JP6233741B2 - Light emitting element lighting device, lighting fixture, and lighting system - Google Patents

Description

  The present invention relates to a light emitting element lighting device, a lighting fixture, and a lighting system.

  Conventionally, dimming control of light-emitting elements by electrically connecting a commercial power supply and a triac, which is a three-pole bidirectional thyristor, and controlling the triac to change the conduction angle of the power supply voltage of the commercial power supply There is a light emitting element lighting device. Examples of the light emitting element include an LED (Light Emitting Diode) element and an organic EL (Electroluminescence) element.

  The triac is turned on by applying a trigger signal to the gate. The triac is turned off when the anode current flowing in the triac becomes equal to or lower than the holding current, or when a reverse bias is applied between the anode and the cathode.

  In general, a so-called pulse trigger method is employed in which a pulse-like trigger signal is input to the gate terminal of a triac only when the triac is switched from an off state to an on state (only when the triac is turned on). However, in this pulse trigger method, when noise is superimposed on the power supply line of the commercial power supply, the triac may be unexpectedly switched to an off state because the anode current flowing through the triac is lower than the holding current due to the noise.

  Thus, a so-called DC trigger method has been proposed in which a trigger signal for turning on the triac is continuously supplied for a predetermined period of time during which the triac is turned on and conducted (see, for example, Patent Document 1).

JP 2012-185998 A

  However, the light emitting element lighting device using the above-described DC trigger method also has the following problems.

  First, in a normal time when noise is not superimposed on the power line of the commercial power supply, the triac is used until the anode current becomes equal to or lower than the holding current after the trigger signal duration T51 ends, as shown in FIG. , Maintain the conduction state. In this case, the triac conduction period T52 is from when the trigger signal rises until the anode current becomes equal to or lower than the holding current. Therefore, the power supply voltage is applied to the lighting fixture until the power supply voltage reaches the vicinity of the zero cross. In FIG. 14A, the broken line indicates the power supply voltage of the commercial power supply, and the solid line indicates the applied voltage of the lighting fixture.

  On the other hand, when noise is superimposed on the power line of the commercial power supply, as shown in FIG. 14B, the triac is turned off when the anode current becomes equal to or less than the holding current after the trigger signal duration T51 ends. There is a risk of doing. In this case, as shown in FIG. 14B, the triac conduction period T53 is shorter than the period T52. In FIG. 14B, the broken line indicates the power supply voltage of the commercial power supply, and the solid line indicates the applied voltage of the lighting fixture.

  Therefore, if noise is superimposed on the power line of the commercial power supply near the zero cross of the power voltage of the commercial power supply, there is a risk that the lighting period of the lighting fixture may flicker or turn off unexpectedly due to fluctuations in the triac conduction period. there were.

  The present invention has been made in view of the above-mentioned reasons, and the purpose thereof is to stabilize the triac without unexpectedly turning off even if noise is superimposed on the power supply line of the AC power supply near the zero cross of the power supply voltage. It is providing the light emitting element lighting device which can perform light control, a lighting fixture, and a lighting system.

The light-emitting element lighting device of the present invention is connected in series to a series circuit of a bidirectional switching element having a self-holding function and an AC power supply, and the bidirectional switching element is turned on for a predetermined period in a conducting period. A light-emitting element lighting device that is continuously supplied with a trigger signal for supplying power supplied from the AC power source to the light source composed of the light-emitting elements, thereby improving the power factor of the AC power source A power conversion circuit having a function and a bleeder circuit that is connected in parallel to the power conversion circuit and generates a bypass current using the AC power supply as a supply source, and the bleeder circuit is input to the power conversion circuit If the voltage is lower than the threshold only to generate the bypass current, within the predetermined period in which the trigger signal is continuously supplied, starts generating the bypass current And wherein the door.

The light-emitting element lighting device of the present invention is connected in series to a series circuit of a bidirectional switching element having a self-holding function and an AC power supply, and the bidirectional switching element is turned on for a predetermined period in a conducting period. A light-emitting element lighting device that is continuously supplied with a trigger signal for supplying power supplied from the AC power source to the light source composed of the light-emitting elements, thereby improving the power factor of the AC power source A power conversion circuit having a function and a bleeder circuit that is connected in parallel to the power conversion circuit and generates a bypass current using the AC power supply as a supply source, and the bleeder circuit is input to the power conversion circuit The bypass current is generated only when the voltage is lower than a threshold, and the bypass current is generated after the predetermined period in which the trigger signal is continuously supplied ends. Characterized in that it started.

  In this invention, it is preferable that the bleeder circuit controls the bypass current to a constant current.

  In this invention, it is preferable that the bleeder circuit gradually increases the bypass current when the voltage input to the power conversion circuit falls below the threshold and the bypass current starts to flow.

  In this invention, the bleeder circuit makes the magnitude of the bypass current variable based on a voltage input to the power conversion circuit in a period in which the bypass current is generated when the bidirectional switching element is conductive. It is preferable that the absolute value of the current flowing through the bidirectional switching element approaches a predetermined value.

  In the present invention, the light emitting element is preferably an LED element or an organic EL element.

  The lighting fixture of this invention is equipped with the light emitting element lighting device of this invention, It is characterized by the above-mentioned.

  In this invention, it is preferable to provide a light emitting element to which lighting power is supplied from the light emitting element lighting device.

The illumination system of the present invention, a light source comprising a light emitting element, a power conversion circuit supplying lighting power to the light source with power supplied from the ac power source, and the AC power supply is connected in parallel to the power conversion circuit A lighting load having a bleeder circuit for generating a bypass current as a supply source , a bidirectional switching element connected in series to a series circuit of the power conversion circuit and an AC power supply and having a self-holding function, and the bidirectional switching element A dimming control unit that performs phase control to change the conduction angle of the AC voltage of the AC power supply by controlling the dimming control unit, and the dimming control unit is a predetermined period of time during which the bidirectional switching element is conducted. over, the bidirectional switching device to supply continuously a trigger signal to turn on, the power conversion circuit is configured to have a power factor improving function of the alternating current power supply, before The bleeder circuit generates the bypass current only when the voltage input to the power conversion circuit is lower than a threshold, and starts generating the bypass current within the predetermined period in which the trigger signal is continuously supplied. characterized in that it.
The illumination system of the present invention supplies a light source composed of a light emitting element, a power conversion circuit that supplies lighting power to the light source using power supplied from an AC power source, and the AC power source connected in parallel to the power conversion circuit A lighting load having a bleeder circuit that generates a bypass current as a source; a bidirectional switching element connected in series to a series circuit of the power conversion circuit and an AC power supply and having a self-holding function; and the bidirectional switching element And a dimming control unit that performs phase control to change a conduction angle of the AC voltage of the AC power source by controlling the dimming control unit in a predetermined period of time during which the bidirectional switching element is conducted. And continuously supplying a trigger signal for turning on the bidirectional switching element, the power conversion circuit has a power factor improving function of the AC power supply, The bleeder circuit generates the bypass current only when the voltage input to the power conversion circuit is lower than a threshold value, and generates the bypass current after the predetermined period in which the trigger signal is continuously supplied ends. It is characterized by starting.

  As described above, according to the present invention, even when noise is superimposed on the power supply line of the AC power supply near the zero cross of the power supply voltage, the effect that stable dimming can be performed without turning off the triac unexpectedly. There is.

It is a block diagram which shows the structure of the illumination system of Embodiment 1. It is a circuit diagram which shows the structure of a lighting fixture same as the above. (A)-(e) It is a wave form diagram which shows operation | movement of each part same as the above. It is a circuit diagram which shows the structure of a current drawing part same as the above. (A) (b) It is a wave form diagram which shows operation | movement of a phase detection circuit same as the above. (A)-(d) It is a wave form diagram of each part explaining a bypass current same as the above. (A)-(e) It is a wave form diagram of each part explaining another bypass current same as the above. FIG. 6 is a circuit diagram illustrating a configuration of a current drawing unit of the second embodiment. It is a circuit diagram which shows the structure of the electric current drawing part of Embodiment 3. (A)-(d) It is a wave form diagram of each part explaining a bypass current same as the above. (A)-(c) It is a wave form diagram of each part explaining a bypass current same as the above. It is a circuit diagram which shows the structure of the electric current drawing part of Embodiment 4. (A)-(c) It is a wave form diagram of each part explaining a bypass current same as the above. (A) (b) It is a wave form diagram of each part which shows the conventional operation | movement.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 shows the configuration of the illumination system of the present embodiment. The lighting system includes a lighting fixture 1 and a dimmer 2. In this lighting system, a series circuit of a lighting fixture 1 and a dimmer 2 is connected between both ends of a commercial power supply 10 (AC power supply). And the lighting fixture 1 is comprised by connecting the illumination load 11 and the bleeder circuit 12 in parallel. The dimmer 2 adjusts the power supplied from the commercial power supply 10 to the lighting fixture 1 by phase-controlling the power supply voltage (AC voltage) of the commercial power supply 10.

  First, as shown in FIG. 2, the illumination load 11 includes an input filter circuit 1a, a rectifier circuit 1b, a power conversion circuit 1c, a phase detection circuit 1d, a dimming circuit 1e, an output feedback circuit 1f, a light source Part 1g. The power conversion circuit 1c and the bleeder circuit 12 constitute a light emitting element lighting device 13.

  The input filter circuit 1 a includes a capacitor C <b> 1 connected between the input ends of the lighting load 11 and an inductor L <b> 1 connected in series to both power supply lines of the lighting load 11. The input filter circuit 1a has a function of suppressing noise propagating to the power supply line and noise radiating to the space.

  The rectifier circuit 1b is configured by full-bridge connection of diodes, and full-wave rectifies the power supply voltage of the commercial power supply 10.

  The power conversion circuit 1c includes capacitors C2 and C3, a transformer T1, a switching element Q1, a control circuit K1, and a diode D1, and constitutes a non-insulated flyback converter. The power conversion circuit 1c constitutes a quasi-resonant circuit for reducing loss and noise, and further has a power factor improving function for improving the power factor of the commercial power source 10.

  The capacitor C2 is a film capacitor connected between the output terminals of the rectifier circuit 1b, and suppresses a voltage / current spike generated when the switching element Q1 is turned on. The capacitor C2 has a smaller capacity than the smoothing capacitor and does not take into account the smoothing action. That is, the power conversion circuit 1c does not include a smoothing capacitor having a large capacity, such as an electrolytic capacitor, in the input means, and does not constitute a capacitor input type power supply circuit.

  The transformer T1 includes a primary winding N1, a secondary winding N2, and a tertiary winding N3, and the windings are magnetically coupled to each other. A series circuit of the primary winding N1 and the switching element Q1 is connected between the output ends of the rectifier circuit 1b, and a diode D1 is interposed at one end of the secondary winding N2, and the secondary winding A smoothing capacitor C3 is connected in parallel to the series circuit of N2 and the diode D1. The tertiary winding N3 is connected to the control circuit K1 and generates an operating power supply for the control circuit K1.

  The control circuit K1 drives the switching element Q1 on / off. First, when the switching element Q1 is turned on, a current flows through the series circuit of the primary winding N1 and the switching element Q1, and magnetic energy is accumulated in the primary winding N1. Next, when the switching element Q1 is turned off, an induced voltage is generated in the secondary winding N2 due to the magnetic energy of the primary winding N1, and a voltage is generated across the capacitor C3. When the switching element Q1 is turned off, an induced voltage is also generated in the tertiary winding N3 due to the magnetic energy of the primary winding N1, and is supplied to the control circuit K1 as an operating power source.

  Further, the control circuit K1 controls the output of the power conversion circuit 1c to a predetermined value by switching the switching element Q1, and further improves the power factor of the commercial power source 10. Note that the power factor correction operation by the flyback converter is a well-known technique and will not be described in detail.

  The light source unit 1g is composed of a plurality of LED elements or organic EL elements connected in series or in parallel, and is connected between both ends of the capacitor C3.

  The phase detection circuit 1d is connected to the cathodes of the diodes D2 and D3 each having an anode connected to each input terminal of the rectifier circuit 1b, and a voltage waveform obtained by full-wave rectifying the power supply voltage phase-controlled by the dimmer 2 is obtained. Entered. Then, the phase detection circuit 1d detects the conduction angle of the power supply voltage input to the illumination load 11, and outputs a duty ratio signal (duty signal) corresponding to the detected conduction angle to the dimming circuit 1e.

  The dimming circuit 1e sets a target value of the load current corresponding to the duty ratio of the duty signal, and outputs a voltage signal (target signal) corresponding to the target value of the load current to the output feedback circuit 1f.

  The output feedback circuit 1f detects a load current flowing through the light source unit 1g by a resistor or the like connected in series with the light source unit 1g. Moreover, the output feedback circuit 1f acquires the target value of the load current based on the target signal input from the dimming circuit 1e. Then, the output feedback circuit 1f outputs a feedback signal (for example, an error between the load current detection value and the target value) based on the load current detection value and the target value to the control circuit K1.

  The control circuit K1 performs constant current control so that the load current matches the target value by setting the conduction period (ON period) of the switching element Q1 according to the feedback signal.

  Next, as shown in FIG. 1, the dimmer 2 includes a capacitor C11 and an inductor L11 that constitute a noise prevention filter, and a triac Q11 that is a bidirectional switching element having a self-holding function. The capacitor C11 is connected between the input ends of the dimmer 2, and a series circuit of the triac Q11 and the inductor L11 is connected in parallel to the capacitor C11. The triac Q11 is connected in series to a series circuit of the power conversion circuit 1c and the commercial power supply 10. Then, AC power is supplied from the commercial power supply 10 to the lighting fixture 1 when the triac Q11 is in a conducting state.

  The dimmer 2 includes a control power supply unit 4. The control power supply unit 4 generates a control power supply for each unit (the dimming control unit 3 described later) of the dimmer 2, and is connected in parallel to the triac Q11.

  The control power supply unit 4 includes a diode D11, a capacitor C12, a power supply circuit K11, and a capacitor C13.

  The diode D11 is connected to the power supply line from the lighting fixture 1, and the capacitor C12 is connected in parallel to the triac Q11 via the diode D11. The power supply circuit K11 converts the voltage across the capacitor C12 into a control voltage Vcc and outputs it. The capacitor C13 is a smoothing capacitor connected between the output terminals of the power supply circuit K11. Here, the low voltage terminal of the capacitor C13 is connected to the circuit ground.

  Furthermore, the dimmer 2 includes a dimming control unit 3. The dimming control unit 3 includes a phase detection circuit K12, a control circuit K13, and an operation unit K14. The dimming control unit 3 controls the triac Q11 to perform phase control that makes the conduction angle of the power supply voltage of the commercial power supply 10 variable.

  First, the phase detection circuit K12 is connected to the power supply line (the anode side of the diode D11) from the lighting fixture 1 via the diode D12. The phase detection circuit K12 has a ground terminal connected to the circuit ground, generates a synchronization signal shown in FIG. 3A based on the phase of the power supply voltage supplied from the commercial power supply 10, and outputs it to the control circuit K13. To do. Specifically, the phase detection circuit K12 compares the power supply voltage of the commercial power supply 10 with a predetermined threshold value Vt1 by detecting the power supply voltage of the commercial power supply 10 via the diode D12, and the power supply voltage exceeds the threshold value Vt1. A synchronization signal having a period of H level is generated. That is, the synchronization signal rises when the power supply voltage exceeds the threshold value Vt1, and falls when the power supply voltage falls below the threshold value Vt1. 3A to 3C, the broken line indicates the power supply voltage of the commercial power supply 10.

  The control circuit K13 generates a trigger signal for turning on the triac Q11 based on the synchronization signal supplied from the phase detection circuit K12 and the dimming signal supplied from the operation unit K14 (see FIG. 3B). The rise and fall of the trigger signal are both determined with reference to the rise of the synchronization signal. The control circuit K13 outputs a trigger signal to the gate of the triac Q11, whereby a drive current flows through the gate of the triac Q11 and the triac Q11 becomes conductive.

  In other words, the dimming control unit 3 controls the phase of the power supply voltage (voltage input to the power conversion circuit 1c) applied to the lighting load 11 by turning on the triac Q11.

  Hereinafter, the dimming operation of the present embodiment will be described. First, the phase detection circuit K12 generates a synchronization signal and outputs it to the control circuit K13. The operation unit K14 outputs a dimming signal corresponding to the user operation to the control circuit K13. The control circuit K13 generates a trigger signal based on the synchronization signal and the dimming signal, and outputs it to the gate of the triac Q11. The triac Q11 is turned on when the trigger signal rises and becomes conductive. Therefore, as shown in FIG. 3C, the power supply voltage of the commercial power supply 10 is applied to the lighting load 11 under phase control, and the power supply voltage of the commercial power supply 10 subjected to phase control is input to the power conversion circuit 1c. The The rising edge of the trigger signal changes in phase angle depending on the voltage signal output from the operation unit K14 operated by the user. Thereby, since the conduction angle of the power supply voltage applied to the illumination load 11 changes, dimming can be performed.

  Thereafter, when the trigger signal falls, the driving current does not flow to the gate of the triac Q11. Since the triac Q11 maintains the conduction state while the anode current exceeds the holding current, the power supply voltage of the commercial power supply 10 is continuously applied to the illumination load 11 for a while after the trigger signal falls (FIG. 3 (c)). )reference). When the anode current of the triac Q11 becomes equal to or lower than the holding current, the triac Q11 is switched to a non-conduction state (off state). Thereby, application of the power supply voltage of the commercial power supply 10 to the illumination load 11 is stopped.

  In the illumination load 11, the phase detection circuit 1d detects the conduction angle of the power supply voltage input to the illumination load 11, and outputs a duty signal corresponding to the detected conduction angle to the dimming circuit 1e. The dimming circuit 1e sets a target value of the load current according to the duty ratio of the duty signal, and outputs a target signal corresponding to the target value. The output feedback circuit 1f outputs a feedback signal based on the detected value of the load current and the target value to the control circuit K1. The control circuit K1 sets the conduction period (ON period) of the switching element Q1 according to the feedback signal, thereby performing constant current control so that the load current matches the target value, and dimming the light source unit 1g. .

  Here, as shown in FIG. 3B, unlike the pulse trigger, the trigger signal is continuously at the H level for a certain period of time during which the lighting load 11 is supplied with power for lighting. As a result, the drive current continues to flow through the gate terminal of the triac Q11 until the trigger signal falls. That is, the drive current is continuously applied to the triac Q11 for a certain period (the H level period of the trigger signal) of the period in which the triac Q11 is turned on.

  The lighting load 11 uses a power conversion circuit 1c, and as shown in FIG. 3D, the input current of the lighting load 11 is sinusoidal, and the power factor of the commercial power supply 10 is improved. That is, the anode current of the triac Q11 can be secured even when the amplitude of the power supply voltage of the commercial power supply 10 decreases past the peak and reaches the vicinity of the zero cross. Therefore, even if noise is superimposed on the power supply line of the commercial power supply 10 near the zero cross of the power supply voltage of the commercial power supply 10, fluctuations in the conduction period of the triac Q11 can be suppressed, and the lighting of the light source unit 1g may be flickering or unexpected. The possibility of turning off the light can be reduced.

  Thus, in the light-emitting element lighting device 13, the lighting fixture 1, and the lighting system of the present embodiment, the triac Q11 is unexpectedly turned off even if noise is superimposed on the power supply line of the commercial power supply 10 near the zero cross of the power supply voltage. Therefore, stable dimming can be performed.

  On the other hand, it is assumed that a large-capacity smoothing capacitor (for example, an electrolytic capacitor) that smoothes the rectified voltage of the rectifier circuit 1b is provided instead of the power conversion circuit 1c, and the voltage of the smoothing capacitor is applied to the light source unit 1g. In this case, the input current of the lighting load 11 becomes a waveform of the inrush current shown in FIG. 3 (e), and the power factor of the commercial power supply 10 becomes low. Therefore, when such a capacitor input type power conversion circuit is used, the anode current of the triac Q11 can be secured when the amplitude of the power supply voltage of the commercial power supply 10 decreases past the peak and reaches the vicinity of the zero cross. It becomes difficult. Therefore, if noise is superimposed on the power supply line of the commercial power supply 10 in the vicinity of the zero cross of the power supply voltage, the triac Q11 may turn off unexpectedly and the dimming may become unstable.

  Further, in the present embodiment, the bleeder circuit 12 is provided in parallel with the power conversion circuit 1c of the illumination load 11 so that a sufficient anode current exceeding the holding current continuously flows in the triac Q11 even during the off period of the trigger signal. (See FIGS. 1 and 2). The bleeder circuit 12 also has a function of supplying power to the control power supply unit 4 of the dimmer 2 when the triac Q11 is turned off.

  First, as shown in FIG. 2, the bleeder circuit 12 includes diodes D2 and D3 having anodes connected to respective input terminals of the rectifier circuit 1b, cathodes of the diodes D2 and D3, and a low-voltage side of the rectified output of the rectifier circuit 1b. And a current drawing part 12a connected between the two. That is, the bleeder circuit 12 can be considered equivalent to a bleeder circuit 12 connected in parallel to the power conversion circuit 1c of the illumination load 11, as shown in FIG.

  FIG. 4 shows a circuit configuration of the current drawing unit 12a. In the current drawing unit 12a, a series circuit of an FET element Q31, a resistor R31, and a resistor R32 is connected between the cathodes of the diodes D2 and D3 and the low-voltage side of the rectified output of the rectifier circuit 1b. The drain of the FET element Q31 is connected to the cathodes of the diodes D2 and D3, and the source of the FET element Q31 is connected to a series circuit of resistors R31 and R32. Further, the gate of the FET element Q31 is connected to the phase detection circuit 1d. A Zener diode ZD31 is connected between the gate of the FET element Q31 and the low-voltage side of the rectified output of the rectifier circuit 1b.

  The phase detection circuit 1 d detects the conduction angle of the power supply voltage input to the illumination load 11. Specifically, the phase detection circuit 1d receives a voltage waveform (see FIG. 5A) obtained by full-wave rectification of the phase-controlled power supply voltage via the diodes D2 and D3. By comparing with the threshold value Vt2, a duty signal corresponding to the conduction angle is generated. The duty signal becomes L level when the amplitude of the power supply voltage is equal to or higher than the threshold value Vt2, and becomes H level when the amplitude of the power supply voltage is lower than the threshold value Vt2 (see FIG. 5B). The phase detection circuit 1d applies this duty signal to the gate of the FET element Q31 of the current drawing unit 12a.

  The FET element Q31 is turned on when the duty signal is at H level, that is, when the amplitude of the phase-controlled power supply voltage is less than the threshold value Vt2, via the diode D2 or D3, the FET element Q31, and the resistors R31 and R32. A bypass current Ib flows. The bypass current Ib flows through a closed circuit including the commercial power supply 10, the bleeder circuit 12, and the dimmer 2 using the commercial power supply 10 as a supply source.

  Hereinafter, the operation of the bleeder circuit 12 will be described with reference to FIGS. In the following description, reference numerals of the bypass currents Ib1 and Ib2 are given depending on the generation period of the bypass current Ib. In FIGS. 6A and 6B, the broken line indicates the power supply voltage of the commercial power supply 10.

  First, when the power supply voltage passes through the zero cross, the amplitude of the power supply voltage is less than the threshold value Vt2 (see FIG. 6B), the duty signal becomes H level (see FIG. 6C), and the FET element. Q31 is turned on, and a bypass current Ib1 is generated (see FIG. 6D). At this time, the triac Q11 of the dimmer 2 is off, and the bypass current Ib1 charges the capacitor C12 through the diode D11 of the dimmer 2. In other words, the control power supply unit 4 generates the control voltage Vcc using the bypass current Ib for maintaining the ON state of the triac Q11, and can secure the control power supply with a simple configuration.

  When the trigger signal rises (see FIG. 6A) and the triac Q11 becomes conductive, the power supply voltage of the commercial power supply 10 is applied to the illumination load 11. When the amplitude of the power supply voltage becomes equal to or higher than the threshold value Vt2 (see FIG. 6B), the duty signal becomes L level (see FIG. 6C), the FET element Q31 is turned off, and the bypass current Ib1 Becomes zero (see FIG. 6D).

  When the amplitude of the power supply voltage decreases after increasing to the peak value and the trigger signal falls (see FIG. 6 (a)), the drive current does not flow to the gate of the triac Q11. As long as the current exceeds the holding current, the conduction state is maintained.

  In this embodiment, when the power supply voltage becomes lower than the threshold value Vt2 (see FIG. 6B), the duty signal becomes H level (see FIG. 6C), the FET element Q31 is turned on, A bypass current Ib2 is generated (see FIG. 6D). The bypass current Ib2 flows through the triac Q11 that is kept conductive after the trigger signal falls, so that the anode current is maintained to be equal to or higher than the holding current.

  Therefore, even if noise is superimposed on the power supply line of the commercial power supply 10 in the vicinity of the zero cross of the power supply voltage, stable dimming can be performed without the triac Q11 turning off unexpectedly. In the embodiment shown in FIG. 6, by setting the threshold value Vt2 relatively high, the duty signal is switched to the H level and the bypass current Ib2 starts to flow before the trigger signal falls, so that the noise resistance is improved. It is further improved.

  For example, when the load power supplied to the light source unit 1g is reduced due to deep light control or due to the temperature characteristics of the circuit elements, the input current of the illumination load 11 may be reduced. In this case, in the vicinity of the zero cross of the input current, the anode current of the triac Q11 may be equal to or lower than the holding current, but the anode current exceeding the holding current can be secured by the bypass current Ib.

  Furthermore, in this embodiment, by using the power conversion circuit 1c having the power factor improvement function, the required bypass current Ib can be suppressed and the circuit loss can be reduced as compared with the case where the capacitor input type power conversion circuit is used. Can be planned.

  Further, the power factor improvement by the power conversion circuit 1c eliminates the need for the bypass current Ib to flow in the phase angle region where the input current of the lighting load 11 is high (the phase angle region where the power supply voltage is high). Reduction can be achieved.

  In addition, the current drawing unit 12a is configured so that the sum of the gate-source voltage of the FET element Q31 and the voltage across the series circuit of the resistors R31 and R32 matches the Zener voltage of the Zener diode ZD31. The drain current is constant current controlled. That is, the bypass current Ib is constant-current controlled by the current drawing unit 12a, and the bypass current Ib does not greatly exceed the necessary holding current, and contributes to the reduction of circuit loss.

  Alternatively, as shown in FIGS. 7A to 7E, the duty signal is set after the trigger signal falls by setting the threshold value Vt2 to be compared with the power supply voltage relatively low (see FIG. 7B). May be switched to the H level and the bypass current Ib2 may begin to flow. In this case, a period Ta in which the bypass current Ib2 does not flow occurs from when the trigger signal falls to when the bypass current Ib2 starts flowing (see FIG. 7E). However, the lighting load 11 improves the power factor of the commercial power supply 10 using the power conversion circuit 1c, and the input current of the lighting load 11 (the anode current of the triac Q11) becomes a sufficiently large value even in the vicinity of the zero cross ( (Refer FIG.7 (c)). Accordingly, noise resistance against noise superimposed on the power supply line of the commercial power supply 10 can be ensured even during the period Ta. Furthermore, the circuit loss can be further reduced by shortening the period during which the bypass current Ib2 flows. 7A and 7B, the broken line indicates the power supply voltage of the commercial power supply 10.

  As described above, in the present embodiment, the bypass current Ib is generated in order to maintain the triac Q11 in the ON state even in the vicinity of the zero cross of the power supply voltage, and the control power supply is secured using the bypass current Ib. Furthermore, the circuit loss is reduced by constant current control of the bypass current Ib.

  In the dimming method of the lighting fixture 1 of the present embodiment, the light source unit 1g is dimmed by turning on and off the switching element Q1, but a circuit that performs dimming by varying the current flowing through the light source unit 1g. It goes without saying that the same effect can be achieved with the configuration.

  In addition, the LED element and the organic EL element used for the light source unit 1g are likely to generate noise at the time of lighting, and the above-described operations become more effective. In the present embodiment, an LED element or an organic EL element is used as the light source unit 1g. However, the present invention is not limited to this, and other solid light emitting elements may be used for the light source unit 1g.

(Embodiment 2)
In the present embodiment, the configuration of the current drawing unit of the bleeder circuit 12 is different from that of the first embodiment, and FIG. 8 shows the configuration of the current drawing unit 12b of the present embodiment. Other configurations are the same as those in the first embodiment, and a description thereof will be omitted.

  The current drawing unit 12b of the bleeder circuit 12 includes an operational amplifier OP31, an FET element Q32, and resistors R33 and R34.

  A series circuit of the FET element Q32 and the resistor R33 is connected between the cathodes of the diodes D2 and D3 and the low-voltage side of the rectified output of the rectifier circuit 1b. The drain of the FET element Q32 is connected to the cathodes of the diodes D2 and D3, and the source of the FET element Q32 is connected to the resistor R33.

  The non-inverting input of the operational amplifier OP31 is connected to the output of the phase detection circuit 1d, and the inverting input of the operational amplifier OP31 is connected to the source of the FET element Q32. The output of the operational amplifier OP31 is connected to the gate of the FET element Q32. Further, a resistor R34 is connected between the non-inverting input of the operational amplifier OP31 and the low voltage side of the rectified output of the rectifier circuit 1b.

  The phase detection circuit 1 d detects the conduction angle of the power supply voltage input to the illumination load 11. Specifically, the phase detection circuit 1d receives a voltage waveform (see FIG. 5A) obtained by full-wave rectification of the phase-controlled power supply voltage via the diodes D2 and D3. By comparing with the threshold value Vt2, a duty signal corresponding to the conduction angle is generated. The duty signal becomes L level when the amplitude of the power supply voltage is equal to or higher than the threshold value Vt2, and becomes H level when the amplitude of the power supply voltage is lower than the threshold value Vt2 (see FIG. 5B).

  The phase detection circuit 1d applies this duty signal to the non-inverting input of the operational amplifier OP31 of the current drawing unit 12b. The operational amplifier OP31 sets the output voltage to the H level and turns on the FET element Q32 when the duty signal is at the H level.

  That is, the FET element Q32 is turned on when the duty signal is H level, that is, when the amplitude of the phase-controlled power supply voltage is less than the threshold value Vt2, and the bypass current is passed through the diode D2 or D3, the FET element Q32, and the resistor R33 Ib flows. The bypass current Ib flows through the closed circuit of the commercial power source 10, the bleeder circuit 12, and the dimmer 2.

  The operational amplifier OP31 performs constant current control on the drain current of the FET element Q32 so that the voltage across the resistor R33 generated by the bypass current Ib matches the H level voltage of the duty signal applied to the non-inverting input of the operational amplifier OP31. To do. That is, the bypass current Ib is controlled at a constant current by the current drawing unit 12b, and the bypass current Ib does not greatly exceed a necessary holding current, and contributes to a reduction in circuit loss.

  Note that the circuit operation using the bypass current Ib is the same as that in the first embodiment, and a description thereof will be omitted.

(Embodiment 3)
In the present embodiment, the configuration of the current drawing unit of the bleeder circuit 12 is different from that of the first embodiment, and FIG. 9 shows the configuration of the current drawing unit 12c of the present embodiment. In addition, the same code | symbol is attached | subjected to the structure similar to Embodiment 1, and description is abbreviate | omitted.

  First, operations by the bleeder circuit 12 using the current drawing unit 12a of the first embodiment are shown in FIGS. 10 (a) to 10 (d).

  When the amplitude of the power supply voltage is less than the threshold value Vt2 (see FIG. 10A), the FET element Q31 is turned on to generate bypass currents Ib1 and Ib2 (see FIG. 10D). The bypass current Ib1 is a current for securing a control power source for the dimmer 2. The bypass current Ib2 is a current for maintaining the ON state of the triac Q11 even in the vicinity of the zero cross of the power supply voltage. The input current of the lighting fixture 1 is the sum of the input current of the lighting load 11 and the bypass currents Ib1 and Ib2 (see FIG. 10B).

  The anode current of the triac Q11 (current flowing through the triac Q11) is the sum of the input current of the lighting load 11 and the bypass current Ib2 (see FIG. 10C). In the period Tb2 during which the bypass current Ib2 is flowing, the anode current of the triac Q11 only needs to secure the holding current Ih of the triac Q11 in order to improve noise resistance. That is, the bypass current Ib2 (shaded portion in FIG. 10C) that flows in excess of the holding current Ih in the period Tb2 is originally unnecessary and causes a loss that occurs in the lighting system.

  Therefore, the bleeder circuit 12 reduces the voltage applied to the lighting load 11 (voltage input to the power conversion circuit 1c) below the threshold value Vt2 in order to suppress unnecessary anode current flowing through the triac Q11 in the period Tb2. When the bypass current Ib2 starts to flow, the bypass current Ib2 is gradually increased. The input current of the lighting fixture 1 is the sum of the input current of the lighting load 11 and the bypass currents Ib1 and Ib2 (see FIG. 11A).

  The current drawing unit 12c of the bleeder circuit 12 is configured by adding a capacitor C21, resistors R41 and R42, and a diode D21 to the current drawing unit 12a (see FIG. 4). The capacitor C21 is connected in parallel to the Zener diode ZD31. The resistor R41 is inserted in front of the capacitor C21 and the Zener diode ZD31 in the path from the phase detection circuit 1d to the gate of the FET element Q31 (path for outputting a duty signal). A series circuit of the resistor R42 and the diode D21 is connected in parallel to the resistor R41. The diode D21 has a forward direction from the gate of the FET element Q31 toward the phase detection circuit 1d.

  When the duty signal output from the phase detection circuit 1d is switched from the L level to the H level, the capacitor C21 is gradually charged through the resistor R41. That is, the gate voltage of the FET element Q31 gradually increases according to the time constant determined by the resistor R41 and the capacitor C21. Since the FET element Q31 gradually shifts from the non-saturated region to the saturated region at the time of turn-on, the drain current of the FET element Q31 gradually increases. Therefore, after the bypass current Ib2 gradually increases (increases) when it starts to flow, the absolute value of the amplitude is controlled to be constant (see FIG. 11C).

  By gradually increasing the bypass current Ib2 at the time of rising, the bypass current Ib2 is reduced in excess (the hatched portion in FIG. 11B) flowing beyond the holding current Ih in the period Tb2. Therefore, unnecessary anode current can be suppressed, and loss generated in the lighting system can be reduced.

  Further, when the duty signal output from the phase detection circuit 1d is switched from the H level to the L level, the capacitor C21 is discharged through a path passing through the resistor R41 and a path passing through the diode D21 and the resistor R42. That is, since the capacitor C21 is discharged through two paths, the time required for the fall of the gate voltage of the FET element Q31 is shortened. Therefore, the FET element Q31 can suppress the switching loss at the time of turn-off.

(Embodiment 4)
The configuration of this embodiment is shown in FIG. 12 and suppresses an unnecessary anode current flowing through the triac Q11 in the period Tb2 as in the third embodiment. In addition, the same code | symbol is attached | subjected to the structure similar to Embodiment 1, 3, and description is abbreviate | omitted.

  The bleeder circuit 12 of FIG. 12 includes a current drawing unit 12d. In the current drawing unit 12d, a series circuit of the FET element Q31, the resistor R31, and the resistor R32 is connected between the cathodes of the diodes D2 and D3 and the low-voltage side of the rectified output of the rectifier circuit 1b. The gate of the FET element Q31 is connected to the phase detection circuit 1h.

  The phase detection circuit 1h of the present embodiment uses a microcomputer. The phase detection circuit 1h is connected to the cathodes of the diodes D2 and D3 each having an anode connected to each input terminal of the rectifier circuit 1b. The voltage waveform obtained by full-wave rectifying the power supply voltage phase-controlled by the dimmer 2 is obtained. Entered. Then, the phase detection circuit 1h detects the magnitude of the power supply voltage (instantaneous value of the power supply voltage) input to the illumination load 11, and controls the amplitude of the duty signal based on the instantaneous value of the power supply voltage, so that the FET The waveform of the drain current (bypass current Ib) of the element Q31 is controlled. The amplitude control of the duty signal by the phase detection circuit 1h is realized by the microcomputer executing a program.

  Specifically, when the duty signal is switched from the L level to the H level, the phase detection circuit 1h gradually increases the amplitude of the duty signal stepwise or continuously as the instantaneous value of the power supply voltage decreases. That is, the gate voltage of the FET element Q31 is controlled by the phase detection circuit 1h and gradually increases stepwise or continuously. Since the FET element Q31 gradually shifts from the non-saturated region to the saturated region at the time of turn-on, the drain current of the FET element Q31 gradually increases stepwise or continuously. Thus, the bypass current Ib2 gradually increases (gradually increases) stepwise or continuously when it starts to flow, and then the absolute value of the amplitude is controlled to be constant (see FIG. 13C). Note that the input current of the lighting fixture 1 is the sum of the input current of the lighting load 11 and the bypass currents Ib1 and Ib2 (see FIG. 13A).

  That is, the phase detection circuit 1h using a microcomputer has a bypass current Ib2 corresponding to the instantaneous value of the power supply voltage so that the sum of the input current of the illumination load 11 and the bypass current Ib2 approaches the holding current Ih in the period Tb2. Control the size of. Thus, the bypass current Ib2 is suppressed as much as possible by the excessive amount (hatched portion in FIG. 13B) flowing beyond the holding current Ih in the period Tb2. Therefore, unnecessary anode current can be further suppressed, and loss generated in the lighting system can be further reduced.

  As described above, the bleeder circuit 12 changes the magnitude of the bypass current Ib2 based on the voltage applied to the lighting load 11 (voltage input to the power conversion circuit 1c) in the period Tb2, thereby making the triac The absolute value of the anode current of Q11 approaches the holding current Ih.

  That is, the above-described light emitting element lighting device 13 is connected in series to a series circuit of a bidirectional switching element (triac Q11) having a self-holding function and an AC power supply (commercial power supply 10). The triac Q11 is continuously supplied with a trigger signal for turning on for a predetermined period of the conduction period. The light emitting element lighting device 13 receives the power supplied from the commercial power supply 10 and supplies the lighting power to the light source unit 1g composed of the light emitting elements. The power conversion circuit 1c having the power factor improving function of the commercial power supply 10 is provided. Prepare.

  Moreover, the above-mentioned lighting fixture 1 is provided with the light emitting element lighting device 13 of the present invention.

  The illumination system includes a light source unit 1g made of a light emitting element, and a power conversion circuit 1c that supplies lighting power to the light source unit 1g using power supplied from an AC power source (commercial power source 10). A load 11 is provided. Further, the lighting system is connected in series to a series circuit of the power conversion circuit 1c and the commercial power source 10 and has a bi-directional switching element (triac Q11) having a self-holding function, and the AC voltage of the commercial power source 10 by controlling the triac Q11. And a dimming control unit 3 that performs phase control to make the conduction angle of the light variable. Then, the dimming control unit 3 continuously supplies a trigger signal for turning on the triac Q11 for a predetermined period of time during which the triac Q11 is conducted, and the power conversion circuit 1c improves the power factor of the commercial power source 10. It has a function.

DESCRIPTION OF SYMBOLS 1 Lighting fixture 2 Dimmer 3 Dimming control part 10 Commercial power supply (AC power supply)
DESCRIPTION OF SYMBOLS 11 Illumination load 12 Breeder circuit 13 Light emitting element lighting device 1c Power conversion circuit 1g Light source part Q11 Triac (bidirectional switching element)

Claims (10)

It is connected in series to a series circuit of a bidirectional switching element having a self-holding function and an AC power supply, and the bidirectional switching element continuously supplies a trigger signal for turning on for a predetermined period of a conducting period. A light emitting device lighting device,
A power conversion circuit that receives power supplied from the AC power supply and supplies lighting power to a light source composed of a light emitting element, and has a power factor improving function of the AC power supply ;
A bleeder circuit that is connected in parallel to the power conversion circuit and generates a bypass current using the AC power supply as a supply source ;
The bleeder circuit generates the bypass current only when the voltage input to the power conversion circuit is lower than a threshold, and generates the bypass current within the predetermined period in which the trigger signal is continuously supplied. A light emitting element lighting device characterized by starting . It is connected in series to a series circuit of a bidirectional switching element having a self-holding function and an AC power supply, and the bidirectional switching element continuously supplies a trigger signal for turning on for a predetermined period of a conducting period. A light emitting device lighting device,
A power conversion circuit that receives power supplied from the AC power supply and supplies lighting power to a light source composed of a light emitting element, and has a power factor improving function of the AC power supply;
A bleeder circuit that is connected in parallel to the power conversion circuit and generates a bypass current using the AC power supply as a supply source ;
The bleeder circuit generates the bypass current only when the voltage input to the power conversion circuit is lower than a threshold, and after the predetermined period in which the trigger signal is continuously supplied ends, light - emitting element lighting device you characterized in that initiates generation. The bleeder circuit, the light emitting element lighting device according to claim 1, wherein the controller controls the bypass current in the constant current. The bleeder circuit, when the voltage input to the power conversion circuit starts decreased the bypass current flows than the threshold, any one of claims 1 to 3, wherein the gradually increasing the bypass current light emitting element lighting device according to.   The bleeder circuit is configured to change the magnitude of the bypass current based on a voltage input to the power conversion circuit during a period in which the bypass current is generated when the bidirectional switching element is turned on. The light emitting element lighting device according to claim 4, wherein an absolute value of a current flowing through the element is made to approach a predetermined value. The light emitting element lighting device according to claim 1, wherein the light emitting element is an LED element or an organic EL element . A lighting fixture comprising the light-emitting element lighting device according to any one of claims 1 to 6. The lighting fixture according to claim 7, further comprising a light emitting element to which lighting power is supplied from the light emitting element lighting device. A light source composed of a light emitting element, a power conversion circuit that supplies lighting power to the light source using power supplied from an AC power source, and a bypass current that is connected in parallel to the power conversion circuit and that uses the AC power source as a supply source A lighting load comprising a bleeder circuit to
  A bidirectional switching element connected in series to a series circuit of the power conversion circuit and an AC power supply and having a self-holding function;
  A dimming control unit that performs phase control to change the conduction angle of the AC voltage of the AC power supply by controlling the bidirectional switching element;
  The dimming control unit continuously supplies a trigger signal for turning on the bidirectional switching element over a predetermined period of time during which the bidirectional switching element is conducted.
  The power conversion circuit has a power factor improvement function of the AC power supply,
The bleeder circuit generates the bypass current only when the voltage input to the power conversion circuit is lower than a threshold, and generates the bypass current within the predetermined period in which the trigger signal is continuously supplied. Start
  A lighting system characterized by that. A light source composed of a light emitting element, a power conversion circuit that supplies lighting power to the light source using power supplied from an AC power source, and a bypass current that is connected in parallel to the power conversion circuit and that uses the AC power source as a supply source A lighting load comprising a bleeder circuit to
  A bidirectional switching element connected in series to a series circuit of the power conversion circuit and an AC power supply and having a self-holding function;
  A dimming control unit that performs phase control to change the conduction angle of the AC voltage of the AC power supply by controlling the bidirectional switching element;
  The dimming control unit continuously supplies a trigger signal for turning on the bidirectional switching element over a predetermined period of time during which the bidirectional switching element is conducted.
  The power conversion circuit has a power factor improvement function of the AC power supply,
The bleeder circuit generates the bypass current only when the voltage input to the power conversion circuit is lower than a threshold, and after the predetermined period in which the trigger signal is continuously supplied ends, Start generation
  A lighting system characterized by that.

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