JP5854319B2 - Lighting power supply and lighting device - Google Patents

Description

  Embodiments described herein relate generally to a lighting power source and a lighting device.

2. Description of the Related Art In recent years, in illumination devices, replacement of incandescent bulbs and fluorescent lamps with light-saving, long-life light sources such as light-emitting diodes (LEDs) has been progressing. In addition, new illumination light sources such as EL (Electro-Luminescence) and organic light-emitting diode (OLED) have been developed. Since the light output of these illumination light sources depends on the value of the flowing current, a power supply circuit that supplies a constant current is required when lighting the illumination. In addition, when dimming, the supplied current is controlled.
Two-wire dimmers are configured to control the phase at which the triac turns on, and are popular as dimmers for incandescent bulbs. Therefore, it is desirable that illumination light sources such as LEDs can also be dimmed with this dimmer. Switching power supplies such as DC-DC converters are known as power supplies that are highly efficient and suitable for power saving and miniaturization.

JP2011-119237A

However, this dimmer is configured to operate in series with a filament of an incandescent bulb serving as a load, and when a switching power supply is connected, the load impedance may change and malfunction.
An object of an embodiment of the present invention is to provide a lighting power source and a lighting device in which a variable range of an output current is widened.

The lighting power source according to the embodiment is connected between the power source and the lighting load, and performs a switching operation that repeats an on state and an off state when a potential difference between the power source and the lighting load is a predetermined value or more. And an output element that remains on when the potential difference between the power source and the lighting load is smaller than a predetermined value, and a constant that is connected in series with the output element and limits the current flowing through the output element. A current element; an inductor connected in series between the constant current element and the lighting load; and a rectifying element connected in parallel to the inductor and the lighting load. The output element can pass a direct current limited by the constant current element when the output element continues to be on.

  According to the embodiment of the present invention, it is possible to provide a lighting power source and a lighting device that have a wide variable range of output current.

It is a block diagram which illustrates the illuminating device containing the power supply for illumination which concerns on 1st Embodiment. FIG. 5 is a characteristic diagram illustrating the relationship between an output voltage VOUT supplied to a lighting load and an output current IOUT. It is a wave form diagram which illustrates the current waveform of an output element. It is a circuit diagram which illustrates the illuminating device containing the power supply for illumination which concerns on 2nd Embodiment. It is a circuit diagram which illustrates a dimmer. It is a wave form diagram showing the main signals of the power supply for illumination. It is a circuit diagram which illustrates the illuminating device containing the power supply for illumination which concerns on 3rd Embodiment. It is a wave form diagram showing the main signals of the power supply for illumination concerning a 3rd embodiment. FIG. 6 is a characteristic diagram illustrating the relationship between the dimming phase angle and the output current IOUT. It is a circuit diagram which illustrates the illuminating device containing the power supply for illumination which concerns on 4th Embodiment.

  Hereinafter, embodiments will be described in detail with reference to the drawings. Note that, in the present specification and each drawing, the same elements as those described above with reference to the previous drawings are denoted by the same reference numerals, and detailed description thereof is omitted as appropriate.

First, the first embodiment will be described.
FIG. 1 is a block diagram illustrating a lighting device including a lighting power source according to the first embodiment.
As illustrated in FIG. 1, the lighting device 1 includes a lighting load 2 and a lighting power source 3 that supplies power to the lighting load 2.

  The illumination load 2 has an illumination light source 4 such as an LED, for example, and is lit by being supplied with an output voltage VOUT and an output current IOUT from the illumination power supply 3. The lighting load 2 can be dimmed by changing at least one of the output voltage VOUT and the output current IOUT. Note that the values of the output voltage VOUT and the output current IOUT are defined according to the illumination light source.

FIG. 2 is a characteristic diagram illustrating the relationship between the output voltage VOUT supplied to the lighting load and the output current IOUT.
In FIG. 2, the characteristic of the illumination load which has an illumination light source with small operation resistance at the time of lighting, such as LED, is illustrated.
When the output voltage VOUT is lower than the predetermined voltage, the illumination load 2 is not lit and is turned off. When the output voltage VOUT is equal to or higher than a predetermined voltage, a current flows and lights up.

  For example, when the illumination light source 4 is an LED, the predetermined voltage is a forward voltage of the LED and is determined according to the illumination light source 4. In addition, the illumination light source 4 has a low operating resistance when lit, and the output voltage VOUT hardly changes even if the output current IOUT increases near the rated operating point P, for example. Therefore, the illumination load 2 having the characteristics as shown in FIG. 2 can control light by controlling the light output of the illumination light source 4 by changing the output current IOUT. Further, when the output voltage VOUT is lower than the predetermined voltage, the illumination light source 4 is turned off and the output current IOUT does not flow. The

The illumination power supply 3 includes an output element 5, a constant current element 6 that is connected in series with the output element 5 and limits a current flowing through the output element 5, and a drive element 70 that drives the output element 5.
The output element 5 is connected between the illumination load 2 and the power source 7. The output element 5 performs a switching operation that repeats an ON state and an OFF state when a potential difference ΔV (= VIN−VOUT) between the voltage VIN of the power supply 7 and the output voltage VOUT output to the lighting load 2 is relatively large. When the potential difference ΔV between the power source 7 and the lighting load 2 is relatively small, the ON state is maintained.
The drive element 70 supplies a potential to the control terminal of the output element 5 to control the output element 5 to be in an on state or an off state.

FIG. 3 is a waveform diagram illustrating a current waveform of the output element.
3A to 3D schematically show waveforms of the current I5 of the output element 5 when the potential difference ΔV between the power source 7 and the illumination load 2 increases.

  As shown in FIG. 3A, when the potential difference ΔV is relatively small, the output element 5 continues to be in an ON state, and a substantially constant DC current limited by the constant current element 6 flows. In a state where the output element 5 outputs a constant DC current, the illumination power supply 3 operates like a series regulator.

  As shown in FIG. 3B, when the potential difference ΔV increases, the current oscillates while the output element 5 remains on. As shown in FIG. 3C, when the potential difference ΔV is further increased, the current fluctuation range of the output element 5 is increased according to the potential difference ΔV.

  As described above, when the potential difference ΔV increases, the output element 5 becomes in an incompletely oscillating state, for example, and the current of the output element 5 oscillates. However, when the potential difference ΔV is smaller than the predetermined value, the output element 5 is not turned off but continues to be turned on. The peak value of the oscillating current of the output element 5 is a value limited by the constant current value of the constant current element 6. Further, the vibration period T of the output element 5 changes according to the fluctuation range of the current.

  As shown in FIG. 3D, when the potential difference ΔV is equal to or greater than a predetermined value, the output element 5 oscillates by performing a switching operation that repeats an on state and an off state. At this time, the illumination power supply 3 operates as a switching power supply.

  The switching power supply is a power supply with low power consumption and high efficiency because the output element 5 performs a switching operation that repeats an ON state with low resistance and an OFF state in which no current flows. In this embodiment, when the potential difference ΔV is larger than a predetermined value, a switching operation is performed, and when the potential difference ΔV is small, an operation like a series regulator is performed. When the potential difference ΔV is large, the product of the potential difference ΔV and the current is large, and the loss increases when the series regulator is operated. Therefore, when the potential difference ΔV is large, the switching operation is suitable for low power consumption. When the potential difference ΔV is small, the loss is small, and there is no problem in operating as a series regulator.

  In the present embodiment, when the potential difference ΔV is smaller than the predetermined value, the output element 5 does not turn off, the current vibrates while continuing the on state, and the lighting load is determined by the average value of the current. 2 is turned on (FIGS. 3B and 3C). When the potential difference ΔV is even smaller, the output element 5 outputs a direct current to the lighting load 2 and keeps the light on while maintaining the ON state (FIG. 3A). As a result, in the present embodiment, the output current can be continuously changed to zero. Moreover, the illumination load 2 in the illumination device 1 can be turned off smoothly.

  Therefore, in the present embodiment, the output current IOUT ranges from the maximum value during the switching operation of the output element 5 to the minimum value when the DC current is output while the output element 5 is kept on in accordance with the potential difference ΔV. Can be changed continuously. Moreover, the illumination load 2 in the illuminating device 1 can be dimmed continuously in the range of 0 to 100%.

  In FIGS. 3A to 3C, the output element 5 does not enter the OFF state, the current vibrates while continuing the ON state, and the fluctuation range of the current increases as the potential difference ΔV increases. The operation is illustrated (FIGS. 3B and 3C). However, the output element 5 oscillates by performing a switching operation that repeats an ON state and an OFF state when the potential difference ΔV is greater than or equal to a predetermined value (FIG. 3D), and turns on when the potential difference ΔV is smaller than the predetermined value. An operation of outputting a direct current may be performed by continuing the above state (FIG. 3A). That is, the output element 5 does not have to perform an operation (FIGS. 3B and 3C) in which the current oscillates while continuing the ON state without being in the OFF state.

The output element 5 and the constant current element 6 are, for example, field effect transistors (FETs), for example, high electron mobility transistors (HEMTs).
In addition, when the output element 5 is in an off state, the output current IOUT may be supplied by, for example, a rectifying element.

  As described above, in this embodiment, the output element oscillates and outputs an oscillation current when the potential difference between the power supply and the lighting load is relatively large, and stops oscillation when the potential difference is relatively small. Output current. As a result, the variable range of the output current can be expanded. In addition, the light control range of the lighting device can be expanded.

FIG. 4 is a circuit diagram illustrating a lighting device including a lighting power source according to the second embodiment.
As shown in FIG. 4, the second embodiment has a dimmer 8, a rectifier circuit 9, and a constant current circuit 10 added to the illumination power supply 3 in comparison with the first embodiment, and an output element. And the point by which the structure of the DC-DC converter 11 which has a constant current element is illustrated is different. Moreover, the illuminating device 1a is provided with the illumination load 2 and the power supply 3a for illumination. The illumination load 2 is the same as in the first embodiment.

  The illumination power supply 3a includes a dimmer 8 that controls the phase of the AC power supply 7a, a rectifier circuit 9 that converts the phase-controlled AC voltage into direct current, and a constant current required for the dimmer 8 to control the phase. The current circuit 10 includes a DC-DC converter 11 that generates an output voltage VOUT. The AC power supply 7a is, for example, a commercial power supply.

The dimmer 8 is connected to the AC power supply 7a and is inserted in series into one of a pair of power supply lines that supply the power supply voltage VIN. Thus, the dimmer 8 may be inserted in series with a pair of power supply lines that supply the power supply voltage VIN.
FIG. 5 is a circuit diagram illustrating the dimmer.
As shown in FIG. 5, the dimmer 8 is a two-wire phase control dimmer.
The dimmer 8 includes a triac 12 inserted in series in the power supply line, a phase circuit 13 connected in parallel with the triac 12, and a diac 14 connected between the gate of the triac 12 and the phase circuit 13. Have.

The triac 12 is normally in an off state, and is turned on when a pulse signal is input to the gate. The triac 12 can pass a current in both directions when the AC power supply voltage VIN is positive and negative.
The phase circuit 13 includes a variable resistor 15 and a capacitor 16, and generates a voltage whose phase is delayed at both ends of the capacitor 16. Further, when the resistance value of the variable resistor 15 is changed, the time constant changes and the delay time changes.

The diac 14 generates a pulse voltage when the voltage charged in the capacitor of the phase circuit 13 exceeds a certain value, and turns on the triac 12.
The dimmer 8 can adjust the timing at which the triac 12 is turned on by changing the time constant of the phase circuit 13 and controlling the timing at which the diac 14 generates a pulse.

  Returning to FIG. 4 again, the rectifier circuit 9 inputs the AC power supply voltage VIN via the dimmer 8 and outputs the DC voltage VRE. The rectifier circuit 9 is configured by a diode bridge. The rectifier circuit 9 outputs a DC voltage VRE whose voltage changes according to the dimming degree by the dimmer 8. The rectifier circuit 9 only needs to rectify the AC voltage input from the dimmer 8 and may have another configuration. A capacitor for reducing noise generated in the DC-DC converter is connected to the input side of the rectifier circuit 9.

The constant current circuit 10 includes a transistor 17, a resistor 18 that biases the transistor 17, a Zener diode 19, a choke coil 20, and a diode 21.
The transistor 17 is, for example, an FET and is a normally-on type element. The drain of the transistor 17 is connected to the high potential terminal 9a of the rectifier circuit 9 via a choke coil, and the source of the transistor 17 is connected to the resistor 18 and the Zener diode 19 connected in parallel to each other. Connected to the low potential terminal 9b. The gate of the transistor 17 is connected to the low potential terminal 9 b of the rectifier circuit 9. The high potential terminal 9 a of the rectifier circuit 9 is connected to the DC-DC converter 11 via the diode 21.

The constant current circuit 10 is a circuit for supplying a constant current for operating the phase circuit 13 of the dimmer 8. By connecting an element whose impedance is smaller than that of the phase circuit 13 as a load of the rectifier circuit 9, the influence of the input impedance of the DC-DC converter 11 in the subsequent stage is suppressed, and the dimmer 8 is stably operated. Can do.
The smoothing capacitor 40 is connected between the cathode of the diode 21 of the constant current circuit 10 and the low potential terminal 9 b of the rectifier circuit 9.

The DC-DC converter 11 includes an output element 5a, a constant current element 6a, a rectifier element 22, an inductor 23, a feedback winding (drive element) 24 for driving the output element 5a, a coupling capacitor 25, split resistors 26 and 27, and an output capacitor. 28 and a bias resistor 29.
The output element 5a and the constant current element 6a are, for example, field effect transistors (FETs), such as high electron mobility transistors (HEMTs), and are normally-on type elements.

The drain of the output element 5 a is connected to the high potential terminal 9 a of the rectifier circuit 9 through the constant current circuit 10. The source of the output element 5 a is connected to the drain of the constant current element 6 a, and the gate of the output element 5 a is connected to one end of the feedback winding 24 via the coupling capacitor 25.
The source of the constant current element 6a is connected to one end of the inductor 23 and the other end of the feedback winding 24. The source potential of the constant current element 6a is divided by dividing resistors 26 and 27 at the gate of the constant current element 6a. A voltage is input.

The bias resistor 29 is connected between the drain of the output element 5a and the source of the constant current element 6a, and supplies a DC voltage to the dividing resistors 26 and 27. As a result, a potential lower than that of the source is supplied to the gate of the constant current element 6a.
The inductor 23 and the feedback winding 24 are magnetically coupled in such a polarity that a positive voltage is supplied to the gate of the output element 5a when an increasing current flows from one end of the inductor 23 to the other end.
A protection diode is connected to each of the gate of the output element 5a and the gate of the constant current element 6a.

The rectifier element 22 is connected between the source of the constant current element 6a and the low potential terminal 9b of the rectifier circuit 9 with the direction from the low potential terminal 9b to the constant current element 6a as the forward direction.
The other end of the inductor 23 is connected to the high potential output terminal 30, and the low potential terminal 9 b of the rectifier circuit 9 is connected to the low potential output terminal 31. The output capacitor 28 is connected between the high potential output terminal 30 and the low potential output terminal 31.

The illumination load 2 is connected in parallel with the output capacitor 28 between the high potential output terminal 30 and the low potential output terminal 31.
Next, the operation of the illumination power supply 3a will be described. Since the dimmer 8, the rectifier circuit 9, and the constant current circuit 10 have already been described, the operation of the DC-DC converter 11 will be mainly described.

  First, the case where the dimming degree of the dimmer 8 is set to approximately 100% and the input AC voltage is transmitted almost as it is, that is, the case where the highest DC voltage is input to the DC-DC converter 11 will be described.

  When the power supply voltage VIN is supplied to the illumination power supply 3a, the output element 5a and the constant current element 6a are normally-on elements, and therefore both are turned on. Then, current flows through the path of the output element 5a, the constant current element 6a, the inductor 23, and the output capacitor 28, and the output capacitor 28 is charged. The voltage across the output capacitor 28, that is, the voltage between the high potential output terminal 30 and the low potential output terminal 31 is supplied to the illumination light source 4 of the illumination load 2 as the output voltage VOUT of the illumination power supply 3a. Since the output element 5a and the constant current element 6a are on, a reverse voltage is applied to the rectifying element 22. No current flows through the rectifying element 22.

  When the output voltage VOUT reaches a predetermined voltage, the output current IOUT flows through the illumination light source 4 and the illumination light source 4 is turned on. At this time, a current flows through the path of the output element 5a, the constant current element 6a, the inductor 23, the output capacitor 28, and the illumination light source 4. For example, when the illumination light source 4 is an LED, the predetermined voltage is a forward voltage of the LED and is determined according to the illumination light source 4. Further, when the illumination light source 4 is turned off, the output current IOUT does not flow, so the output capacitor 28 holds the value of the output voltage VOUT.

  Since the DC voltage input to the DC-DC converter 11 is sufficiently higher than the output voltage VOUT, that is, the potential difference ΔV between the input and output is sufficiently large, the current flowing through the inductor 23 increases. Since the feedback winding 24 is magnetically coupled to the inductor 23, an electromotive force having a polarity with a high potential on the coupling capacitor 25 side is induced in the feedback winding 24. Therefore, a positive potential is supplied to the gate of the output element 5a with respect to the source via the coupling capacitor 25, and the output element 5a is kept on.

  When the current flowing through the constant current element 6a composed of the FET exceeds the upper limit value, the drain-source voltage of the constant current element 6a rapidly increases. Therefore, the gate-source voltage of the output element 5a becomes lower than the threshold voltage, and the output element 5a is turned off. The upper limit value is the saturation current value of the constant current element 6a, and is defined by the potential input from the dividing resistors 26 and 27 to the gate of the constant current element 6a. As described above, since the gate potential of the constant current element 6a is negative with respect to the source, the saturation current value can be limited to an appropriate value.

  The inductor 23 continues to pass current through the path of the rectifying element 22, the output capacitor 28, the illumination load 2, and the inductor 23. At this time, since the inductor 23 releases energy, the current of the inductor 23 decreases. Therefore, an electromotive force having a polarity that causes the coupling capacitor 25 side to have a low potential is induced in the feedback winding 24. A negative potential is supplied to the gate of the output element 5a with respect to the source via the coupling capacitor 25, and the output element 5a maintains the OFF state.

  When the energy stored in the inductor 23 becomes zero, the current flowing through the inductor 23 becomes zero. The direction of the electromotive force induced in the feedback winding 24 is reversed again, and an electromotive force that induces a high potential on the coupling capacitor 25 side is induced. As a result, a higher potential than the source is supplied to the gate of the output element 5a, and the output element 5a is turned on. As a result, the output voltage VOUT returns to the predetermined voltage.

  Thereafter, the above operation is repeated. Thereby, switching of the output element 5a to ON and OFF is automatically repeated, and the illumination light source 4 is supplied with the output voltage VOUT that is a drop in the power supply voltage VIN. The current supplied to the illumination light source 4 is a constant current whose upper limit is limited by the constant current element 6a. Therefore, the illumination light source 4 can be lighted stably.

  Even when the dimming degree of the dimmer 8 is set to a value smaller than 100% and the input AC voltage is phase-controlled and transmitted, that is, when a high DC voltage is input to the DC-DC converter 11. When the output element 5a can continue to oscillate, it is the same as described above. Depending on the dimming degree of the dimmer 8, the value of the DC voltage input to the DC-DC converter 11 changes, and the average value of the output current IOUT can be controlled. Therefore, the illumination light source 4 of the illumination load 2 can be dimmed according to the dimming degree.

  In addition, when the dimming degree of the dimmer 8 is set to a smaller value, that is, when the DC voltage input to the DC-DC converter 11 is lower, the potential difference between both ends of the inductor 23 even when the output element 5a is turned on. Therefore, the current flowing through the inductor 23 cannot be increased. Therefore, the output element 5a is not turned off and outputs a constant direct current.

FIG. 6 is a waveform diagram showing main signals of the power supply for illumination.
6, in the order of FIGS. 6A to 6H, when the dimming degree of the dimmer 8 decreases, the DC voltage VRE of the rectifier circuit 9, the output current IOUT of the illumination power supply 3a, the rectifier element 22 Represents the measured value of the voltage VD.

  As shown in FIGS. 6A to 6C, when the dimming degree is large, the output element 5a oscillates by switching between the ON state and the OFF state, and the voltage VD of the rectifying element 22 is oscillated. It becomes a waveform. Since the control according to the dimming degree of the dimmer 8 is not performed, the output current IOUT is substantially constant.

  As shown in FIGS. 6D to 6F, when the dimming degree decreases, the output element 5a continues to be on due to the ripple of the voltage input to the DC-DC converter 11, and the on state. And a period of stopping the switching operation that repeats the OFF state occurs. Since the average value of the current I5 of the output element 5 changes according to the dimming degree, the average value of the output current IOUT changes according to the dimming degree.

  As shown in FIGS. 6G and 6H, when the dimming degree further decreases, the output element 5a continues to be in an ON state, and the DC current I5 flows. Therefore, the voltage VD of the rectifying element 22 is the DC voltage. become. Since the value of the direct current I5 changes according to the dimming degree, the output current IOUT changes according to the dimming degree.

  As described above, in this embodiment, the normally-on output element oscillates by repeating the switching operation between the ON state and the OFF state according to the dimming degree of the dimmer, or the ON state is changed. Continue to output DC current. As a result, the output current can be continuously changed from the maximum value to zero. Moreover, the illumination load in the illumination device can be turned off smoothly.

FIG. 7 is a circuit diagram illustrating a lighting device including a lighting power source according to the third embodiment.
As shown in FIG. 7, the third embodiment is different from the second embodiment in the configuration for generating the gate potential of the constant current element 6 a in the DC-DC converter 11. In other words, resistors 52, 53, and 56, a capacitor 54, and a diode 58 are added to the illumination power supply 3b. The configurations of the dimmer 8, the rectifier circuit 9, the constant current circuit 10a, and the DC-DC converter 11 are the same as those in the second embodiment.

  The resistors 52 and 53 are connected in series between the anode of the diode 21 of the constant current circuit 10 and the low potential terminal 9 b of the rectifier circuit 9. The capacitor 54 is connected in parallel with the resistor 53. The voltage of the resistor 53 is supplied to the connection point of the divided resistors 26 and 27 via the diode 58 and the resistor 56. The resistor 52 and the capacitor 54 constitute a low-pass filter or an integrating circuit, and the resistor 53 generates a voltage obtained by smoothing the DC voltage VRE of the rectifier circuit 9.

  Since the voltage of the resistor 53 changes according to the dimming degree of the dimmer 8, the gate potential of the constant current element 6a can be changed according to the dimming degree.

FIG. 8 is a waveform diagram showing main signals of the illumination power source according to the third embodiment.
In FIG. 8, in the order of FIGS. 8A to 8H, when the dimming degree of the dimmer 8 increases, the DC voltage VRE of the rectifier circuit 9, the output current IOUT of the illumination power supply 3b, the rectifier element 22 Represents the measured value of the voltage VD.

As shown in FIG. 8A, when the dimming degree is 0%, that is, when the dimming phase angle is 180 degrees, the output voltage IOUT does not flow because the DC voltage VRE of the rectifier circuit 9 is zero.
As shown in FIGS. 8B and 8C, when the dimming degree increases, that is, when the dimming phase angle decreases, the DC voltage VRE of the rectifier circuit 9 increases, and the output element 5a continues to be in the ON state. In this state, the current I5 vibrates, and the voltage VD of the rectifying element 22 vibrates. Depending on the dimming degree, the fluctuation range of the current I5 increases, and the fluctuation range of the voltage VD of the rectifying element 22 increases. Therefore, the output current IOUT increases as the dimming degree increases. Since the output element 5a is not turned off, the voltage VD of the rectifying element 22 does not become zero.

  As shown in FIGS. 8D to 8H, when the dimming degree is further increased, the output element 5a oscillates by performing a switching operation that repeats an on state and an off state. The fluctuation range of the voltage of the rectifying element 22 increases and decreases to almost zero. The output current IOUT increases as the dimming degree increases.

  As described above, in this specific example, the output element 5a performs a switching operation that repeats the on state and the off state in which the output element 5a continuously vibrates without being turned off according to the dimming degree. And continuously transition between the oscillating state. As a result, the amplitude of the oscillation current I5 continuously changes according to the dimming degree, and the output current IOUT continuously changes according to the dimming degree.

FIG. 9 is a characteristic diagram illustrating the relationship between the dimming phase angle and the output current IOUT.
As shown in FIG. 9, in this specific example, the output current IOUT can be continuously controlled to zero according to the dimming phase angle (the dimming degree).
Thus, in this embodiment, the state of an output element changes continuously according to the light control degree of a light control device. As a result, the output current can be continuously changed, and the variable range of the dimming degree of the dimmer can be expanded. In addition, the lighting device can be dimmed continuously, and the dimming range can be expanded.

FIG. 10 is a circuit diagram illustrating a lighting device including a lighting power source according to the fourth embodiment.
As shown in FIG. 10, the fourth embodiment is different in the configurations of the constant current circuit 10 and the DC-DC converter 11 from the third embodiment. That is, the illumination power supply 3c includes a dimmer 8, a rectifier circuit 9, a constant current circuit 10a, and a DC-DC converter 11a. The dimmer 8 and the rectifier circuit 9 are the same as in the third embodiment. Moreover, the illuminating device 1c is provided with the illumination load 2 and the power supply 3c for illumination. The illumination load 2 is the same as in the first embodiment.

  The constant current circuit 10a is different from the constant current circuit 10 in the second embodiment in that the transistor 17 is a normally-off element and the configuration of a bias circuit for supplying a constant current. That is, the constant current circuit 10a includes a transistor 17a, resistors 18 and 32 that bias the transistor 17a, a Zener diode 19, a choke coil 20, and a diode 21.

  The transistor 17a is, for example, an FET and is a normally-off type element. The drain of the transistor 17a is connected to the high potential terminal 9a of the rectifier circuit 9 via the choke coil 20, and the source of the transistor 17a is connected to the low potential terminal 9b of the rectifier circuit 9 via the resistor 18. The gate of the transistor 17 a is connected to the cathode of the diode 21 through the bias resistor 32, and is connected to the low potential terminal 9 b of the rectifier circuit 9 through the Zener diode 19. The high potential terminal 9a of the rectifier circuit 9 is connected to the anode of the diode 21, and the cathode of the diode 21 is connected to the DC-DC converter 11a. A smoothing capacitor 40 is connected between the cathode of the diode 21 and the low potential terminal 9 b of the rectifier circuit 9.

  The transistor 17 a is biased by the bias resistor 32 and the Zener diode 19, and passes a constant current that operates the phase circuit 13 of the dimmer 8. Therefore, like the constant current circuit 10, the constant current circuit 10 a is connected to an element having a smaller impedance than the phase circuit 13 as a load of the rectifier circuit 9, so The dimmer 8 can be stably operated while suppressing the influence.

The DC-DC converter 11a is different from the DC-DC converter 11 in the second embodiment in that both the output element 5a and the constant current element 6a are normally-off elements, and as a result, the inductor 23 and the like. Configurations such as the position of are different.
The DC-DC converter 11a includes an output element 5b, a constant current element 6b, a rectifier element 22, an inductor 23, a feedback winding (drive element) 24 for driving the output element 5b, a coupling capacitor 25, an output capacitor 28, a bias resistor 29, Resistors 33 to 37 are provided.
The output element 5b and the constant current element 6b are, for example, field effect transistors (FETs), for example, high electron mobility transistors (HEMTs).

The drain of the output element 5b is connected to the cathode of the diode 21 of the constant current circuit 10a via the rectifying element 22 in the reverse direction. The source of the output element 5 b is connected to the constant current element 6 b, and the gate of the output element 5 b is connected to one end of the feedback winding 24. The other end of the feedback winding 24 is connected to the low potential terminal 9 b of the rectifier circuit 9 via the coupling capacitor 25.
The bias resistor 29 is connected between the cathode of the diode 21 and the gate of the output element 5b, and the resistor 33 is connected between the gate of the output element 5b and the low potential terminal 9b of the rectifier circuit 9. A protective diode is connected to the gate of the output element 5b.

The constant current element 6b is composed of a current mirror, the drain of the output side transistor is connected to the source of the output element 5b, the source is connected to the low potential terminal 9b of the rectifier circuit 9 via the resistor 34, and the gate Are connected to the gate and drain of the reference transistor. The source of the reference side transistor is connected to the low potential terminal 9 b of the rectifier circuit 9 through the resistor 35, and the drain and gate are connected to the anode of the diode 21 through the resistors 36 and 37. The resistor 37 is connected to the low potential terminal 9 b of the rectifier circuit 9 through the capacitor 54. The resistor 37 and the capacitor 54 constitute a low-pass filter or an integration circuit. A zener diode 58 is connected in parallel with the capacitor 54 via a resistor 56.
A current that changes in accordance with the dimming degree flows through the resistor 36 to the reference-side transistor of the constant current element 6b. Therefore, a current that changes in accordance with the dimming level flows through the output-side transistor of the constant current element 6b.

  The inductor 23 is connected between the drain of the output element 5 b and the low potential output terminal 31. The inductor 23 and the feedback winding 24 are magnetically coupled in such a polarity that a positive voltage is supplied to the gate of the output element 5b when an increasing current flows from one end of the inductor 23 to the other end.

  The output capacitor 28 is connected between the high potential output terminal 30 and the low potential output terminal 31. The high potential output terminal 30 is connected to the cathode of the diode 21 of the constant current circuit 10a.

The illumination load 2 is connected in parallel with the output capacitor 28 between the high potential output terminal 30 and the low potential output terminal 31.
Compared with the DC-DC converter 11, the operation of the DC-DC converter 11a is such that the output element 5a and the constant current element 6a are on the low potential side, and the rectifier element 22, the output capacitor 28, and the illumination load 2 are on the high potential side. The points are the same except that the respective elements are moved and the output element 5a and the constant current element 6a are replaced with normally-off elements.

  Therefore, in the present embodiment, the normally-off output element oscillates by repeating the switching operation between the ON state and the OFF state according to the dimming degree of the dimmer, or remains in the ON state. Outputs output current. That is, similarly to the output element in the third embodiment, the operation state continuously changes according to the dimming degree of the dimmer. As a result, the same effect as that of the third embodiment can be obtained.

  As described above, the embodiments have been described with reference to specific examples. However, the embodiments are not limited thereto, and various modifications are possible.

  For example, the output elements 5, 5a, 5b and the constant current elements 6, 6a, 6b are not limited to GaN-based HEMTs. For example, a semiconductor element formed using a semiconductor (wide band gap semiconductor) having a wide band gap such as silicon carbide (SiC), gallium nitride (GaN), or diamond on the semiconductor substrate may be used. Here, the wide band gap semiconductor means a semiconductor having a wider band gap than gallium arsenide (GaAs) having a band gap of about 1.4 eV. For example, a semiconductor having a band gap of 1.5 eV or more, gallium phosphide (GaP, band gap about 2.3 eV), gallium nitride (GaN, band gap about 3.4 eV), diamond (C, band gap about 5.27 eV) , Aluminum nitride (AlN, band gap of about 5.9 eV), silicon carbide (SiC), and the like. Such a wide band gap semiconductor element can be made smaller than a silicon semiconductor element when the breakdown voltage is made equal, so that the parasitic capacitance is small and high speed operation is possible, so that the switching cycle can be shortened, and the winding parts and Capacitors can be miniaturized.

  The illumination light source 4 is not limited to an LED, and may be an EL or an OLED. A plurality of illumination light sources 4 may be connected to the illumination load 2 in series or in parallel.

  Although several embodiments and examples of the present invention have been described, these embodiments or examples are presented as examples and are not intended to limit the scope of the invention. These novel embodiments or examples can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments or examples and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1, 1a, 1b ... Illuminating device, 2 ... Illumination load, 3, 3a, 3b ... Power supply for illumination, 4 ... Illumination light source, 5, 5a, 5b ... Output element 6, 6a, 6b ... Constant current element, 7 ... Power supply, 7a ... AC power supply, 8 ... Dimmer, 9 ... Rectifier circuit, 9a ... High potential terminal, 9b ... Low potential terminal, 10, 10a ... Constant current circuit, 11, 11a ... DC-DC converter, 12 ... Triac , 13 ... Phase circuit, 14 ... Diac, 15 ... Variable resistance, 16 ... Capacitor, 17, 17a ... Transistor, 18, 33-37 ... Resistance, 19 ... Zener diode, 20 ... Choke coil, 21 ... Diode, 22 ... Rectification Elements 23 ... Inductors 24 ... Feedback windings 25 ... Coupling capacitors 26, 27 ... Split resistors 28 ... Output capacitors 29, 32 ... Bi Scan resistance, 30 ... high-potential output terminal, 31 ... low-potential output terminal

Claims (7)

A switching operation that is connected between a power source and a lighting load, and repeats an on state and an off state when a potential difference between the power source and the lighting load is greater than or equal to a predetermined value; An output element that remains on when the potential difference between is less than a predetermined value;
A constant current element connected in series with the output element and restricting a current flowing through the output element;
An inductor connected in series between the constant current element and the lighting load;
A rectifying element connected in parallel to the inductor and the lighting load;
Equipped with a,
The output power supply is an illumination power source capable of flowing a direct current limited by the constant current element when the output element is kept on . 2. The illumination power supply according to claim 1, wherein a current flowing through the output element vibrates with a fluctuation range corresponding to a magnitude of a potential difference between the power supply and the illumination load, and the fluctuation range is larger as the potential difference is larger . The illumination power supply according to claim 1 or 2, wherein when the potential difference between the power supply and the illumination load is smaller than the predetermined value, the output element continues to be on and outputs a direct current.   The illumination power supply according to any one of claims 1 to 3, further comprising a phase control circuit that controls a timing at which the AC voltage is conducted.   The power supply for illumination according to any one of claims 1 to 4, wherein the output element is a normally-on type element.   The illumination power supply according to claim 1, wherein the output element is a normally-off element that is supplied with an output voltage and biased to an on state. Lighting load,
The power supply for illumination according to any one of claims 1 to 6, wherein power is supplied to the illumination load.
A lighting device comprising: