JP2020077504A - Lighting system, illumination control system and luminaire - Google Patents

Abstract

To provide a lighting system, an illumination control system and a luminaire, capable of maintaining an operation of a control circuit at least until a light source is turned off, when the optical output is faded out by the phase control of an AC voltage.SOLUTION: In a lighting system 11, during a control circuit 1d performs fade out control to fade out the optical output of a light source 12, as dimming control, the control circuit 1d maintains a first control voltage V11 and a second control voltage V12 at a value that allows the control circuit 1d to operate at least until the light source 12 is turned off.SELECTED DRAWING: Figure 1

Description

  The present invention relates generally to lighting systems, lighting control systems, and lighting fixtures.

  BACKGROUND ART Conventionally, there is an illumination device capable of dimming a light emitting element.

  For example, in Patent Document 1, a dimmer table outputs a DMX signal to a lighting device by executing a predetermined effect program. The lighting device converts the input DMX signal into a PWM signal having a duty ratio corresponding to the gradation shown by the DMX signal. At this time, the lighting device generates the PWM signal in accordance with the correspondence relationship indicated by the dimming curve indicating the correspondence relationship between the dimming ratio and the duty ratio. Then, the lighting device performs the dimming control of the light emitting element so as to emit the light having the brightness corresponding to the dimming ratio corresponding to the duty ratio indicated by the PWM signal. The dimming curve has linearity and becomes a straight line in the range from 100% to 2.2%. Further, the dimming curve has a non-linearity in the dimming ratio range of 2.2% to 0% and becomes a curve.

  Further, the LED lighting device of Patent Document 2 receives the voltage of a phase-controlled AC power source, rectifies the phase-controlled voltage, and supplies a load current to the LED light source using the rectified output as a power source. Furthermore, the LED lighting device dims the LED light source based on the phase or voltage of the voltage of the phase-controlled AC power supply. In the LED lighting device, the smaller the conduction angle of the phase-controlled voltage, the darker the brightness of the LED light source.

JP-A-2015-144080 Japanese Patent Laid-Open No. 2018-56100

  In the above-mentioned patent document 2, the conduction angle of the voltage of the phase-controlled AC power supply is reduced, so that the LED light source can be gradually darkened and faded out. However, there is a problem that the smaller the conduction angle is, the lower the effective value of the voltage is, and the operation of the LED lighting device (lighting system) is stopped before the light source is turned off.

  Therefore, an object of the present invention is to provide a lighting system, a lighting control system, and a lighting system capable of maintaining the operation of the control circuit at least until the light source is turned off when the light output is faded out by the phase control of the AC voltage. To provide equipment.

  A lighting system according to one aspect of the present invention includes a DC power supply circuit, a converter, a phase reading circuit, a control circuit, and a control power supply. The DC power supply circuit receives a phase control voltage, which is an AC voltage whose conduction angle is variably set, and outputs the DC voltage. The converter receives the DC voltage and supplies lighting power to the light source. The phase reading circuit detects the conduction angle. The control circuit controls at least the converter according to the detection value of the conduction angle, and performs dimming control that lowers the dimming ratio of the light source as the detection value of the conduction angle decreases. The control power supply generates a control voltage for operating the control circuit. The control power supply maintains the control voltage at a value at which the control circuit is operable at least until the light source is extinguished, while a fade-out control for fading out the light output of the light source is performed as the dimming control.

  A lighting control system according to one aspect of the present invention includes a series circuit of the above-described lighting system connected to an AC power source and a dimmer. The dimmer outputs a phase control voltage, which is an AC voltage having a conduction angle variably set, to the lighting system.

  A lighting fixture according to one aspect of the present invention includes the lighting system described above, a light source to which the lighting power is supplied from the lighting system, and a housing that supports at least the light source.

  As described above, the present invention has an effect that when the light output is faded out by the phase control of the AC voltage, the operation of the control circuit can be maintained at least until the light source is turned off.

FIG. 1 is a block diagram showing a lighting control system including a lighting system according to an embodiment. FIG. 2 is a waveform diagram showing an input waveform of the above lighting system. FIG. 3 is a schematic circuit diagram showing a PFC circuit of the above lighting system. FIG. 4 is a schematic circuit diagram showing a first control power supply of the above lighting system. FIG. 5 is a waveform diagram for explaining the fade-out control of the above lighting system. FIG. 6 is a waveform diagram for explaining the fade-out control of the comparative example. FIG. 7 is another waveform diagram for explaining the fade-out control of the lighting system according to the embodiment. FIG. 8: is a perspective view which shows the lighting fixture provided with the lighting system same as the above.

  The following embodiments relate generally to lighting systems, lighting control systems, and luminaires. More specifically, the present invention relates to a lighting system, a lighting control system, and a lighting fixture that dimming a light source by phase control that changes a conduction angle of an AC voltage. The embodiment described below is merely an example of the embodiment of the present invention. The present invention is not limited to the following embodiments, and various modifications can be made according to the design and the like as long as the effects of the present invention can be exhibited.

  The lighting system, the lighting control system, and the lighting fixture of the embodiment are mainly used in an event venue, a store, an office, and the like. In particular, the lighting system, the lighting control system, and the lighting equipment of the embodiment are preferably used in a wedding reception hall. Moreover, the lighting system, the lighting control system, and the lighting fixture of the embodiment may be used in a dwelling unit, an apartment house, or the like.

  Embodiments will be described below with reference to the drawings.

  As shown in FIG. 1, the lighting control system A1 of the embodiment includes a lighting device 1 and a dimmer 2. A series circuit of the lighting device 1 and the dimmer 2 is connected between both ends of the AC power supply 9. The AC power supply 9 is a commercial power supply with a nominal voltage of 100 V (or 200 V) and a frequency of 50 Hz or 60 Hz.

  The dimmer 2 controls the phase of the AC voltage Va supplied from the AC power supply 9 to the lighting device 1. That is, in the lighting device 1, the AC voltage Va whose phase is controlled by the dimmer 2 is input as the phase control voltage Vb. The dimmer 2 adjusts the conduction angle, which is a conduction period for each half-wave of the phase control voltage Vb, and the lighting device 1 performs light control according to the conduction angle. In this case, the conduction angle corresponds to instruction information indicating an instruction value of the dimming ratio (dimming level) of the light source 12, which will be described later. The dimmer 2 is, for example, a dimming console including a rotary type or a sliding type operating unit operated by a user, or a dimmer that outputs a phase control voltage Vb obtained by converting a DMX signal output from the dimming console. This is an optical unit, and the conduction angle is adjusted by the user operating the operation unit.

  The lighting device 1 is a dimmable lighting fixture, and includes a lighting system 11 and a light source 12, as shown in FIG. 1. The lighting system 11 of the present embodiment includes a lighting device. The lighting system 11 and the light source 12 may be housed in a common housing and integrally configured, or the lighting system 11 and the light source 12 may be separately configured.

  The lighting system 11 includes a DC power supply circuit 1a, a converter 1b, a phase reading circuit 1c, a control circuit 1d, a rectifying circuit 1e, a constant voltage circuit 1f, a constant voltage circuit 1g, and a control power supply 1h. The DC power supply circuit 1a includes a rectifier circuit 111, a PFC (Power Factor Correction) circuit 112, and a capacitor 113. The control power supply 1h includes a first control power supply 101 and a second control power supply 102.

  The rectifier circuit 111 is a full-wave rectifier circuit having a diode bridge or the like, and receives the phase control voltage Vb. The rectifier circuit 111 full-wave rectifies the phase control voltage Vb and outputs a pulsating current voltage Vc. FIG. 2 shows the waveform of the pulsating voltage Vc. The pulsating current voltage Vc in FIG. 2 is phase-controlled like the phase control voltage Vb, and the conduction angle θ is defined as the period during which each half-wave is in the energized state. In FIG. 2, the alternate long and short dash line indicates the waveform of the full-wave rectified voltage Ve obtained by full-wave rectifying the AC voltage Va. Further, a filter circuit may be provided in the preceding stage of the rectifier circuit 111. The filter circuit has, for example, an inductor and a capacitor for removing noise, and a surge absorber, and attenuates unnecessary frequency components (for example, high frequency noise).

  The PFC circuit 112 is a switching power supply circuit (power factor correction circuit) having a power factor correction function. The PFC circuit 112 receives the pulsating voltage Vc, converts the pulsating voltage Vc into a DC voltage, and outputs the DC voltage. A capacitor 113 is connected between the output terminals of the PFC circuit 112. The capacitor 113 smoothes the DC voltage output from the PFC circuit 112, and a DC voltage Vd is generated across the capacitor 113. The PFC circuit 112 is a step-up chopper circuit or a step-up / step-down chopper circuit having a semiconductor switching element, and the pulsating current voltage Vc is converted to a DC voltage Vd by turning on / off the semiconductor switching element. For example, the PFC circuit 112 is composed of a flyback converter (PFC flyback converter) having a power factor correction function. Further, the PFC circuit 112 may be a normal flyback converter, or another switching power supply circuit such as a SEPIC circuit.

  FIG. 3 shows a circuit example of the PFC circuit 112. In FIG. 3, the PFC circuit 112 is a PFC flyback converter including a transformer 112a, a switching element 112b, a diode 112c, a drive circuit 112d, and diodes 112e and 112f. The pulsating current voltage Vc is applied to the series circuit of the primary winding N1 of the transformer 112a and the switching element 112b. The switching element 112b is, for example, an enhancement-type N-channel MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor). The primary winding N1 is arranged on the high side and the switching element 112b is arranged on the low side with respect to the pulsating current voltage Vc. A diode 112c for regeneration is connected between both ends of the primary winding N1. The drive circuit 112d switches ON / OFF of the switching element 112b by switching the gate voltage of the switching element 112b between H level and L level. The anode of the diode 112e is connected to one end of the secondary winding N2 of the transformer 112a. The cathode of the diode 112e is connected to the positive electrode of the capacitor 113. The other end of the secondary winding N2 of the transformer 112a is connected to the negative electrode of the capacitor 113.

  Then, the drive circuit 112d turns on and off the switching element 112b, so that the current flowing through the primary winding N1 of the transformer 112a is conducted and cut off. As a result, an induced voltage is generated in the secondary winding N2 of the transformer 112a, the capacitor 113 is charged through the diode 112e, and a DC voltage Vd is generated across the capacitor 113. The drive circuit 112d turns the switching element 112b on and off based on an instruction from the control circuit 1d to match the DC voltage Vd with the voltage target value. The switching control of the switching element 112b by the drive circuit 112d may be any of the discontinuous mode, the continuous mode, and the critical mode. The drive circuit 112d preferably controls the switching of the switching element 112b by detecting the zero cross of the switching current flowing through the switching element 112b and the peak value of the inductor current.

  As described above, the DC power supply circuit 1a receives the phase control voltage Vb whose phase is controlled by the dimmer 2 and outputs the DC voltage Vd. The voltage value of DC voltage Vd is preferably a value sufficiently larger than the sum of the output voltage of converter 1b and a first control voltage V11 described later.

  The converter 1b is a DC / DC converter, receives the DC voltage Vd, and supplies a DC load current (output current) Io to the light source 12. The converter 1b controls the output based on the instruction from the control circuit 1d to match the value of the load current Io with the current target value. The converter 1b changes the current target value according to an instruction from the control circuit 1d. That is, the converter 1b dimms the light source 12 so that the dimming ratio is instructed by the control circuit 1d. The converter 1b preferably has, for example, a step-down converter, a step-up converter, a step-up / step-down converter, or a constant current regulator.

  The light source 12 includes a plurality of LEDs (Light Emitting Diodes) as a plurality of solid state light emitting elements. Then, the light source 12 emits illumination light (light output) by being supplied with the load current Io from the converter 1b. The plurality of LEDs included in the light source 12 are connected in series, or connected in series and in parallel.

  The phase reading circuit 1c corresponds to an information acquisition unit that receives instruction information representing an instruction value of the dimming ratio of the light source 12 from the outside. In the present embodiment, the conduction angle θ of the phase control voltage Vb corresponds to the instruction information. Then, the phase reading circuit 1c detects the conduction angle θ and outputs the conduction angle detection signal Sa.

  The phase reading circuit 1c performs full-wave rectification of the phase control voltage Vb, compares the rectified voltage of the phase control voltage Vb with a determination reference value, and generates a PWM (Power Width Modulation) signal (rectangular wave signal) based on the comparison result. ) Is output. The PWM signal is a pulse signal synchronized with the phase control voltage Vb, and the on-duty of the PWM signal corresponds to the conduction angle θ. Specifically, when the conduction angle θ increases, the on-duty of the PWM signal increases, and when the conduction angle θ decreases, the on-duty of the PWM signal decreases.

  The phase reading circuit 1c smoothes the PWM signal, generates a conduction angle detection signal Sa, and outputs the conduction angle detection signal Sa to the control circuit 1d. The on-duty of the PWM signal corresponds to the instruction value of the dimming ratio. In other words, the voltage value of the conduction angle detection signal Sa corresponds to the detected value of the conduction angle θ. Therefore, the instruction value of the dimming ratio is reflected in the voltage value of the conduction angle detection signal Sa obtained by smoothing the PWM signal. That is, the higher the dimming ratio instruction value, the larger the voltage value of the conduction angle detection signal Sa, and the lower the dimming ratio instruction value, the smaller the voltage value of the conduction angle detection signal Sa.

  The phase control voltage Vb may fluctuate instantaneously due to the effects of noise, ripple, surge voltage, and the like. Therefore, it is preferable that the phase reading circuit 1c set the time constant of the smoothing circuit that smoothes the PWM signal to a value that can absorb the instantaneous fluctuation of the phase control voltage Vb. As a result, it is possible to suppress problems such as flicker of the light source 12 and erroneous light emission due to instantaneous fluctuations in the phase control voltage Vb.

  The control circuit 1d includes a computer. When this computer executes the program, some or all of the functions of the control circuit 1d are realized. The computer includes a processor that operates according to a program as a main hardware configuration. The processor may be of any type as long as it can realize the function by executing the program. The processor is composed of one or a plurality of electronic circuits including a semiconductor integrated circuit (IC) or an LSI (large scale integration). Although referred to as an IC or an LSI here, it may be called a system LSI, a VLSI (very large scale integration), or a ULSI (ultra large scale integration) depending on the degree of integration. A field programmable gate array (FPGA) that is programmed after the manufacture of the LSI, or a reconfigurable logic device that can reconfigure the junction relation inside the LSI or set up the circuit section inside the LSI can be used for the same purpose. You can The plurality of electronic circuits may be integrated on one chip or may be provided on the plurality of chips. The plurality of chips may be integrated in one device or may be provided in the plurality of devices. The program is recorded in a non-transitory recording medium such as a computer-readable ROM, an optical disk, or a hard disk drive. The program may be stored in the recording medium in advance, or may be supplied to the recording medium via a wide area communication network such as the Internet.

  The control circuit 1d may include a control IC. The control IC realizes a part or all of the functions of the control circuit 1d by an electric circuit formed on the IC chip without executing a program.

  The control circuit 1d acquires the detected value of the DC voltage Vd from the PFC circuit 112. The control circuit 1d outputs a voltage control signal to the PFC circuit 112 so that the DC voltage Vd matches the voltage target value. In the PFC circuit 112, the drive circuit 112d drives the switching element 112b on and off based on the voltage control signal from the control circuit 1d to match the value of the DC voltage Vd with the voltage target value.

  Further, the control circuit 1d acquires the detected value of the load current Io from the converter 1b. Then, the control circuit 1d generates a current control signal based on the conduction angle detection signal Sa and the detection value of the load current Io, and outputs the current control signal to the converter 1b.

  The control circuit 1d reads the conduction angle θ (instruction value of the dimming ratio) from the voltage value of the conduction angle detection signal Sa, and determines the current target value according to the read value of the conduction angle θ. Then, the control circuit 1d controls the operation of the converter 1b so that the deviation (difference) between the detected value of the load current Io and the current target value becomes small (close to zero).

  The control circuit 1d performs at least one of amplitude dimming and burst dimming in order to control the load current Io and dimming the light source 12. Amplitude dimming controls the dimming ratio of the light source 12 by continuously supplying the load current Io to the light source 12 and controlling the magnitude of the load current Io. In this case, the control parameter of converter 1b is the magnitude of load current Io. In burst dimming, the load current Io is intermittently supplied to the light source 12, and the ON period of supplying the load current Io to the light source 12 is PWM-controlled to control the dimming ratio of the light source 12. In this case, the control parameter of the converter 1b is the ON period in which the load current Io is supplied to the light source 12. When the switching element of the converter 1b is switching-controlled, the control circuit 1d generally preferably switches at a high frequency of several tens kHz to several hundreds kHz. Further, when performing the burst dimming, the control circuit 1d preferably intermittently outputs the load current Io at a low frequency lower than several tens kHz to several hundreds kHz. The control circuit 1d may use a method other than amplitude dimming and burst dimming as a dimming method for the light source 12, and the dimming method for the light source 12 is not limited to a particular dimming method.

  That is, the control circuit 1d adjusts the control parameter so that the deviation between the detected value of the load current Io and the current target value becomes small, and performs feedback control for controlling the converter 1b. As a result, the load current Io is controlled so that the dimming ratio of the light source 12 becomes the indicated value. The larger the conduction angle θ is, the higher the indication value of the dimming ratio is. Therefore, the larger the conduction angle θ is, the larger the target current value is. Further, the smaller the conduction angle θ, the lower the indication value of the dimming ratio. Therefore, the smaller the conduction angle θ, the smaller the target current value. The dimming ratio takes a value within the range of 0 to 100%. If the dimming ratio is 0%, the light source 12 is turned off. If the dimming ratio is 100%, all the light sources 12 are turned on. In the present embodiment, the control circuit 1d can control the dimming ratio within the range of 1% to 100% when the light source 12 is turned on. In this case, the lower limit value (dimming lower limit value) of the dimming ratio that can be adjusted by the lighting system 11 when the light source 12 is turned on is 1%. The dimming lower limit value is not limited to a specific value.

  Next, the control voltage of the lighting system 11 will be described. The control power supply 1h receives the voltages V1, V2, and V3, and outputs the first control voltage V11 (control voltage) and the second control voltage V12 (control voltage).

  Specifically, the rectifier circuit 1e full-wave rectifies the phase control voltage Vb and outputs a full-wave rectified voltage of the phase control voltage Vb. The constant voltage circuit 1f receives the output of the rectifier circuit 1e (full-wave rectified voltage of the phase control voltage Vb) and outputs a DC voltage V1 to the first control power supply 101. The constant voltage circuit 1f is composed of a linear regulator such as a series regulator or a shunt regulator, and controls the voltage V1 to a constant voltage value. The linear regulator has a resistor, a transistor, a capacitor, a Zener diode, and the like.

  The PFC circuit 112 outputs the pulsed voltage V2 while performing the power conversion process of converting the pulsating current voltage Vc into the DC voltage Vd. The PFC circuit 112 of the present embodiment turns on / off the switching element 112b to turn on / off the current flowing through the primary winding N1 of the transformer 112a during a steady period after startup (see FIG. 3). Then, the induced voltage generated in the control winding N3 (see FIG. 3) of the transformer 112a is output to the first control power supply 101 as the voltage V2 via the diode 112f.

  The constant voltage circuit 1g receives the DC voltage Vd, which is the voltage across the capacitor 113, and outputs a DC voltage V3 to the first control power supply 101. The constant voltage circuit 1g is configured by a linear regulator such as a series regulator or a shunt regulator, and controls the voltage V3 to a constant voltage value. The linear regulator has a resistor, a transistor, a capacitor, a Zener diode, and the like.

  The first control power supply 101 receives the above-described three-system voltages V1, V2, and V3, and uses any of the three-system voltages V1, V2, and V3 to generate the first DC control voltage V11. In the present embodiment, the magnitude relationship among the voltages V1, V2, and V3 of the three systems is V2> V1 and V2> V3. The first control power supply 101 performs constant voltage control of the first control voltage V11 to a constant voltage value. The first control voltage V11 serves as the operating power supply for the PFC circuit 112 and the converter 1b. For example, the first control voltage V11 becomes a drive voltage for each switching element (FET, bipolar transistor, etc.) of the PFC circuit 112 and the converter 1b. The first control voltage V11 is preferably a minimum voltage value capable of driving the switching elements of the PFC circuit 112 and the converter 1b in consideration of heat generation of components.

  FIG. 4 shows a circuit example of the first control power supply 101. In FIG. 4, the first control power supply 101 includes diodes 121 and 122, a capacitor 123, a resistor 124, a Zener diode 125, a transistor 126, and a capacitor 127.

  The anode of the diode 121 is connected to the output of the constant voltage circuit 1f, and the cathode of the diode 121 is connected to the positive electrode of the capacitor 123. The anode of the diode 122 is connected to the output of the constant voltage circuit 1g, and the cathode of the diode 122 is connected to the positive electrode of the capacitor 123. That is, the capacitor 123 is applied with the voltage V1 via the diode 121 and is applied with the voltage V3 via the diode 122. Further, the voltage V2 is applied to the capacitor 123. In this embodiment, a DC voltage of about 15 to 25 V is generated across the capacitor 123.

  A series circuit of the resistor 124 and the Zener diode 125 is connected in parallel with the capacitor 123. One end of the resistor 124 is connected to the positive electrode of the capacitor 123, and the other end of the resistor 124 is connected to the cathode of the Zener diode 125. The anode of the Zener diode 125 is connected to the negative electrode of the capacitor 123. The transistor 126 is an npn-type bipolar transistor, and the cathode of the Zener diode 125 is connected to the base of the transistor 126. The collector of the transistor 126 is connected to the positive electrode of the capacitor 123, and the emitter of the transistor 126 is connected to the positive electrode of the capacitor 127. The negative electrode of the capacitor 127 is connected to the negative electrode of the capacitor 123.

  In the above-described first control power supply 101, a voltage substantially equal to the Zener voltage of the Zener diode 125 is generated across the capacitor 127. Then, the first control power supply 101 outputs the voltage across the capacitor 127 as the first control voltage V11. In the present embodiment, as the first control voltage V11 (voltage across the capacitor 127), a DC voltage of about 12V is generated.

  The second control power supply 102 receives the first control voltage V11 and outputs the second control voltage V12. The second control voltage V12 serves as an operating power supply for the control circuit 1d. The second control power supply 102 is composed of, for example, a linear regulator such as a series regulator or a shunt regulator, and controls the second control voltage V12 at a constant voltage value. The second control voltage V12 may be any voltage value with which the control circuit 1d can operate. In particular, the second control voltage V12 is preferably a minimum voltage value that allows the control circuit 1d to operate in consideration of heat generation of components. In the present embodiment, the second control voltage V12 is a DC voltage of about 5V.

  Then, in the starting period immediately after the power supply from the AC power source 9 to the lighting system 11 is started via the dimmer 2, the PFC circuit 112 is not operating and the voltage V1 among the voltages V1, V2, and V3 is V1. Only generated. The first control power supply 101 generates the first control voltage V11 from the voltage V1, and the second control power supply 102 generates the second control voltage V12. When the first control voltage V11 is generated, the PFC circuit 112 and the converter 1b can start each operation. When the second control voltage V12 is generated, the control circuit 1d starts operating. The control circuit 1d controls the PFC circuit 112, and the PFC circuit 112 starts outputting the DC voltage Vd. When the DC voltage Vd is output and the DC voltage Vd reaches the voltage target value, the control circuit 1d controls the converter 1b, and the converter 1b starts outputting the load current Io.

  Furthermore, when the PFC circuit 112 starts operating, an induced voltage is generated in the control winding N3 of the transformer 112a (see FIG. 3) by turning on / off the switching element 112b, and a voltage V2 is generated. The control winding N3 is designed to generate an induced voltage capable of generating the first control voltage V11 and the second control voltage V12. Then, when the second control voltage V12 is output and the starting period shifts to the steady period, the constant voltage circuit 1f stops the output of the voltage V1, and the first control power supply 101 changes the voltage V2 from the first control voltage V11. To generate. That is, the first control power supply 101 generates the first control voltage V11 from the voltage V1 in the starting period, and generates the first control voltage V11 from the voltage V2 in the steady period.

  The first control power supply 101 may generate the first control voltage V11 from the voltage V1 during both the starting period and the steady period. Further, the first control power supply 101 may generate the first control voltage V11 by using both the voltages V1 and V2 in the steady period.

  In the steady period, the control circuit 1d matches the value of the DC voltage Vd with the voltage target value. Further, in the steady period, the control circuit 1d controls the load current Io so that the dimming ratio of the light source 12 becomes the value indicated by the dimming ratio by the dimmer 2.

  Next, the operation of the lighting system 11 instructed by the dimmer 2 to fade out (dimming off operation) will be described.

  The user operates the operation unit of the dimmer 2 to instruct a fade-out in which the dimming ratio is gradually reduced and the light source 12 is turned off. Hereinafter, the operation of the dimmer 2 for instructing fade-out will be referred to as a fade-out operation. When the fade-out operation is performed on the dimmer 2, the conduction angle θ gradually decreases and the voltage value of the conduction angle detection signal Sa gradually decreases. Then, the control circuit 1d performs fade-out control for controlling the converter 1b so that the load current Io gradually decreases to 0 (zero). As a result, the dimming ratio of the light source 12 gradually decreases, the light source 12 is turned off, and the light output of the light source 12 fades out.

  When the fade-out operation is performed on the dimmer 2, the conduction angle θ gradually decreases and the effective value of the pulsating current voltage Vc gradually decreases. Then, when the load current Io drops below Io (1%) (when the dimming ratio of the light source 12 drops below the dimming lower limit value), the effective value of the pulsating current voltage Vc becomes excessively low, The PFC circuit 112 stops operating and the output voltage of the PFC circuit 112 becomes zero.

  That is, when the fade-out operation is performed on the dimmer 2 and the load current Io drops below Io (1%), the effective value of the phase control voltage Vb reaches a value at which the PFC circuit 112 becomes inoperable. descend. As a result, in a comparative example different from the present embodiment (a lighting system that generates a control voltage by using only the voltages V1 and V2 without using the voltage V3), the light output of the light source 12 that fades out is the lower limit of dimming. There was a case where the light source 12 suddenly became 0 (zero) near the value, and it was felt by the human eye that the light source 12 suddenly turned off. Such a sudden change in light output makes a person feel uncomfortable. However, in the field of stage lighting such as a stage or an event, it is necessary to make the human eyes feel that the light output has decreased smoothly during the fade-out operation until the light source is turned off without causing any discomfort. For example, in a 40 W class illumination system, even if the dimming ratio becomes 1% or less during a fade-out operation, it is required to gradually reduce the light output until the light source is turned off. However, in the lighting system using the phase control voltage as an input, when the dimming ratio becomes 1% or less during the fade-out operation, it is difficult to gradually reduce the light output until the light source is turned off.

  On the other hand, the fade-out control of this embodiment will be described with reference to FIG. FIG. 5 shows waveforms of the conduction angle detection signal Sa and the load current Io. In this case, the conduction angle detection signal Sa corresponds to the instruction value of the dimming ratio, and the load current Io corresponds to the light output of the light source 12. When the fade-out operation is started at time t0, the voltage value of the conduction angle detection signal Sa decreases and the load current Io decreases. When fading out the light output of the light source 12, the control circuit 1d sets the period in which the value of the load current Io is Io (1%) or more as the follow-up fade period Ta (second period). Further, when the control circuit 1d fades out the light output of the light source 12, the control circuit 1d sets a fixed fade period Tb (first time) until the light source 12 is turned off after the value of the load current Io becomes less than Io (1%). 1 period). Io (1%) is the value of the load current Io corresponding to the dimming lower limit value.

  During the follow-up fade period Ta, the PFC circuit 112 is operating and the DC voltage Vd maintains the voltage target value. Then, the control circuit 1d performs the fade-out control while constantly updating the control parameter based on the voltage value of the conduction angle detection signal Sa in the following fade period Ta. At this time, the control circuit 1d smoothly reduces the load current Io over the follow-up fade period Ta so that the human eye can see that the light output is smoothly reduced. The control circuit 1d reduces the load current Io over the follow-up fade period Ta by using, for example, a 2.3th power curve, a 2.7th power curve, or a 3.7th power curve used in the production field. ..

  When the voltage value of the conduction angle detection signal Sa further decreases, the PFC circuit 112 stops operating during the fixed fade period Tb. However, immediately after the PFC circuit 112 stops operating, electric charge is accumulated in the capacitor 113, and the DC voltage Vd immediately after the PFC circuit 112 stops operating maintains the voltage target value. Therefore, the control circuit 1d uses the charging power of the capacitor 113 in the fixed fade period Tb to smoothly reduce the light output of the light source 12 until the light source 12 is turned off, thereby completing the fade-out control. That is, the control circuit 1d controls the converter 1b by using the DC voltage Vd (charging power of the capacitor 113) during the fixed fade period Tb. The converter 1b supplies the lighting power to the light source 12 by using the DC voltage Vd (the charging power of the capacitor 113) in the fixed fade period Tb.

  Specifically, in the fixed fade period Tb, the control circuit 1d fixes the control parameter of the converter 1b, electrically connects the positive electrode of the capacitor 113 to the positive electrode of the light source 12, and sets the negative electrode of the capacitor 113 to the negative electrode of the light source 12. Electrically connect to. That is, the DC voltage Vd, which is the voltage across the capacitor 113, is continuously applied to the light source 12, and the charging power of the capacitor 113 is discharged to the light source 12. As a result, in the fixed fade period Tb, the load current Io smoothly decreases to 0 (zero) so that human eyes can see that the light output smoothly decreases. Therefore, during the fade-out operation, the lighting system 11 can cause the human eyes to feel that the light output is smoothly reduced until the light source 12 is turned off.

  Further, the control circuit 1d may control the converter 1b while updating the control parameter of the converter 1b during the fixed fade period Tb. That is, the control circuit 1d discharges the charging power of the capacitor 113 while controlling the load current Io during the fixed fade period Tb. In the fixed fade period Tb, the control circuit 1d changes the control parameter according to the predetermined control pattern so that the dimming curve is determined in advance. Further, the control circuit 1d may perform feedback control of the control parameter during the fixed fade period Tb. As a result, in the fixed fade period Tb, the load current Io smoothly decreases to 0 (zero) so that human eyes can see that the light output smoothly decreases. Therefore, during the fade-out operation, the lighting system 11 can cause the human eyes to feel that the light output is smoothly reduced until the light source 12 is turned off.

  In the above description, the user is slowly operating the operation unit of the dimmer 2, and the conduction angle θ of the phase control voltage Vb is slowly decreasing. However, when the user operates the operation unit of the dimmer 2 rapidly and the conduction angle θ of the phase control voltage Vb sharply decreases, the decrease amount of the load current Io (light output) follows the decrease amount of the conduction angle θ. There are times when you don't. Therefore, the control circuit 1d makes the update amount of the control parameter when the conduction angle θ sharply decreases larger than the update amount of the control parameter when the conduction angle θ slowly decreases. That is, the control circuit 1d controls the update amount of the control parameter when the decrease of the light output does not follow the decrease of the conduction angle θ when performing the fade-out control, and the decrease of the light output follows the decrease of the conduction angle θ. If it is, the control parameter update amount is made larger. The control parameter update amount is the difference between the two control parameters continuously set by the control circuit 1d.

  In the PFC circuit 112 of FIG. 3, when the user quickly operates the operation unit of the dimmer 2, the effective value of the phase control voltage Vb sharply decreases. As a result, the control circuit 1d rapidly increases the on-duty of the switching element 112b to match the DC voltage Vd with the voltage target value. Therefore, the control circuit 1d can determine that if the on-duty of the switching element 112b suddenly increases, the conduction angle θ rapidly decreases, and the decrease in light output cannot follow the decrease in conduction angle θ. Therefore, the control circuit 1d increases the update amount of the control parameter when the decrease amount of the on-duty of the switching element 112b per unit time exceeds the threshold value. When the update amount of the control parameter becomes large, the converter 1b can sharply decrease the load current Io, and the decrease in the light output follows the decrease in the conduction angle θ.

  For example, when performing burst dimming, the control circuit 1d controls the magnitude of the ON period in which the load current Io is intermittently supplied to the light source 12 as a control parameter. In this case, the control circuit 1d outputs the update amount of the ON period (the reduction amount of the ON period per unit time) when the decrease of the light output does not follow the decrease of the conduction angle θ in the following fade period Ta. It is made larger than the update amount of the ON period when the decrease of the output follows the decrease of the conduction angle θ.

  Further, when performing the amplitude dimming, the control circuit 1d controls the magnitude of the load current Io as a control parameter. In this case, the control circuit 1d determines the update amount of the load current Io (the decrease amount of the load current Io per unit time) when the decrease of the light output does not follow the decrease of the conduction angle θ in the follow-up fade period Ta. , The amount of update of the load current Io when the decrease of the light output follows the decrease of the conduction angle θ.

  Further, the control circuit 1d may switch between burst dimming and amplitude dimming. For example, the control circuit 1d performs amplitude dimming when the dimming ratio of the light source 12 is a predetermined value or more. Further, the control circuit 1d performs burst dimming if the dimming ratio of the light source 12 is less than a predetermined value. Therefore, the control circuit 1d updates the load current Io when the decrease in the light output does not follow the decrease in the conduction angle θ (the decrease amount per unit time of the ON period, or the load current during the follow-up fade period Ta). The decrease amount of Io per unit time) is made larger than the update amount of the load current Io when the decrease of the optical output follows the decrease of the conduction angle θ.

  Therefore, even when the user operates the operation unit of the dimmer 2 quickly and the conduction angle θ sharply decreases, the light output decreases following the decrease in the conduction angle θ. As a result, the fade-out control that can follow the fast fade-out operation of the dimmer 2 is realized.

  Next, a process of generating the first control voltage V11 and the second control voltage V12 in the fade-out control will be described.

  In the follow-up fade period Ta of the fade-out control, the DC voltage Vd maintains the voltage target value, and the voltages V1 and V2 maintain the values in the steady period. Therefore, the control power supply 1h can generate the first control voltage V11 and the second control voltage V12 from the voltage V1 or the voltage V2 in the follow-up fade period Ta. For example, the control power supply 1h generates the first control voltage V11 and the second control voltage V12 from the voltage V2 in the first half of the follow-up fade period Ta, and from the voltage V1 to the first control voltage V11 in the second half of the follow-up fade period Ta. , And the second control voltage V12.

  However, when the dimming ratio of the light source 12 falls below the dimming lower limit value (the load current Io falls below Io (1%)), and the tracking fade period Ta shifts to the fixed fade period Tb, the phase control is performed. As the effective value of the voltage Vb decreases, the voltages V1 and V2 also decrease. Therefore, the first control power supply 101 cannot generate the first control voltage V11 and the second control voltage V12 from the voltages V1 and V2.

  That is, when a fade-out operation is performed on the dimmer 2 and the dimming ratio of the light source 12 falls below the dimming lower limit value, the voltage V1 in the fixed fade period Tb renders the first control power supply 101 inoperable. To a value that When the dimming ratio of the light source 12 falls below the dimming lower limit value, the PFC circuit 112 stops operating and the voltage V2 of the fixed fade period Tb reaches a value at which the first control power supply 101 becomes inoperable. descend.

  Therefore, in the lighting system 11 of the present embodiment, when the voltages V1 and V2 are lower than the voltage V3 when the light output of the light source 12 is faded out, the first control power supply 101 uses the voltage V3 to generate the first control voltage. V11 is generated.

  Furthermore, even if the dimming ratio of the light source 12 is lowered to less than the dimming lower limit value by the fade-out operation and the PFC circuit 112 stops operating, electric charge is accumulated in the capacitor 113. The DC voltage Vd immediately after the PFC circuit 112 stops operating maintains the voltage target value. Therefore, during the fade-out control, the first control power supply 101 can generate the first control voltage V11 using the voltage V3.

  As a result, when the lighting system 11 fades out the light output of the light source 12, even if the voltages V1 and V2 decrease and the PFC circuit 112 stops operating, the first control voltage V11 and the second control voltage V12 are also generated. Can be secured for a while.

  In this case, the capacitance C1 of the capacitor 113 is set to a value that satisfies the following Expression 1. The target voltage value of the DC voltage Vd is Vd1. Furthermore, the time length of the fixed fade period Tb is Tb1. Further, the average value of the load current Io in the fixed fade period Tb and the discharge current of the capacitor 113 necessary for each operation of the constant voltage circuit 1g, the first control power supply 101, the second control power supply 102, the control circuit 1d, etc. is I1. And

  C1 ≧ I1 · Tb1 / Vd1 (Equation 1).

  The control circuit 1d can control the converter 1b over the fixed fade period Tb by setting the capacitance of the capacitor 113 to be the capacitance C1 that satisfies the above-described formula 1. That is, the control power supply 1h can maintain the first control voltage V11 at a value capable of driving the PFC circuit 112 and the converter 1b at least until the light source 12 is turned off during the fade-out control. Further, the control power supply 1h can maintain the second control voltage V12 at a value at which the control circuit 1d can operate at least until the light source 12 is turned off during the fade-out control.

  FIG. 6 shows a waveform of each part when the first control power supply 101 generates the first control voltage V11 and the second control voltage V12 using only the voltages V1 and V2 without using the voltage V3. FIG. 6 shows waveforms of the DC voltage Vd, the first control voltage V11, and the load current Io.

  When the fade-out operation is started at time t10, the effective value of the phase control voltage Vb decreases, and the DC voltage Vd and the first control voltage V11 also decrease. From time t10 to time t11, the first control power supply 101 generates the first control voltage V11 using the voltage V1 or the voltage V2, and the first control voltage V11 operates the converter 1b and the control circuit 1d, respectively. It is a value that can be made. Therefore, from time t10 to time t11, the control circuit 1d can control the converter 1b to gradually decrease the load current Io. However, at time t11, the second control voltage V12 also decreases due to the excessive decrease of the first control voltage V11. As a result, the control circuit 1d stops operating and the converter 1b stops operating. When the operation of the converter 1b is stopped, the load current Io sharply drops to 0 (zero). As a result, human eyes feel that the light source 12 suddenly goes out.

  On the other hand, FIG. 7 shows a waveform of each part when the first control power supply 101 generates the first control voltage V11 using the voltages V1, V2, and V3. FIG. 7 shows waveforms of the DC voltage Vd, the first control voltage V11, and the load current Io.

  When the fade-out operation is started at time t10, the effective value of the phase control voltage Vb decreases, and the DC voltage Vd and the first control voltage V11 also decrease. The first control power supply 101 uses the voltage V1 or the voltage V2 to generate the first control voltage V11 from time t10 to time t11. Further, the first control power supply 101 generates the first control voltage V11 using the voltage V3 after the time t11. Therefore, after time t11, the first control power supply 101 can generate the first control voltage V11, the second control power supply 102 can generate the second control voltage V12, and the control circuit 1d can control the converter 1b. After time t11, the control circuit 1d can control the converter 1b to smoothly reduce the light output of the light source 12 until the light source 12 is turned off, and complete the fade-out control (time t12).

  That is, when the fade-out control is performed, the control power supply 1h can generate the first control voltage V11 and the second control voltage V12 from the DC voltage Vd in the predetermined period including the turn-off timing (time t12) of the light source 12. If “C1 = I1 · Tb1 / Vd1” in the above equation 1, when the fade-out control is performed, the control power supply 1h changes from the DC voltage Vd to the first control voltage V11 and the first control voltage V11 over the fixed fade period Tb. Two control voltages V12 can be generated. Further, in the above expression 1, if “C1> I1 · Tb1 / Vd1”, the control power supply 1h is controlled from the DC voltage Vd over the fixed fade period Tb + α (see FIG. 7) when the fade-out control is performed. The first control voltage V11 and the second control voltage V12 can be generated.

  As described above, when performing the fade-out control, the control circuit 1d controls the converter 1b before the DC voltage Vd drops to the minimum voltage value VL1 (see FIG. 7) that allows the light source 12 to be turned on. Light source 12 is turned off. Therefore, the lighting system 11 can smoothly change the light output when the light output is faded out by the phase control of the AC voltage Va.

  Further, the lighting system 11 maintains the respective values of the first control voltage V11 and the second control voltage V12 at least until the light source 12 is extinguished when fading out the optical output of the light source 12 by phase control of the AC voltage Va. it can. Therefore, during the fade-out control, the lighting system 11 can maintain the operation of the control circuit 1d at least until the light source 12 is turned off.

(Modification)
The phase reading circuit 1c may output the PWM signal as the conduction angle detection signal Sa without smoothing the PWM signal. In this case, it is preferable that the control circuit 1d perform a moving average process when reading the conduction angle detection signal Sa.

  Further, the phase reading circuit 1c may have two smoothing circuits having different time constants. In this case, the smoothing circuit having a large time constant can output the first conduction angle detection signal having low sensitivity to the change in the conduction angle θ to the control circuit 1d. Further, the smoothing circuit having a small time constant can output the second conduction angle detection signal having high sensitivity to the change in the conduction angle θ to the control circuit 1d. Then, the control circuit 1d can accurately control the converter 1b by using the first conduction angle detection signal and the second conduction angle detection signal, regardless of the magnitude of the conduction angle θ.

  Each of the plurality of solid state light emitting elements included in the light source 12 is not limited to an LED, and may be another solid state light emitting element such as an organic EL (Organic Electro Luminescence, OEL) or an inorganic EL. Further, the number of solid-state light emitting elements is not limited to plural, and may be one. The electrical connection relationship between the plurality of solid state light emitting devices may be either serial connection or parallel connection, or may be a connection relationship in which series connection and parallel connection are combined.

  When the light source 12 has an incandescent lamp or the like, the control circuit 1d controls the dimming ratio of the light source 12 by controlling the magnitude of the output voltage of the converter 1b. In this case, the control parameter of converter 1b is the magnitude of the output voltage of converter 1b.

(lighting equipment)
FIG. 8: shows the lighting fixture B1 attached to the electric power supply duct 4 installed in the ceiling panel. The lighting fixture B1 includes a fixing portion 31 fixed to the power supply duct 4 and a housing 32 holding the light source 12. The housing 32 has a columnar shape and emits the light of the light source 12 from one surface in the axial direction. The lighting system 11 is housed in the fixed portion 31 or the housing 32. Further, the lighting system 11 may be accommodated in the fixed portion 31 and the housing 32 in a distributed manner. The phase control voltage Vb is input to the lighting system 11 of the lighting fixture B1 via a conductor (not shown) in the power supply duct 4.

  Further, the housing 32 is rotatably connected to the fixed portion 31. Specifically, the lighting device B1 includes a first connecting portion 33 and a second connecting portion 34. The first connecting portion 33 is connected to the fixed portion 31 so as to be rotatable around the vertical direction. The second connecting portion 34 connects the housing 32 to the first connecting portion 33 so as to be rotatable around the horizontal direction. That is, by rotating the first connecting portion 33 with respect to the fixed portion 31, it is possible to change the horizontal direction of the housing 32. Further, by rotating the housing 32 with the second connecting portion 34, the vertical direction of the housing 32 can be changed.

  As described above, the lighting system (11) of the first aspect according to the embodiment includes the DC power supply circuit (1a), the converter (1b), the phase reading circuit (1c), the control circuit (1d), And a control power source (1h). The DC power supply circuit (1a) receives a phase control voltage (Vb) which is an AC voltage (Va) whose conduction angle (θ) is variably set, and outputs a DC voltage (Vd). The converter (1b) receives the DC voltage (Vd) and supplies lighting power to the light source (12). The phase reading circuit (1c) detects the conduction angle (θ). The control circuit (1d) controls at least the converter (1b) according to the detected value of the conduction angle (θ), and adjusts the dimming ratio of the light source (12) to be lower as the detected value of the conduction angle (θ) is smaller. Performs light control. The control power supply (1h) generates control voltages (V11, V12) for operating the control circuit (1d). Then, the control circuit (1d) controls the control voltage (V11, V12) at least until the light source (12) is turned off while the fade-out control for fading out the light output of the light source (12) is performed as the dimming control. The circuit (1d) is maintained at an operable value.

  The above lighting system (11) maintains the operation of the control circuit (1d) at least until the light source (12) is extinguished when fading out the optical output of the light source (12) by phase control of the alternating voltage (Va). can do.

  Moreover, in the lighting system (11) of the second aspect according to the embodiment, in the first aspect, the DC power supply circuit (1a) includes a capacitor (113) and supplies a DC voltage (Vd) to the capacitor (113). ). When the fade-out control is performed, the control power supply (1h) preferably generates the control voltage (V11, V12) from the DC voltage (Vd) during a predetermined period (Tb) including the turn-off timing of the light source (12).

  The above lighting system (11) can maintain the operation of the control circuit (1d) by using the charging power of the capacitor (113) at least until the light source (12) is turned off during the fade-out control.

  Moreover, in the lighting system (11) of the third aspect according to the embodiment, in the second aspect, the predetermined period is the first period (Tb). The DC power supply circuit (1a) outputs a voltage (V2) different from the DC voltage (Vd) during operation. When the fade-out control is performed, the control power supply (1h) generates the control voltage (V11, V12) from the voltage (V2) in at least a part of the second period (Ta) before the first period (Tb). Preferably.

  The above lighting system (11) can maintain the operation of the control circuit (1d) in the second period (Ta).

  Moreover, in the lighting system (11) of the fourth aspect according to the embodiment, in the third aspect, when the fade-out control is performed, the control power supply (1h) causes the phase in a part of the second period (Ta). It is preferable to generate the control voltage (V11, V12) from the control voltage (Vb).

  The above lighting system (11) can maintain the operation of the control circuit (1d) in the second period (Ta).

  In addition, in the lighting system (11) of the fifth aspect according to the embodiment, in any one of the first to fourth aspects, the control circuit (1d) performs a DC voltage (Vd) when performing the fade-out control. However, it is preferable to control the converter (1b) to turn off the light source (12) before the voltage drops to the minimum voltage value (VL1) that enables the light source (12) to be turned on.

  The lighting system (11) described above can smoothly change the light output when the light output is faded out by the phase control of the AC voltage (Va). Therefore, the lighting system (11) can make the human eyes feel that the light output has decreased smoothly during the fade-out operation until the light source (12) is turned off.

  Moreover, the lighting control system (A1) of the sixth aspect according to the embodiment includes a lighting system (11) of any one of the first to fifth aspects connected to an AC power source (9) and a dimmer ( 2) with a series circuit. The dimmer (2) outputs a phase control voltage (Vb), which is an AC voltage (Va) whose conduction angle (θ) is variably set, to the lighting system (11).

  The above-described lighting control system (A1) operates the control circuit (1d) at least until the light source (12) is turned off when fading out the light output of the light source (12) by phase control of the AC voltage (Va). Can be maintained.

  The lighting fixture (B1) of the seventh aspect according to the embodiment is a lighting system (11) according to any one of the first to fifth aspects, and a light source to which lighting power is supplied from the lighting system (11). (12) and a housing (32) supporting at least the light source (12).

  The above lighting fixture (B1) maintains the operation of the control circuit (1d) at least until the light source (12) is extinguished when fading out the optical output of the light source (12) by phase control of the AC voltage (Va). can do.

  Further, the above-described embodiment and modified examples are examples. For this reason, the present invention is not limited to the above-described embodiments and modifications, and other than this embodiment and modifications, as long as it does not deviate from the technical idea of the present invention, the design Of course, various changes can be made according to the above.

1 Lighting Device 2 Dimmer 9 AC Power Supply 11 Lighting System 12 Light Source 32 Housing 113 Capacitor 1a DC Power Supply Circuit 1b Converter 1c Phase Reading Circuit 1d Control Circuit 1h Control Power Supply A1 Lighting Control System B1 Lighting Fixture θ Conduction Angle V11 First Control Voltage (control voltage)
V12 Second control voltage (control voltage)
Va AC voltage Vb Phase control voltage Vd DC voltage VL1 Minimum voltage value Ta Follow-up fade period (second period)
Tb fixed fade period (first period)

Claims (7)

A DC power supply circuit that inputs a phase control voltage, which is an AC voltage whose conduction angle is variably set, and outputs a DC voltage,
A converter which receives the DC voltage and supplies lighting power to a light source,
A phase reading circuit for detecting the conduction angle,
A control circuit that controls at least the converter according to the detection value of the conduction angle, and performs dimming control that lowers the dimming ratio of the light source as the detection value of the conduction angle is smaller,
A control power supply for generating a control voltage for operating the control circuit,
The control power supply maintains the control voltage at a value at which the control circuit is operable at least until the light source is turned off while a fade-out control for fading out a light output of the light source is performed as the dimming control. system. The DC power supply circuit has a capacitor, the DC voltage is generated in the capacitor,
The lighting system according to claim 1, wherein when the fade-out control is performed, the control power supply generates the control voltage from the DC voltage during a predetermined period including a turn-off timing of the light source. The predetermined period is the first period,
The DC power supply circuit outputs a voltage different from the DC voltage during operation,
The lighting system according to claim 2, wherein when the fade-out control is performed, the control power supply generates the control voltage from the voltage in at least a part of a second period before the first period. The lighting system according to claim 3, wherein the control power supply generates the control voltage from the phase control voltage during a part of the second period when the fade-out control is performed. The control circuit is
5. When performing the fade-out control, the converter is controlled to turn off the light source until the DC voltage drops to a minimum voltage value that enables the light source to be turned on. The lighting system according to the item. A series circuit comprising the lighting system according to any one of claims 1 to 5 and a dimmer connected to an AC power supply,
The lighting control system, wherein the dimmer outputs to the lighting system a phase control voltage that is an AC voltage with a conduction angle variably set. A lighting system according to any one of claims 1 to 5,
A light source supplied with the lighting power from the lighting system,
A housing that supports at least the light source.

Images