lighting threshold value XT3. It is also preferable to set the value until the time to reach is within a predetermined time. The control unit 30 determines a control value S1 corresponding to a predetermined set value, and controls on / off of the switching element Q2 based on the determined control value S1.

(Embodiment 3)
Next, a control device, a lighting device, and a lighting fixture according to Embodiment 3 will be described with reference to FIG. In addition, about the structure similar to the control apparatus 1, the lighting device 2, and the lighting fixture 4 of Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 7, the luminaire 4a of the present embodiment includes a plurality (two in FIG. 7) of lighting devices 2a and a plurality (two in FIG. 7) of solid light sources 40. The two lighting devices 2a share one control device 1a. Each lighting device 2a includes an input filter 11, a rectifier circuit 12, a step-up chopper circuit 13, and a step-down chopper circuit 14 (power supply circuit) in addition to the control device 1a. That is, the lighting fixture 4a includes a plurality (two) of step-down chopper circuits 14. The two solid-state light sources 40 correspond one-to-one to the two step-down chopper circuits 14, and each solid-state light source 40 is connected to the corresponding step-down chopper circuit 14. The two solid light sources 40 emit light of different colors. Specifically, one of the two solid light sources 40 emits light bulb color light, and the other emits white light.

  The control device 1a includes a central block 36 and a plurality (two in FIG. 7) of operation blocks 37. The operation blocks 37 are provided in the same number as the step-down chopper circuits 14 and correspond to the step-down chopper circuits 14 on a one-to-one basis. The function of the control unit 3 (see FIG. 1) in the first embodiment is shared by the central block 36 and the two operation blocks 37. This will be described in more detail below.

  The central block 36 includes a conversion circuit 32, a processing unit 361, a storage unit 362, an A / D conversion port 363, a signal transmission unit 364, and a timer 365 (acquisition unit). The processing unit 361 is configured by a CPU (Central Processing Unit), for example. The processing unit 361, the storage unit 362, the A / D conversion port 363, the signal transmission unit 364, and the timer 365 constitute a microcomputer 360 (hereinafter referred to as a microcomputer 360).

  The operation block 37 includes a step-up control circuit 31, a microcomputer 370 (hereinafter referred to as a microcomputer 370), and a step-down control circuit 34 (execution unit). The step-down control circuit 34 in each operation block 37 has a one-to-one correspondence with the step-down chopper circuit 14.

  The processing unit 361 and the signal transmission unit 364 of the central block 36, and the microcomputer 370 and the step-down control circuit 34 of a plurality (two) of the operation blocks 37 constitute a control unit 30a. That is, the control unit 30 a includes a processing unit 361, a signal transmission unit 364, a plurality (two) of microcomputers 370, and a plurality (two) step-down control circuits 34.

  Unlike the control device 1 of Embodiments 1 and 2 (see FIG. 1), the control device 1a is a detection circuit 21 (see FIG. 1) corresponding to an acquisition unit that detects the applied voltage Vo1 applied to the solid-state light source 40. ) Is not provided. In the present embodiment, the timer 365 of the microcomputer 360 corresponds to the acquisition unit. The timer 365 acquires, as an acquisition time length (physical quantity), an elapsed time after the control value S1 based on the dimming level instruction value X1 reaches the control threshold value ST3 (acquisition step). That is, the timer 365 measures the time during which power is supplied to the capacitor C2 through the switching element Q2. Thereby, since the applied voltage Vo1 to each solid-state light source 40 can be estimated, the acquisition time length is a value corresponding to the applied voltage Vo1. That is, the acquisition time length is a value corresponding to both the applied voltage Vo1 to one of the two solid light sources 40 and the applied voltage Vo1 to the other solid light source 40.

  The conversion circuit 32 of the central block 36 accepts a continuous or intermittent input of a dimming signal having a dimming level instruction value X1. The conversion circuit 32 converts the dimming signal into a DC voltage V1 corresponding to the dimming level instruction value X1. The conversion circuit 32 inputs the DC voltage V <b> 1 to the A / D conversion port 363 of the microcomputer 360. The A / D conversion port 363 A / D converts the DC voltage V1 into a DC voltage signal. The processing unit 361 of the microcomputer 360 refers to the dimming table stored in the storage unit 362 and determines the control value S1 according to the DC voltage signal. The control value S1 corresponds to a control signal for controlling on / off of the switching element Q2.

  The signal transmission unit 364 of the microcomputer 360 has a plurality of output terminals (not shown). The signal transmission unit 364 transmits the control value S1 to the microcomputer 370 of each operation block 37. In each operation block 37, the microcomputer 370 transmits the control value S <b> 1 to the step-down control circuit 34. The step-down control circuit 34 in each operation block 37 controls on / off of the switching element Q2 of the corresponding step-down chopper circuit 14 based on the control value S1, so that the solid-state light source 40 is controlled by the dimming level instruction value X1. It is adjusted to the indicated dimming level.

  The signal transmission unit 364 immediately outputs the control value S1 (control signal) determined by the processing unit 361 to the microcomputer 370, and the storage value S2 that is the control value S1 (control signal) stored in the storage unit 362. In some cases, the data is output to the microcomputer 370. Details will be described later.

  The storage unit 362 of the microcomputer 360 stores a control threshold value ST3, and the control value S1 determined by the processing unit 361 of the microcomputer 360 is compared with the control threshold value ST3 in the processing unit 361. The storage unit 362 stores a predetermined time length (predetermined value). The predetermined time length is set to be approximately equal to the length of time required for the voltage Vo1 applied to the solid light source 40 to reach the lighting voltage VL1 of the solid light source 40 after the control value S1 reaches the control threshold ST3. That is, the predetermined time length is set to a value corresponding to the lighting voltage VL1 of the solid light source 40. For example, the predetermined time length is set in advance based on an actual measurement value of the time required for the applied voltage Vo1 to reach the lighting voltage VL1. The predetermined time length may be set based on, for example, an integral value of the control value S1 based on the dimming level instruction value X1 of the input dimming signal.

  The storage unit 362 of the microcomputer 360 stores the control value S1 as the storage value S2 after the control value S1 reaches the control threshold value ST3. Note that the storage unit 362 may store the control value S1 as the storage value S2 at least until the acquisition time length reaches the predetermined time length after the control value S1 reaches the control threshold value ST3.

  Next, the operation of the control device 1a to dimm the solid light source 40 when the solid light source 40 is turned on will be described.

  As described above, when the control value S1 reaches the control threshold value ST3, the timer 365 of the microcomputer 360 measures the length of time that has elapsed thereafter as the acquisition time length.

  The processing unit 361 of the microcomputer 360 determines the control value S1 based on the dimming level instruction value X1 included in the dimming signal input to the conversion circuit 32. Until the acquisition time length reaches a predetermined time length, the signal transmission unit 364 sends the control value S1 determined by the processing unit 361 to the microcomputer 370 of each operation block 37 in real time when the dimming signal is input. To the step-down control circuit 34. Therefore, the step-down control circuit 34 of each operation block 37 controls on / off of the switching element Q2 based on the control value S1.

  When the acquisition time length reaches a predetermined time length, the signal transmission unit 364 transmits the storage value S2 stored in the storage unit 362 to the step-down control circuit 34 via the microcomputer 370 of each operation block 37. Therefore, the step-down control circuit 34 of each operation block 37 controls on / off of the switching element Q2 based on the stored value S2.

  As described above, the central block 36 has a function from when the dimming signal having the dimming level instruction value X1 is input to when the control value S1 or the stored value S2 is output to the microcomputer 370 of each operation block 37. Yes. In the central block 36, when the control value S1 reaches the control threshold value ST3, the timer 365 of the microcomputer 360 measures the length of time that has passed thereafter as the acquisition time length, and the storage unit 362 of the microcomputer 360 The control value S1 is stored as the storage value S2.

  Since the lighting fixture 4a includes a plurality of (two) lighting devices 2a, one central block 36 in one control device 1a performs these functions, and thus a plurality of central blocks 36 are provided. In addition, the circuit configuration of the lighting fixture 4a can be simplified.

  As described above, in the control device 1a according to the present embodiment, the acquisition unit (timer 365) calculates the elapsed time after the dimming level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3). , Acquired as physical quantity (acquisition time length).

  As described above, the acquisition unit (timer 365) uses the physical amount corresponding to the applied voltage Vo1 as the elapsed time after the dimming level instruction value X1 (control value S1) reaches the lighting threshold value XT3 (control threshold value ST3). Acquired as acquisition time length). Since the acquisition time length corresponds to the time during which power is supplied to the capacitor C2, the voltage Vo1 applied to the solid light source 40 can be estimated from the acquisition time length. Thus, in the control device 1a, the acquisition time length corresponding to the applied voltage Vo1 is acquired without modifying the existing solid-state light source 40 and the power supply circuit (step-down chopper circuit 14). More appropriate dimming control using the stored value S2 can be performed.

  Moreover, the lighting fixture 4a which concerns on this embodiment is provided with multiple power supply circuits (step-down chopper circuit 14). The luminaire 4a further includes a plurality of solid light sources 40. The plurality of solid state light sources 40 correspond one-to-one to the plurality of power supply circuits. The acquisition unit (timer 365) acquires a physical quantity (acquisition time length). The physical quantity corresponds to at least one of voltages (applied voltage Vo1) individually applied to the plurality of solid state light sources 40. The control unit 30a includes a signal transmission unit 364 and a plurality of execution units (step-down control circuit 34). The processing unit 361 transmits a control signal (control value S1, storage value S2). The control signals (control value S1, stored value S2) are signals for controlling on / off of the switching element Q2. The plurality of step-down control circuits 34 correspond one-to-one to the plurality of power supply circuits. The plurality of step-down control circuits 34 control on / off of the switching element Q2 of the corresponding power supply circuit among the plurality of power supply circuits based on the control signals (control value S1, stored value S2) input from the signal transmission unit 364. To do. The signal transmission unit 364 transmits a control signal (control value S1) based on the dimming level instruction value X1 to the plurality of step-down control circuits 34 until the physical quantity reaches a predetermined value (predetermined time length). After the physical quantity reaches a predetermined value, the processing unit 361 transmits a control signal (stored value S2) based on the stored value S2 to the plurality of step-down control circuits 34 according to a temporal order.

  With the above configuration, in the lighting fixture 4a of the present embodiment, one acquisition unit (timer 365) of one control device 1a has a physical quantity (acquisition time length) corresponding to the applied voltage Vo1 applied to the solid light source 40. get. Therefore, the circuit configuration of the lighting fixture 4a can be simplified and the manufacturing cost of the lighting fixture 4a can be reduced without providing a plurality of timers 365 for a plurality of power supply circuits (step-down chopper circuits 14). Further, the signal transmission unit 364 sends a control signal (control value S1, storage value S2) to a plurality of execution units (step-down control circuit 34) in accordance with whether or not the physical quantity has reached a predetermined value (predetermined time length). Send to. Each of the plurality of step-down control circuits 34 controls ON / OFF of the switching element Q2 of the corresponding power supply circuit. Therefore, it is possible to synchronize the dimming timings for the plurality of solid-state light sources 40 connected to the plurality of power supply circuits in a one-to-one correspondence. Further, by inputting the dimming level instruction value X1 to one input unit (conversion circuit 32), dimming control for the solid state light sources 40 connected to each of the plurality of power supply circuits can be performed collectively.

  When the stored value S2 is stored in the storage unit 362 in a form that can be used as it is in the step-down control circuit 34 as in this embodiment, the signal transmission unit 364 transmits the stored value S2 as a control signal as it is. do it. On the other hand, when the stored value is stored as, for example, the dimming level instruction value X1 and needs to be converted to the control value S1 for use in the step-down control circuit 34, the processing unit 361 of the control unit 30a stores the stored value. The control value S1 may be determined based on the dimming level instruction value X1 being performed. Furthermore, the signal transmission unit 364 may transmit such a control value S1 as a control signal to the step-down control circuit 34.

  Moreover, although this embodiment demonstrated the case where the two lighting devices 2a shared the control apparatus 1a, one lighting device 2a may have one control apparatus 1a, and three or more The lighting device 2a may share one control device 1a.

  In the present embodiment, the colors of light emitted by the two solid light sources 40 may be the same color. Alternatively, for example, one type of each of the red, green, blue, and white solid light sources 40 may be connected to the step-down chopper circuits 14 of the four lighting devices 2a.

  Also in the control device 1a of the present embodiment, similarly to the control device 1 of the second embodiment, the set value S31 may be used as the control value S1. That is, after the control value S1 reaches the control threshold ST3 and until the acquisition time length reaches a predetermined time length, the step-down control circuit 34 controls ON / OFF of the switching element Q2 based on the set value S31. Good.

  In the first and second embodiments, the applied voltage Vo1 to the solid-state light source 40 is detected by the detection circuit 21 (acquisition unit) having the resistors R3 and R4. In the first and second embodiments, the detection circuit 21 is provided. Instead, the microcomputer 33 may have a timer function. That is, following the timer 365 of the microcomputer 360 of the third embodiment, the timer of the microcomputer 33 may function as an acquisition unit in the first and second embodiments. Furthermore, the timer of the microcomputer 33 may acquire an acquisition time length (physical quantity) that is an elapsed time after the control value S1 reaches the control threshold value ST3. The control unit 30 controls on / off of the switching element Q2 based on the control value S1 until the acquisition time length reaches a predetermined time length. After the acquisition time length reaches the predetermined time length, the control unit 30 controls the switching element Q2. Thus, the on / off state of the switching element Q2 may be controlled.

  In addition, in one lighting device 2 (2a) of each embodiment, a plurality of step-down chopper circuits 14 may be provided. That is, a plurality of step-down chopper circuits 14 may be connected in parallel to the output terminal of the step-up chopper circuit 13. Further, a plurality of control units 30 (30a) may be provided in one lighting device 2 (2a). Thereby, a plurality of solid light sources 40 of different colors are connected to the plurality of step-down chopper circuits 14, and dimming control according to the lighting voltage VL <b> 1 of each solid light source 40 is performed by the plurality of control units 30 (30 a). be able to. For example, it is possible to configure the lighting fixture 4 (4a) in which the color of light is variable by connecting one type of each of the red, green, blue and white solid light sources 40 to the four step-down chopper circuits 14 respectively.

  In each embodiment, the step-down chopper circuit 14 is used as the power supply circuit. However, the power supply circuit is not limited to the step-down chopper circuit 14, and a known switching circuit such as a flyback circuit may be used.

  In each embodiment, the dimming signal input to the conversion circuit 32 may be an analog signal such as DC 0 V to 10 V, or may be a digital signal such as a PWM signal.

  In each embodiment, the predetermined value (predetermined voltage value or predetermined time length) is a physical quantity (detected voltage value or acquisition time) when the applied voltage Vo1 reaches the lighting voltage VL1 that is a voltage at which the solid light source 40 starts to light. However, the predetermined value is not limited to this. For example, the predetermined value is a value that is increased or decreased with respect to the physical quantity when the applied voltage Vo1 reaches the lighting voltage VL1 in consideration of the detection error of the physical quantity, the assumed value of the dimming level instruction value X1, and the like. May be. When the solid light source 40 starts to light, it is preferable to start the dimming control based on the stored value S2 stored in the storage unit 332 (362). Therefore, it is preferable to set the predetermined value so that the physical quantity reaches the predetermined value immediately before the applied voltage Vo1 reaches the lighting voltage VL1.

  Even in each of the above modifications, the control device 1 (1a), the lighting device 2 (2a), the luminaire 4 (4a), and the lighting control method are dimming when the solid light source 40 in the off state is turned on. Control can be performed more appropriately.

  The embodiment described above is an example of the present invention. For this reason, this invention is not limited to these embodiment, A various deformation | transformation is possible in the range which does not deviate from the meaning of this invention.

1, 1a Control device 2, 2a Lighting device 4, 4a Lighting fixture 14 Step-down chopper circuit (power supply circuit)
21 Detection circuit (acquisition part)
30, 30a Control unit 32 Conversion circuit (input unit)
34 Step-down control circuit (execution unit)
40 Solid light sources 332 and 362 Storage unit 364 Signal transmission unit 365 Timer (acquisition unit)
C2 Capacitor Q2 Switching element S1 Control value (control signal)
S2 Memory value (control signal)
S31 Set value Vo1 Applied voltage VL1 Lighting voltage X1 Dimming level instruction value XT3 Lighting threshold

Claims (8)

A dimming level of the solid state light source is controlled by controlling a power supply circuit having a capacitor to which the solid state light source is connected in parallel and a switching element that increases or decreases the power supplied to the solid state light source by turning on and off. A control device,
An input unit that accepts continuous or intermittent input of a dimming level indicating value indicating the dimming level;
An acquisition unit for acquiring a physical quantity corresponding to a voltage applied to the solid-state light source;
At least until the physical quantity reaches a predetermined value corresponding to the lighting voltage of the solid state light source after the lighting level indication value reaches the lighting threshold value indicating the smallest dimming level in the range where the solid state light source is turned on. A storage unit for storing a dimming level instruction value as a stored value while maintaining a temporal order input to the input unit;
The on / off control of the switching element is controlled based on the dimming level instruction value until the physical quantity reaches the predetermined value. After the physical quantity reaches the predetermined value, according to the time sequence, the stored value A control unit that controls on / off of the switching element based on the control device.   The control device according to claim 1, wherein the acquisition unit acquires, as the physical quantity, an elapsed time after the dimming level instruction value reaches the lighting threshold. From the time when the light control level instruction value reaches the lighting threshold, until the physical quantity reaches the predetermined value, the control unit is based on the setting value indicating the light control level greater than the light control level instruction value. Controls on / off of switching elements,
The set value is a time from when the dimming level instruction value reaches the lighting threshold to when the physical quantity reaches the predetermined value by controlling on / off of the switching element based on the set value. The control device according to claim 1 or 2, wherein the value is within a predetermined time.   4. The control apparatus according to claim 3, wherein the set value is a constant value. The control device according to any one of claims 1 to 4,
A lighting device comprising: the power supply circuit. The control device according to any one of claims 1 to 4,
The power supply circuit;
A lighting apparatus comprising: the solid-state light source. A plurality of the power supply circuits are provided,
Furthermore, a plurality of the solid-state light sources are provided so as to correspond one-to-one to the plurality of power supply circuits,
The acquisition unit acquires the physical quantity corresponding to at least one of the voltages individually applied to the plurality of solid state light sources,
The controller is
A signal transmission unit for transmitting a control signal for controlling on / off of the switching element;
A plurality of power supply circuits that correspond one-to-one, and that control on / off of the switching elements of the corresponding power supply circuit among the plurality of power supply circuits based on the control signal input from the signal transmission unit. An execution unit,
The signal transmitter is
Until the physical quantity reaches the predetermined value, the control signal based on the dimming level instruction value is transmitted to the plurality of execution units,
The lighting apparatus according to claim 6, wherein after the physical quantity reaches the predetermined value, the control signal based on the stored value is transmitted to the plurality of execution units according to the temporal order. A dimming level of the solid state light source is controlled by controlling a power supply circuit having a capacitor to which the solid state light source is connected in parallel and a switching element that increases or decreases the power supplied to the solid state light source by turning on and off. A lighting control method,
An input step for accepting continuous or intermittent input of a dimming level indicating value indicating the dimming level;
An acquisition step of acquiring a physical quantity corresponding to a voltage applied to the solid-state light source;
At least until the physical quantity reaches a predetermined value corresponding to the lighting voltage of the solid state light source after the lighting level indication value reaches the lighting threshold value indicating the smallest dimming level in the range where the solid state light source is turned on. A storage step of storing the dimming level instruction value as a stored value while maintaining the temporal order input in the input step;
A first control step of controlling on / off of the switching element based on the dimming level instruction value until the physical quantity reaches the predetermined value;
A lighting control method comprising: a second control step of controlling on / off of the switching element based on the stored value in accordance with the time order after the physical quantity reaches the predetermined value.

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