JP4975083B2 - Light source lighting device and lighting device - Google Patents

Description

  The present invention relates to a light source lighting device and a lighting device for lighting an LED (light emitting diode), for example.

If the LED is lit by connecting a voltage source directly to the LED, an excessive current corresponding to the voltage-current characteristic flows through the LED, which may break the LED.
Therefore, in order to limit the current flowing through the LED, a current limiting element such as a resistor or a transistor is connected in series with the LED.
However, in such a system, power loss due to the current limiting element is large (low efficiency), and heat is generated in the current limiting element, so that an LED lighting apparatus using a high-power LED or a high-intensity LED that is becoming mainstream in recent years Not suitable for.

Patent Document 1 proposes an LED lighting device using a switching power supply (step-down chopper circuit) that has a smaller power loss than a resistor or a transistor.
The LED lighting device described in Patent Document 1 includes a step-down chopper circuit having a switching element, an inductor, and a free wheel diode. This circuit stores energy in the inductor when the switching element is turned on and simultaneously supplies energy to the load side (LED). When the switching element is turned off, the energy stored in the inductor is released to the load side via the return diode. Is done. The switching element is repeatedly turned on and off at high speed in order to supply current to the LED.
Since the energy loss in the inductor is very small, a highly efficient LED lighting device can be obtained by this method.

Moreover, the feedback control which detects the LED current which flows into LED by LED current detection resistance connected in series with LED, and adjusts the ON time of a switching element according to the detected LED current is performed. Since the LED current can be controlled by feedback control, dimming lighting for adjusting the brightness of the LED can be easily achieved.
Usually, the LED current detection resistor is connected between the cathode side of the LED and the ground (reference potential). By making the reference potentials of the current detection circuit and the current control circuit the same, it is possible to easily detect the voltage applied to the LED current detection resistor as a voltage corresponding to the LED current.

However, even if an overcurrent flows through the step-down chopper circuit for some reason, the LED current is smoothed by a smoothing capacitor provided at the output terminal of the step-down chopper circuit. It cannot be detected instantaneously.
Therefore, a switching current detection resistor that detects a current flowing through the switching element of the step-down chopper circuit may be provided. When an overcurrent is detected by the switching current detection resistor, the switching element of the step-down chopper circuit is instantaneously turned off.

When a transistor is used as the switching element, the switching current detection resistor is connected to the emitter terminal, and when a MOS-FET is used as the switching element, the switching current detection resistor is connected to the source terminal.
However, when a switching current detection resistor is connected to the emitter terminal or the source terminal of the switching element, the reference potentials of the current detection circuit and the current control circuit are different, so the signal obtained by the switching current detection circuit is used with a photocoupler, etc. Must be transmitted to the current control circuit.
Therefore, the circuit size and cost of the LED lighting device are increased.

JP 2008-52994 A

  The present invention has been made, for example, in order to solve the above-described problems. With a simple circuit configuration, the feedback control of the LED current is appropriately performed, and the switching element is detected by instantaneously detecting the overcurrent. The purpose is to be able to turn off.

The light source lighting device of the present invention is
A DC power circuit that converts AC voltage from the AC power source into DC voltage;
A step-down chopper circuit having a switching element and stepping down a DC voltage from the DC power supply circuit to a DC voltage corresponding to an ON time of the switching element;
A light source is attached, and a light source unit that turns on the light source with a DC voltage stepped down by the step-down chopper circuit;
A light source current detection resistor connected in series with the light source attached to the light source unit;
A differential amplifier for detecting a voltage difference between both ends of the light source current detection resistor;
A switching element control circuit that adjusts an ON time of the switching element of the step-down chopper circuit according to a voltage difference detected by the differential amplifier.

  According to the present invention, for example, without using a photocoupler or the like, it is possible to appropriately perform feedback control of the LED current and instantaneously detect an overcurrent to turn off the switching element.

FIG. 3 is a circuit diagram illustrating an LED lighting device 41 of the lighting device according to the first embodiment. FIG. 6 is a circuit diagram illustrating an LED lighting device 41 of the lighting device according to the second embodiment. FIG. 6 is a circuit diagram illustrating an LED lighting device 41 of the lighting device according to Embodiment 3. FIG. 6 is a side sectional view of lighting device 40 according to Embodiment 4.

Embodiment 1 FIG.
An LED lighting device that performs feedback control of the LED current to dimm the LED and detects the overcurrent instantaneously to control the current will be described.

FIG. 1 is a circuit diagram illustrating an LED lighting device 41 of the lighting device according to the first embodiment.
The LED lighting device 41 of the lighting device in the first embodiment will be described below with reference to FIG.

  The LED lighting device 41 is supplied with electric power from the commercial AC power supply 1 and lights an LED unit (hereinafter referred to as “LED 11”) in which a plurality of LEDs are connected in series with a specific brightness. The specific brightness is designated by an operating device (for example, a dimming switch or a remote controller) that operates the lighting device. Hereinafter, the specific brightness designated by the operating device of the lighting device is referred to as “target illuminance”.

The LED is an example of a light source, and other light sources may be used instead of the LED or together with the LED. For example, organic EL (electroluminescence) may be used as the light source. The LED 11 and the organic EL are light sources whose brightness changes according to the magnitude of current.
Hereinafter, the current flowing through the LED 11 is referred to as “LED current”.

First, the configuration of the LED lighting device 41 will be described.
The LED lighting device 41 includes a rectifier circuit 2, a step-up chopper circuit 31, a first switching element control circuit 33, a step-down chopper circuit 32, a drive circuit 18, a light source unit 34, an LED current detection resistor 12, a differential amplifier 14, and an error amplifier 15. , A dimming controller 16, a diode 37, a switching current detection resistor 13, and a second switching element control circuit 17. The LED 11 is attached to the light source unit 34.

The rectifier circuit 2 is connected to the commercial AC power supply 1 on the input side, and is connected to the boost chopper circuit 31 on the output side.
The rectifier circuit 2 performs full-wave rectification on the AC voltage supplied from the commercial AC power supply 1. The AC voltage supplied from the commercial AC power supply 1 is converted into a DC voltage (pulsation voltage) by full-wave rectification.
For example, a diode bridge is used as the rectifier circuit 2.

The step-up chopper circuit 31 is connected to the rectifier circuit 2 on the input side, and is connected to the step-down chopper circuit 32 on the output side.
The step-up chopper circuit 31 boosts and smoothes the DC voltage that has been full-wave rectified by the rectifier circuit 2, and supplies the boosted and smoothed DC voltage to the step-down chopper circuit 32.

The step-up chopper circuit 31 includes a first inductor 3, a first switching element 4, a diode 5, and a first smoothing capacitor 6.
The first switching element 4 is switched on (on) / off (off) by a first switching element control circuit 33 ("control IC" in FIG. 1).
The first inductor 3 stores the DC voltage (current) from the rectifier circuit 2 as energy when the first switching element 4 is on, and the step-down chopper circuit 32 and the stored energy when the first switching element 4 is off. The first smoothing capacitor 6 is supplied.
The first smoothing capacitor 6 stores the DC voltage from the rectifier circuit 2 and the first inductor 3 as energy when the first switching element 4 is OFF, and supplies the stored energy to the step-down chopper circuit 32.
The diode 5 allows a direct current from the first inductor 3 to flow to the first smoothing capacitor 6 when the first switching element 4 is off.

  The DC voltage from the rectifier circuit 2 is boosted according to the duty ratio (ratio of on-time) of the first switching element 4 and smoothed by the first smoothing capacitor 6.

  The rectifier circuit 2 and the step-up chopper circuit 31 constitute a DC power supply circuit that supplies a DC voltage. Thus, the power factor of the LED lighting device 41 can be improved by combining the rectifier circuit 2 and the step-up chopper circuit 31 to form a DC power supply circuit. However, a DC power supply circuit may be configured other than the combination of the rectifier circuit 2 and the boost chopper circuit 31. For example, a capacitor input rectifier circuit may be used as the DC power supply circuit.

The first switching element control circuit 33 is connected to the first switching element 4 of the step-up chopper circuit 31 and switches on / off the switch of the first switching element 4.
For example, the first switching element control circuit 33 is configured by “IC (semiconductor integrated circuit)”, and the second switching element 7 is configured by “MOS-FET”. In this case, the first switching element control circuit 33 is connected to the gate terminal of the second switching element 7 and controls the voltage applied to the gate terminal to be connected to switch the second switching element 7 on / off. When the switch is on, a current flows between the drain and source of the MOS-FET, and when the switch is off, no current flows between the drain and source of the MOS-FET.
In FIG. 1, the first switching element control circuit 33 is referred to as “control IC”.

The step-down chopper circuit 32 is connected to the step-up chopper circuit 31 on the input side, and is connected to the LED 11 on the output side.
The step-down chopper circuit 32 steps down and smoothes the direct-current voltage boosted by the step-up chopper circuit 31 to a direct-current voltage having a specific magnitude, and supplies the step-down and smoothed direct-current voltage to the LED 11.

The step-down chopper circuit 32 includes a second switching element 7, a second inductor 8, a free wheel diode 9, and a second smoothing capacitor 10.
The second switching element 7 is switched on / off by the drive circuit 18.
The second inductor 8 stores the DC voltage from the step-up chopper circuit 31 as energy when the second switching element 7 is ON, and the LED 11 and the second smoothing capacitor 10 when the second switching element 7 is OFF. To supply.
The second smoothing capacitor 10 stores the DC voltage from the step-up chopper circuit 31 as energy when the second switching element 7 is on.
The freewheeling diode 9 secures a current path in the step-down chopper circuit 32 when the second switching element 7 is off. When the second switching element 7 is off, a current flows through the step-down chopper circuit 32 through a path of “second inductor 8 → second smoothing capacitor 10 → reflux diode 9 → second inductor 8”.

  The DC voltage from the step-up chopper circuit 31 is stepped down according to the duty ratio of the second switching element 7 and smoothed by the second smoothing capacitor 10. The smoothing of the DC voltage (DC current) in the second smoothing capacitor 10 reduces the ripple (magnitude of pulsation) of the LED current, and the LED current peak value (maximum pulsating value) is the maximum rated current of the LED 11. Overshooting can be suppressed.

The drive circuit 18 is connected to the second switching element control circuit 17 and the second switching element 7 of the step-down chopper circuit 32, and turns on / off the second switching element 7 according to the switching signal output from the second switching element control circuit 17. Switch.
For example, the drive circuit 18 is configured by a “pulse transformer”, and the second switching element 7 is configured by a “MOS-FET”. In this case, the drive circuit 18 is connected to the gate terminal of the second switching element 7 and transmits the switching signal from the second switching element control circuit 17 to the gate terminal of the second switching element 7. The second switching element 7 is switched on / off according to a switching signal from the second switching element control circuit 17.

The LED current detection resistor 12 is connected in series with the LED 11 on the cathode side of the LED 11.
The LED current detection resistor 12 is used to detect the LED current flowing through the LED 11.

The differential amplifier 14 is connected to both ends of the LED current detection resistor 12 at two input terminals, and is connected to the error amplifier 15 at an output terminal.
The differential amplifier 14 detects a voltage difference between both ends of the LED current detection resistor 12 as a voltage corresponding to the LED current, and amplifies the detected voltage difference. Hereinafter, the voltage difference detected and amplified by the differential amplifier 14 is referred to as “differential voltage”. The voltage at the output terminal of the differential amplifier 14 is a differential voltage.

By detecting the voltage corresponding to the LED current using the differential amplifier 14, the voltage drop of the switching current detection resistor 13 located downstream of the LED current detection resistor 12 (downstream side, low potential [ground] side) is included. Instead, only the voltage drop across the LED current detection resistor 12 can be detected. That is, by using the differential amplifier 14, the LED current can be accurately detected without being affected by the voltage drop of the switching current detection resistor 13.
On the other hand, when an error amplifier is used instead of the differential amplifier 14, the voltage between the cathode of the LED 11 and the ground terminal, that is, the voltage obtained by adding the drop voltage of the switching current detection resistor 13 to the drop voltage of the LED current detection resistor 12 is obtained. It is detected as a voltage corresponding to the LED current. Therefore, when an error amplifier is used instead of the differential amplifier 14, only the voltage drop of the LED current detection resistor 12 cannot be detected as a voltage corresponding to the LED current.

  The amplification factor of the differential amplifier 14 is determined by the ratio of the resistance values of the resistors constituting the differential amplifier 14. Each resistor constituting the differential amplifier 14 can be replaced from the outside. That is, the amplification factor of the differential amplifier 14 can be freely set by replacing each resistance of the differential amplifier 14. If the amplification factor of the differential amplifier 14 is appropriately set, a resistor having a small resistance value can be used as the LED current detection resistor 12, and power loss due to the LED current detection resistor 12 can be reduced.

The error amplifier 15 is connected to the output terminal of the differential amplifier 14 at one input terminal of the two input terminals and connected to the variable voltage device 19 at the other input terminal. The output terminal of the error amplifier 15 is connected to the second switching element control circuit 17 via the diode 37. The diode 37 is connected to the error amplifier 15 on the cathode side, and is connected to the second switching element control circuit 17 on the anode side.
The variable voltage device 19 is controlled by the dimming controller 16 (“dimming signal” in FIG. 1) and has a voltage of a specific magnitude. Hereinafter, the voltage of the variable voltage device 19 is referred to as “target voltage”.
The error amplifier 15 detects the voltage difference between the differential voltage of the differential amplifier 14 and the target voltage of the variable voltage device 19, and amplifies the detected voltage difference. Hereinafter, the voltage difference detected and amplified by the error amplifier 15 is referred to as “error voltage”. The voltage at the output terminal of the error amplifier 15 is an error voltage.

  The dimming controller 16 sets a predetermined voltage (target voltage) corresponding to the target illuminance of the LED 11 in the variable voltage device 19. The magnitude of the target voltage corresponds to the magnitude of the LED current (target LED current) for lighting the LED 11 with the target illuminance. It is assumed that the target voltage is predetermined in association with illuminance.

  The switching current detection resistor 13 is connected in series with the LED current detection resistor 12 on one end side, and is connected to the ground terminal on the other end side. That is, the switching current detection resistor 13 is connected in series with the second switching element 7 via the LED current detection resistor 12, the LED 11, and the step-down chopper circuit 32 on one end side, and is connected to the ground terminal on the other end side. The switching current detection resistor 13 is used to detect a current flowing through the second switching element 7. The switching current detection resistor 13 is located at one input end of the step-down chopper circuit 32, and the second switching element 7 is located at the other input end of the step-down chopper circuit 32. Hereinafter, the current flowing through the switching current detection resistor 13 is referred to as “switching current”.

  The second switching element control circuit 17 includes an output terminal of the error amplifier 15 (anode side of the diode 37), one end side of the switching current detection resistor 13 (between the switching current detection resistor 13 and the LED current detection resistor 12), a drive circuit. 18 and the ground terminal. The second switching element control circuit 17 detects a voltage applied to the switching current detection resistor 13 (a voltage on one end side of the switching current detection resistor 13) as a voltage corresponding to the switching current. Hereinafter, the voltage applied to the switching current detection resistor 13 is referred to as “switching voltage”.

Based on the error voltage of the error amplifier 15 and the switching voltage applied to the switching current detection resistor 13, the second switching element control circuit 17 drives the drive circuit 18 so that the difference between the actual LED current and the target LED current becomes small. The second switching element 7 is controlled via At this time, the second switching element control circuit 17 outputs a switching signal having a predetermined voltage to the drive circuit 18 in order to control the second switching element 7.
Accordingly, the second switching element control circuit 17 can bring the actual LED current closer to the target LED current and can light the LED 11 at approximately the target illuminance.

  Hereinafter, control of the second switching element 7 by the second switching element control circuit 17 will be described.

The differential voltage detected by the differential amplifier 14 increases as the LED current increases.
When the differential voltage detected by the differential amplifier 14 is larger than the target voltage of the variable voltage device 19, that is, when the actual LED current is larger than the target LED current, the error voltage detected by the error amplifier 15 decreases. It becomes.
When the differential voltage detected by the differential amplifier 14 is smaller than the target voltage of the variable voltage device 19, that is, when the actual LED current is smaller than the target LED current, the error voltage detected by the error amplifier 15 increases. It becomes.

When the error voltage decreases, the current that flows from the second switching element control circuit 17 to the error amplifier 15 increases. And the duty ratio of the 2nd switching element 7 becomes small, LED current becomes small, and the illumination intensity of LED11 becomes low.
When the error voltage increases, the current that flows from the second switching element control circuit 17 to the error amplifier 15 decreases. And the duty ratio of the 2nd switching element 7 becomes large, LED current becomes large, and the illumination intensity of LED11 becomes high.

  Further, the second switching element control circuit 17 controls the second switching element 7 as follows.

  The second switching element control circuit 17 relates to the error voltage detected by the error amplifier 15 when the magnitude of the switching voltage applied to the switching current detection resistor 13 exceeds a predetermined voltage (hereinafter referred to as “upper limit voltage”). First, the second switching element 7 is turned off via the drive circuit 18. “Turning off the second switching element 7” means stopping the on / off switching of the second switching element 7 with the second switching element 7 turned off.

Even if an overcurrent flows through the step-down chopper circuit 32 for some reason, the LED current is smoothed by the second smoothing capacitor 10, and therefore the overcurrent cannot be detected instantaneously by the LED current detection resistor 12.
However, the second switching element control circuit 17 detects the overcurrent instantaneously by detecting the switching current with the switching current detection resistor 13. Then, the second switching element control circuit 17 that has detected the overcurrent immediately turns off the second switching element 7. Thereby, the saturation of the 2nd inductor 8 by the overcurrent and the failure | damage of LED11 can be prevented.

  As described above, the switching current detection resistor 13 is in series with the second switching element 7 and one side is connected to the ground terminal. Therefore, the reference potential (ground) of the switching current detection resistor 13 and the second switching element control circuit 17 is equal, and the second switching element control circuit 17 can easily detect the switching current flowing through the second switching element 7. .

  The second switching element control circuit 17 is composed of, for example, an IC. In FIG. 1, the second switching element control circuit 17 is referred to as “control IC”.

Next, the function of the LED lighting device 41 will be described.
When the commercial AC power source 1 is turned on, the AC voltage supplied from the commercial AC power source 1 is rectified by the rectifier circuit 2, and a DC voltage is obtained by rectification. The DC voltage obtained by the rectification is boosted and smoothed by the boost chopper circuit 31.

The DC voltage boosted and smoothed by the boost chopper circuit 31 is stepped down by the step-down chopper circuit 32.
When the second switching element 7 of the step-up chopper circuit 31 is turned on, energy is stored in the second inductor 8 and the second smoothing capacitor 10 is charged via the second inductor 8. In addition, when the second switching element 7 is turned off, the energy stored in the second inductor 8 is released, and the current flows through the path “second inductor 8 → second smoothing capacitor 10 → freewheeling diode 9 → second inductor 8”. Flows. The second switching element 7 repeats the on / off operation under the control of the drive circuit 18.

The current flowing through the second switching element 7 (switching current) is detected by the switching current detection resistor 13, and the voltage corresponding to the current detected by the switching current detection resistor 13 is input to the second switching element control circuit 17 as a detection signal. The
When the detection signal value exceeds the threshold value (upper limit voltage), the second switching element control circuit 17 outputs a switch-off signal to the driving circuit 18 and the second switching element 7 connected to the driving circuit 18 is turned off.

A current (LED current) flowing through the LED 11 is detected by the LED current detection resistor 12, and a differential voltage corresponding to the current detected by the LED current detection resistor 12 is input to the differential amplifier 14 as a detection signal.
An LED current detection signal (differential voltage) detected by the LED current detection resistor 12 and the differential amplifier 14 is input to the error amplifier 15 and compared with a target LED current value set by the dimming controller 16. . An error signal (error voltage) corresponding to the difference between the LED current detection signal value and the target LED current value is output from the error amplifier 15 to the second switching element control circuit 17.

  The second switching element control circuit 17 performs feedback control according to the error signal as follows. By this feedback control, the difference between the LED current and the target LED current is reduced.

When the error signal indicates that the LED current is larger than the target LED current, the second switching element control circuit 17 outputs a predetermined switching signal A to the drive circuit 18, and the duty ratio of the second switching element 7 is reduced. And according to the duty ratio of the 2nd switching element 7, LED current becomes small.
When the error signal indicates that the LED current is smaller than the target LED current, the second switching element control circuit 17 outputs a predetermined switching signal B to the drive circuit 18 and the duty ratio of the second switching element 7 is increased. Then, the LED current increases in accordance with the duty ratio of the second switching element 7.

  The LED current detection resistor 12, the differential amplifier 14, the error amplifier 15, and the second switching element control circuit 17 are constant currents having a function (constant current function) of flowing a constant amount of LED current (target LED current) to the LED 11. A control circuit is configured.

In the first embodiment, the following LED lighting device 41 has been described.
The reference potential (ground) of the current control circuit (symbol “17”) and the current detection circuit (symbols “12” “13” “14” “15”) can be made common. The current flowing through the switching element (symbol “7”) and the current flowing through the LED 11 can be detected without using an insulating means such as a photocoupler. That is, since an insulating means such as a photocoupler is unnecessary, the LED lighting device 41 can be reduced in size.
Further, the magnitude of the LED current can be kept close to the target LED current by feedback control. For this reason, even if each LED has a lifetime or other characteristic variations, a substantially constant current can be supplied to each LED, and the lighting accuracy (dimming control accuracy) of the LED can be improved.
Further, since the switching current is detected, the switching element (symbol “7”) can be instantaneously turned off even if an overcurrent flows in the circuit (symbol “32”) for some reason.

Embodiment 2. FIG.
An LED lighting device that detects an overvoltage and controls the voltage will be described.
Hereinafter, items different from the first embodiment will be mainly described. Matters whose description is omitted are the same as those in the first embodiment.

FIG. 2 is a circuit diagram showing LED lighting device 41 of the lighting device according to the second embodiment.
The LED lighting device 41 of the illuminating device in Embodiment 2 is demonstrated below based on FIG.

First, the configuration of the LED lighting device 41 will be described.
The LED lighting device 41 includes a voltage dividing resistor 20a, a voltage dividing resistor 20b, a differential amplifier 21, an error amplifier 22, an OR circuit 23, and a transistor 35 in addition to the configuration of the first embodiment (see FIG. 1). In this embodiment, the diode 37 (see FIG. 1) is not necessary.
The voltage dividing resistor 20 a, the voltage dividing resistor 20 b, the differential amplifier 21, and the error amplifier 22 constitute an output voltage detection unit that detects a DC voltage stepped down by the step-down chopper circuit 32 (output voltage of the step-down chopper circuit 32).

  The voltage dividing resistor 20a and the voltage dividing resistor 20b are connected in series. The voltage dividing resistor 20 a and the voltage dividing resistor 20 b are connected in parallel with the LED 11 on the output side of the step-down chopper circuit 32. The voltage dividing resistor 20a is located on the anode side (upstream side, high potential side) of the LED 11, and the voltage dividing resistor 20b is located on the cathode side (downstream side, low potential side) of the LED 11. The voltage dividing resistor 20a and the voltage dividing resistor 20b are used to detect the output voltage of the step-down chopper circuit 32, that is, the voltage applied to the LED 11. Hereinafter, the voltage applied to the LED 11 that is the output voltage of the step-down chopper circuit 32 is referred to as “LED voltage”.

The differential amplifier 21 is connected to both ends of the voltage dividing resistor 20b at two input terminals, and is connected to the error amplifier 22 at an output terminal.
The differential amplifier 21 detects a voltage difference between both ends of the voltage dividing resistor 20b as a voltage corresponding to the LED voltage, and amplifies the detected voltage difference. Hereinafter, the voltage difference detected and amplified by the differential amplifier 21 is referred to as a “second differential voltage”. The voltage difference detected and amplified by the differential amplifier 14 is referred to as “first differential voltage”. The voltage at the output terminal of the differential amplifier 21 is the second differential voltage.

By detecting the LED voltage (second differential voltage) using the differential amplifier 21, the voltage drop across the switching current detection resistor 13 located downstream (downstream, low potential [ground] side) of the voltage dividing resistor 20b. Only the voltage drop of the voltage dividing resistor 20b can be detected. That is, by using the differential amplifier 21, it is possible to accurately detect the voltage corresponding to the LED voltage without being affected by the voltage drop of the switching current detection resistor 13.
On the other hand, when an error amplifier is used instead of the differential amplifier 21, a voltage between the voltage dividing resistor 20a and the ground terminal, that is, a voltage obtained by adding a voltage drop of the switching current detection resistor 13 to a voltage drop of the voltage dividing resistor 20b is obtained. It is detected as a voltage corresponding to the LED voltage. Therefore, when an error amplifier is used instead of the differential amplifier 21, only the voltage drop across the voltage dividing resistor 20b cannot be detected as a voltage corresponding to the LED voltage.

The error amplifier 22 is connected to the output terminal of the differential amplifier 21 at one input terminal of the two input terminals, and connected to the constant voltage source 24 at the other input terminal. The error amplifier 22 is connected to the OR circuit 23 at the output terminal.
The constant voltage source 24 supplies a voltage having a magnitude corresponding to a predetermined voltage (hereinafter referred to as “allowable output voltage”) as a voltage allowed in the step-down chopper circuit 32. Hereinafter, the voltage of the constant voltage source 24 is referred to as “reference voltage”. For example, a value higher than the product of the forward voltage per LED and the number of LEDs connected in series is set as the allowable output voltage.
The error amplifier 22 detects a voltage difference between the second differential voltage of the differential amplifier 21 and the reference voltage of the constant voltage source 24, and amplifies the detected voltage difference. Hereinafter, the voltage difference detected and amplified by the error amplifier 22 is referred to as “second error voltage”. The voltage difference detected and amplified by the error amplifier 15 is referred to as a “first error voltage”. The voltage at the output terminal of the error amplifier 22 is the second error voltage.

The second differential voltage detected by the differential amplifier 21 increases as the LED voltage increases.
When the second differential voltage detected by the differential amplifier 21 is larger than the reference voltage of the constant voltage source 24, that is, when the LED voltage is larger than the allowable output voltage, the second error voltage detected by the error amplifier 22 increases. To do.
When the second differential voltage detected by the differential amplifier 21 is smaller than the reference voltage of the constant voltage source 24, that is, when the LED voltage is smaller than the allowable output voltage, the second error voltage detected by the error amplifier 22 decreases. To do.

  The first error voltage of the error amplifier 15 increases if the LED current is larger than the target LED current, and decreases if the LED current is smaller than the target LED current.

The OR circuit 23 has one input terminal connected to the output terminal of the error amplifier 15 and the other input terminal connected to the output terminal of the error amplifier 22. The OR circuit 23 is connected to the base terminal of the transistor 35 at the output terminal.
In the OR circuit 23, the higher one of the first error voltage of the error amplifier 15 and the second error voltage of the error amplifier 22 is input to the base terminal of the transistor 35.

  The transistor 35 has a base terminal connected to the output terminal of the OR circuit 23, a collector terminal connected to the second switching element control circuit 17, and an emitter terminal connected to the ground terminal. Hereinafter, the terminal of the second switching element control circuit 17 connected to the collector terminal of the transistor 35 is referred to as “first input terminal”. A terminal of the second switching element control circuit 17 connected to the switching current detection resistor 13 is referred to as a “second input terminal”.

  The collector-emitter conducts in accordance with the magnitude of the base current input to the transistor 35, and current flows out from the second switching element control circuit 17. The duty ratio of the second switching element 7 is determined according to the flowing current. Here, it is assumed that the duty ratio of the second switching element 7 decreases as the flowing current increases.

That is, as the signal level input to the transistor 35 increases, the duty ratio of the second switching element 7 decreases and the LED current or LED voltage decreases.
Further, the duty ratio of the second switching element 7 increases as the signal level input to the transistor 35 decreases, and the LED current or LED voltage increases.
Since the LED reference voltage is set high, the output signal of the error amplifier 22 during normal lighting is small. Therefore, during normal lighting, the output signal of the error amplifier 15 is input to the transistor 35, and constant current control is performed.

Next, the function of the LED lighting device 41 will be described.
From the electrical characteristics of the LED, the forward voltage of the LED is a substantially constant value. Accordingly, the output voltage (LED voltage) of the step-down chopper circuit 32 during normal lighting is a substantially constant voltage, although it varies slightly depending on the value of the LED current.

Here, it is assumed that the LED 11 is broken due to some cause.
In this case, the output side of the step-down chopper circuit 32 is in an open state, and the LED current becomes zero. The second switching element control circuit 17 tries to increase the LED current by increasing the duty ratio of the second switching element 7 of the step-down chopper circuit 32 by the constant current control function (see the first embodiment). However, the LED current does not increase due to the disconnection failure of the LED 11, and the duty ratio of the second switching element 7 is increased to the maximum.
When the duty ratio of the second switching element 7 becomes maximum in the disconnected state, the output voltage of the step-up chopper circuit 31 is not stepped down by the step-down chopper circuit 32. Therefore, the voltage applied to the step-down chopper circuit 32 may rise to the output voltage of the step-up chopper circuit 31, that is, the voltage of the first smoothing capacitor 6. Since a high voltage is applied to the first smoothing capacitor 6 due to the step-up function of the step-up chopper circuit 31, if the voltage of the first smoothing capacitor 6 is applied to the step-down chopper circuit 32 without being stepped down, the second smoothing capacitor 10 and others Parts may be damaged.

  Therefore, the second switching element control circuit 17 determines the duty ratio of the second switching element 7 of the step-down chopper circuit 32 in order to lower the output voltage of the step-down chopper circuit 32 when the output voltage of the step-down chopper circuit 32 exceeds the reference voltage. Lower. This feedback control is constant voltage control that keeps the output voltage of the step-down chopper circuit 32 constant.

  That is, when the LED 11 is broken due to some cause, the feedback control of the second switching element control circuit 17 is switched from constant current control to constant voltage control. As a result, the voltage of the first smoothing capacitor 6 is stepped down in the step-down chopper circuit 32, and failure of the step-down chopper circuit 32 can be prevented.

In the second embodiment, the following LED lighting device 41 has been described.
During normal lighting, the LED 11 is lit at a current value determined by the dimming controller 16 by constant current operation. However, when the output voltage of the step-down chopper circuit 32 exceeds a predetermined voltage (allowable output voltage) due to disconnection of the LED 11 or the like, the output voltage of the step-down chopper circuit 32 is lowered by constant voltage operation, and a failure of the step-down chopper circuit 32 is caused. prevent.
That is, a substantially constant current is supplied to the LED 11 by a constant current feedback control (constant current control function) during normal times, and an abnormal increase in output voltage is prevented by a constant voltage feedback control (constant voltage control function) when an abnormality occurs.

  Further, by using the differential amplifier 21, the output voltage of the step-down chopper circuit 32 is accurately detected without being affected by the switching current detection resistor 13.

Embodiment 3 FIG.
An LED lighting device that stops supplying voltage when an overvoltage is detected will be described.
Hereinafter, items different from the first embodiment will be mainly described. Matters whose description is omitted are the same as those in the first embodiment.

FIG. 3 is a circuit diagram illustrating an LED lighting device 41 of the lighting device according to the third embodiment.
The LED lighting device 41 of the lighting device in the third embodiment will be described below with reference to FIG.

The LED lighting device 41 includes a voltage dividing resistor 20a, a voltage dividing resistor 20b, and a latch circuit 25 in addition to the configuration of the first embodiment (see FIG. 1).
The voltage dividing resistor 20a, the voltage dividing resistor 20b, and the latch circuit 25 constitute an output voltage detecting unit that detects a DC voltage stepped down by the step-down chopper circuit 32 (an output voltage of the step-down chopper circuit 32).

  The voltage dividing resistor 20 a and the voltage dividing resistor 20 b are connected in series as in the second embodiment, and are connected in parallel with the LED 11 on the output side of the step-down chopper circuit 32. The voltage dividing resistor 20a and the voltage dividing resistor 20b are used for detecting the LED voltage. The LED voltage is a voltage applied to the LED 11 and is an output voltage of the step-down chopper circuit 32.

The latch circuit 25 detects whether or not the LED voltage has become an overvoltage, and maintains the state in which the overvoltage is detected.
The latch circuit 25 outputs a high level signal to the second switching element control circuit 17 until the overvoltage is detected, and outputs a low level signal to the second switching element control circuit 17 after the overvoltage is detected.

  The latch circuit 25 includes a Zener diode 26 having a cathode terminal connected between the voltage dividing resistor 20a and the voltage dividing resistor 20b. The Zener diode 26 detects an overvoltage. Hereinafter, the voltage applied to the voltage dividing resistor 20b is referred to as “LED divided voltage” as a voltage corresponding to the LED voltage. The breakover voltage for passing a current from the cathode side to the anode side of the Zener diode 26 is an appropriate voltage that is larger than the LED divided voltage in the normal state and smaller than the LED divided voltage corresponding to the LED voltage that causes the step-down chopper circuit 32 to fail. It shall be. When the LED divided voltage exceeds the breakover voltage (when an overvoltage is detected), a current flows through the Zener diode 26 from the cathode side to the anode side.

The latch circuit 25 includes a first transistor 27 (NPN type) and a second transistor 28 (PNP type).
The first transistor 27 has a base terminal connected to the anode terminal of the Zener diode 26 and the collector terminal of the second transistor 28, and a collector terminal connected to the DC power source 36, the base terminal of the second transistor 28, and the second switching element control circuit 17. And the emitter terminal is connected to the ground terminal.
The second transistor 28 has a base terminal connected to the collector terminal of the first transistor 27, a collector terminal connected to the base terminal of the first transistor 27, and an emitter terminal connected to the DC power source 36.
Hereinafter, the terminal of the second switching element control circuit 17 connected to the collector terminal of the first transistor 27 is referred to as “third input terminal”. Further, the terminal of the second switching element control circuit 17 connected to the output terminal of the error amplifier 15 is “first input terminal”, and the terminal of the second switching element control circuit 17 connected to the switching current detection resistor 13 is “second input”. Terminal ".

When the LED divided voltage is smaller than the breakover voltage, no current flows to the anode side of the Zener diode 26, and the first transistor 27 connected to the anode side of the Zener diode 26 is off.
When the first transistor 27 is off, the collector-emitter of the first transistor 27 is not conducted, and the potential of the third input terminal of the second switching element control circuit 17 connected to the first transistor 27 is high level (DC power supply). 36). At this time, since the collector-emitter of the first transistor 27 does not conduct, the second transistor 28 connected to the first transistor 27 is off and the emitter-collector of the second transistor 28 does not conduct.
When the third input terminal is at a high level, the second switching element control circuit 17 performs the input voltage (corresponding to the LED current) of the first input terminal and the input voltage of the second input terminal as described in the first embodiment. The second switching element 7 is controlled according to (corresponding to the switching current).

When the LED divided voltage exceeds the breakover voltage, current flows to the anode side of the Zener diode 26, and the first transistor 27 connected to the anode side of the Zener diode 26 is turned on.
When the first transistor 27 is on, the collector-emitter of the first transistor 27 becomes conductive, and the potential of the third input terminal of the second switching element control circuit 17 connected to the first transistor 27 is low level (almost “0”). ")become. In addition, when the collector-emitter of the first transistor 27 becomes conductive, the second transistor 28 connected to the first transistor 27 is turned on, and the emitter-collector of the second transistor 28 becomes conductive. Then, the first transistor 27 connected to the second transistor 28 is maintained in the ON state by conducting between the emitter and the collector of the second transistor 28.
When the third input terminal is at the low level, the second switching element control circuit 17 does not depend on the input voltage (corresponding to the LED current) of the first input terminal and the input voltage (corresponding to the switching current) of the second input terminal. Then, a switch-off signal is output to the drive circuit 18 to turn off the second switching element 7.

In the third embodiment, the following LED lighting device 41 has been described.
During normal times when an open failure or the like of the LED 11 has not occurred, the LED lighting device 41 lights the LED 11 by the constant current control of the second switching element control circuit 17 as described in the first embodiment.

However, when some failure occurs and the output voltage of the step-down chopper circuit 32 increases, the LED lighting device 41 functions as follows.
For example, when the LED 11 has an open failure for some reason, as described in the second embodiment, the output voltage of the step-down chopper circuit 32 increases.
When the output voltage of the step-down chopper circuit 32 exceeds a predetermined voltage, the Zener diode 26 is turned on and becomes conductive. Then, the first transistor 27 of the latch circuit 25 is turned on and becomes conductive, and the terminal of the second switching element control circuit 17 connected to the collector terminal of the first transistor 27 becomes the Low level. Then, the second switching element control circuit 17 turns off the second switching element 7 and stops constant current control. The latch circuit 25 maintains this on state once the first transistor 27 is turned on. For this reason, even when the second switching element 7 is turned off, the output voltage of the step-down chopper circuit 32 is lowered, and the Zener diode 26 is turned off, the Low signal is continuously input from the latch circuit 25 to the first transistor 27. . That is, the second switching element control circuit 17 maintains the constant current control stopped state.

In the third embodiment, the following protection circuit (latch circuit 25) has been described.
When the constant current control is performed, the output voltage of the step-down chopper circuit 32 increases when the LED 11 is in an open failure as compared with the normal lighting state. Further, when the LED 11 has an open failure, the output of the step-down chopper circuit 32 may be stopped, so that the output voltage of the step-down chopper circuit 32 may not be kept constant. Therefore, it is not necessary to detect the output voltage of the step-down chopper circuit 32 with high accuracy.
That is, in applications where constant current control may be stopped when an overvoltage is detected, the output voltage of the step-down chopper circuit 32 need not be detected with high accuracy using the differential amplifier 21 as in the second embodiment. It doesn't matter. Therefore, the output voltage of the step-down chopper circuit 32 may be simply detected using the Zener diode 26 as in the third embodiment.

Further, the above form may be as follows.
The first switching element control circuit 33 turns off the first switching element 4 of the step-up chopper circuit 31 when the second switching element control circuit 17 turns off the second switching element 7.
For example, like the second switching element control circuit 17, the first switching element control circuit 33 is connected to the first transistor 27 of the latch circuit 25. The first switching element control circuit 33 turns off the first switching element 4 of the step-up chopper circuit 31 when the Low signal is input from the latch circuit 25.
As a result, power consumption when an abnormality occurs (when the second switching element 7 of the step-down chopper circuit 32 is turned off) can be reduced.

Embodiment 4 FIG.
An illumination device using the LED lighting device 41 described in Embodiment 1-3 will be described.

FIG. 4 is a side sectional view of illumination device 40 in the fourth embodiment.
As shown in FIG. 4, the lighting device 40 includes an LED lighting device 41, a power line 42, a connector 43, a wiring 44, and the LED 11 in a lighting device main body 49.

  As the LED lighting device 41, the one described in any of Embodiments 1-3 is used.

The LED lighting device 41 is connected to a commercial AC power source 1 (not shown) via a power line 42 and a connector 43.
The LED 11 is mounted on the light emitting surface of the illuminating device main body 49 and connected to the LED lighting device 41 by the wiring 44.

The LED lighting device 41 performs dimming lighting of the LED 11 as follows.
The LED lighting device 41 accurately detects the LED current and performs feedback control. As a result, the LED current is maintained at the target current value, and even if there is a variation in the life or other characteristics of each LED, a substantially constant current is supplied to each LED to achieve accurate LED lighting (dimming control). Can do. Further, since the switching current is detected, the switching element (second switching element 7) can be instantaneously turned off even if an overcurrent flows in the circuit (step-down chopper circuit 32) for some reason.

  DESCRIPTION OF SYMBOLS 1 Commercial alternating current power supply, 2 Rectifier circuit, 3rd inductor, 1st switching element, 5 diode, 6 1st smoothing capacitor, 7 2nd switching element, 8 2nd inductor, 9 freewheeling diode, 10 2nd smoothing capacitor, 11 LED, 12 LED current detection resistor, 13 switching current detection resistor, 14 differential amplifier, 15 error amplifier, 16 dimming controller, 17 second switching element control circuit, 18 drive circuit, 19 variable voltage device, 20a, 20b min Voltage resistor, 21 Differential amplifier, 22 Error amplifier, 23 OR circuit, 24 Constant voltage source, 25 Latch circuit, 26 Zener diode, 27 First transistor, 28 Second transistor, 31 Boost chopper circuit, 32 Buck chopper circuit, 33 First switching element control circuit, 34 Light source unit, 35 transistor, 36 DC power supply, 37 diode, 40 lighting device, 41 LED lighting device, 42 power line, 43 connector, 44 wiring, 49 lighting device body.

Claims (7)

A DC power circuit that converts AC voltage from the AC power source into DC voltage;
A step-down chopper circuit having a switching element and stepping down a DC voltage from the DC power supply circuit to a DC voltage corresponding to an ON time of the switching element;
A light source is attached, and a light source unit that turns on the light source with a DC voltage stepped down by the step-down chopper circuit;
A light source current detection resistor connected in series with the light source attached to the light source unit;
A differential amplifier for detecting a voltage difference between both ends of the light source current detection resistor;
A switching element control circuit for adjusting an on-time of the switching element of the step-down chopper circuit according to a voltage difference detected by the differential amplifier ;
A ground terminal;
A switching current detection resistor connected in series between the switching element of the step-down chopper circuit and the ground terminal;
When the voltage difference detected by the differential amplifier is greater than a predetermined target voltage, the switching element control circuit changes the ON time of the switching element of the step-down chopper circuit to reduce the DC voltage after step-down. When the voltage difference detected by the differential amplifier is smaller than the target voltage, the on-time of the switching element of the step-down chopper circuit is changed to increase the DC voltage after step-down.
When the voltage applied to the switching current detection resistor exceeds a predetermined upper limit voltage, the switching element control circuit turns off the switching element of the step-down chopper circuit regardless of the voltage difference detected by the differential amplifier. A light source lighting device characterized by: The light source lighting device further includes:
An output voltage detection unit for detecting a DC voltage stepped down by the step-down chopper circuit;
The switching element control circuit changes an ON time of the switching element of the step-down chopper circuit according to a voltage difference detected by the differential amplifier and a DC voltage detected by the output voltage detection unit. The light source lighting device according to claim 1 . The switching element control circuit is at least one of a case where the voltage difference detected by the differential amplifier is larger than the target voltage and a case where the DC voltage detected by the output voltage detector is larger than a predetermined reference voltage. 3. The light source lighting device according to claim 2 , wherein the on-time of the switching element of the step-down chopper circuit is changed to reduce the DC voltage after step-down. The light source lighting device includes a first differential amplifier as the differential amplifier that detects a voltage difference between both ends of the light source current detection resistor,
The output voltage detector is
A voltage dividing resistor for dividing the DC voltage stepped down by the step-down chopper circuit;
As a voltage corresponding to the DC voltage stepped down by the step-down chopper circuit, a second differential amplifier that detects a voltage difference between both ends of the voltage dividing resistor,
The switching element control circuit includes a case where the voltage difference detected by the first differential amplifier is larger than the target voltage and a case where the voltage difference detected by the second differential amplifier is larger than the reference voltage. 4. The light source lighting device according to claim 3 , wherein in at least one of the cases, the DC voltage after step-down is reduced by changing the ON time of the switching element of the step-down chopper circuit. The output voltage detector is
A voltage dividing resistor for dividing the DC voltage stepped down by the step-down chopper circuit;
A latch circuit that detects whether or not a voltage applied to the voltage dividing resistor exceeds the reference voltage;
When the latch circuit detects a voltage exceeding the reference voltage, the switching element control circuit turns off the switching element of the step-down chopper circuit regardless of the voltage difference detected by the differential amplifier. The light source lighting device according to claim 3 . The DC power supply circuit is
A rectifier circuit for converting an AC voltage from the AC power source into a DC voltage;
A boost chopper circuit that includes a first switching element and boosts a DC voltage from the rectifier circuit to a DC voltage corresponding to an on-time of the first switching element;
The light source lighting device is:
A second switching element as the switching element of the step-down chopper circuit;
The switching element control circuit includes:
When the latch circuit detects a voltage exceeding the reference voltage, the second switching element of the step-down chopper circuit is turned off and the first switching element of the step-up chopper circuit is turned off. The light source lighting device according to claim 5 . The light source lighting device according to any one of claims 1 to 6 ,
An illumination device comprising: a light source attached to the light source unit of the light source lighting device.

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