JP2018170135A - Lighting device, lighting apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting device and a lighting apparatus capable of reducing distortion of current, while restraining increase in the cost and power consumption.SOLUTION: Lighting device 10 includes a lighting block 20. The lighting block 20 has a rectification part 21, a power factor improvement part 22, a transducer 23 and a control section 24. The rectification part 21 rectifies AC voltage of an AC power supply 40. The power factor improvement part 22 reshapes the waveform of the output voltage from the rectification part 21 so that a current, flowing to the lighting block 20, approaches a sinewave. The transducer 23 converts the output voltage of the power factor improvement part 22 into a DC voltage and is outputted. The control section 24 controls the light source 25 to be lighted with the DC voltage outputted from the transducer 23. Furthermore, the power factor improvement part 22 has a function for decreasing a current I20 flowing to the lighting block 20, for a prescribed period when a current I30 is flowing from the AC power supply 40 to a circuit block connected with the AC power supply 40 in parallel with the lighting block 20.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a lighting device and a lighting fixture, and more particularly, to a lighting device and a lighting fixture that turns on a light source with electric power from an AC power source.

  Patent Document 1 discloses an LED driving circuit (lighting device) using a light emitting diode (LED) as a light source. The LED drive circuit of Patent Document 1 includes an illuminance sensor, a sensor power supply circuit, an illuminance level detection circuit, a brightness setting register, a brightness control circuit, and an LED power supply circuit. The sensor power supply circuit supplies a voltage to the illuminance sensor. The illuminance level detection circuit detects the illuminance level from the illuminance voltage obtained by the illuminance sensor. In the luminance setting register, specific dimming data is selected according to the illuminance level detected by the illuminance level detection circuit. The luminance control circuit generates a luminance signal according to the dimming data selected by the luminance setting register. The LED power supply circuit performs dimming driving of the LED by the luminance signal from the luminance control circuit.

Japanese Patent Laid-Open No. 2004-233569

  In Patent Document 1, not only an LED power supply circuit but also a sensor power supply circuit is connected to an external power supply. Conventionally, the current consumption of such a sensor power supply circuit is smaller than the current consumption of the light source power supply circuit, and the current distortion has little effect. However, in recent years, LEDs that are often used as light sources consume less current than fluorescent lamps that have been conventionally used as light sources. Therefore, the influence of the current consumption of the sensor power supply circuit becomes relatively large, and as a result, the influence on the distortion may not be ignored.

  The subject of this invention is providing the lighting device and lighting fixture which can reduce distortion of an electric current, suppressing the increase in cost and power consumption.

  The lighting device according to one aspect of the present invention includes a lighting block that turns on a light source with electric power from an AC power supply. The lighting block includes a rectification unit, a power factor improvement unit, a conversion unit, and a control unit. The rectifying unit is configured to rectify an AC voltage of the AC power supply. The power factor improving unit is configured to shape the waveform of the output voltage of the rectifying unit so that the waveform of the current flowing through the lighting block approaches a sine wave. The converting unit is configured to convert the output voltage of the power factor improving unit into a DC voltage and output the DC voltage. The control unit is configured to turn on the light source by a DC voltage output from the conversion unit. The power factor improving unit has a function of reducing a current flowing through the lighting block during a predetermined period in which a current flows from the AC power supply to a circuit block connected to the AC power supply in parallel with the lighting block.

  The lighting fixture of 1 aspect which concerns on this invention is equipped with the said lighting device and the fixture main body holding the said lighting device.

  The lighting device and the lighting fixture according to the aspect of the present invention have an effect that current distortion can be reduced while suppressing an increase in cost and power consumption.

FIG. 1 is a block diagram of the lighting device according to the first embodiment. FIG. 2 is a schematic diagram of a power factor improvement unit of the lighting block of the lighting device according to the first embodiment. FIG. 3 is a schematic diagram of a voltage shift circuit of the power factor correction unit of the lighting device according to the first embodiment. FIG. 4 is an explanatory diagram of the operation of the lighting device of the first embodiment. FIG. 5 is a perspective view of a lighting fixture including the lighting device of the first embodiment. FIG. 6 is a block diagram of the lighting device according to the second embodiment. FIG. 7 is a schematic diagram of a power supply unit of a control block of the lighting device according to the second embodiment. FIG. 8 is a schematic diagram of a voltage shift circuit of the power factor improvement unit of the lighting block of the lighting device according to the second embodiment. FIG. 9 is an explanatory diagram of the operation of the lighting device of the second embodiment. 10A to 10C are modified examples of the voltage adjustment circuit of the voltage shift circuit.

1. Embodiment 1.1 Embodiment 1
1.1.1 Configuration FIG. 1 shows a lighting device 10 of the present embodiment. The lighting device 10 includes a lighting block 20 that turns on the light source 25 with power from the AC power supply 40, and a control block 30 that operates with power from the AC power supply 40 and controls the lighting block 20. Note that the AC power supply 40 is, for example, a commercial AC power supply that outputs an AC voltage having a frequency of 50 Hz or 60 Hz.

  The control block 30 is a circuit block connected to the AC power supply 40 in parallel with the lighting block 20. As shown in FIG. 1, the control block 30 includes a rectification unit (second rectification unit) 31, a smoothing unit 32, a conversion unit (second conversion unit) 33, a control unit (second control unit) 34, Sensor 35. In the control block 30, the second rectification unit 31, the smoothing unit 32, and the second conversion unit 33 constitute a power supply unit that generates the operating voltage of the control block 30.

  The sensor 35 is a circuit for obtaining information around the lighting device 10. For example, as the sensor 35, a human sensor, a brightness sensor, or the like is used. If the sensor 35 is a human sensor, the sensor 35 can detect a person around the lighting device 10. If the sensor 35 is a brightness sensor, the brightness around the lighting device 10 can be measured by the sensor 35. The sensor 35 acquires information around the lighting device 10 as detection information and outputs the detection information to the control unit 34.

  The rectifier 31 is a circuit (so-called rectifier circuit) that rectifies the AC voltage of the AC power supply 40. More specifically, the rectification unit 31 rectifies (full-wave rectification) the AC voltage of the AC power supply 40 to generate a pulsating voltage and outputs it to the smoothing unit 32. The rectifier 31 is a circuit including a diode bridge, for example.

  The smoothing unit 32 is a circuit that smoothes the output voltage (pulsating voltage) of the rectifying unit 31. The output voltage of the smoothing unit 32 is input to the conversion unit 33. The smoothing unit 32 ensures the input voltage required by the conversion unit 33. The smoothing unit 32 includes, for example, a capacitor (for example, an electrolytic capacitor) that is electrically connected between the output terminals of the rectifying unit 31.

  The conversion unit 33 is a circuit that converts the output voltage of the smoothing unit 32 into a voltage required by the control unit 34 (an operating voltage of the control block 30). For example, the conversion unit 33 generates a direct-current operating voltage based on the output voltage of the smoothing unit 32. The conversion unit 33 is a DC-DC converter. Examples of the DC-DC converter include a step-down chopper circuit, a step-up chopper circuit, and a step-up / step-down chopper circuit.

  The control unit 34 is a circuit that executes a predetermined operation using the operation voltage generated by the conversion unit 33. For example, the control unit 34 drives the sensor 35 using the operating voltage, and obtains detection information from the sensor 35. The control unit 34 outputs a control signal to the lighting block 20 according to the detection information obtained from the sensor 35. Examples of control signals include a lighting signal that instructs the lighting block 20 to turn on the light source 25, a turn-off signal that instructs the lighting block 20 to turn off the light source 25, and a control that causes the lighting block 20 to adjust the brightness of the light source 25. An optical signal is mentioned. The control unit 34 is configured by a microcontroller including a memory and a processor, for example. In other words, the microcontroller functions as the control unit 34 when the processor executes the program stored in the memory.

  As illustrated in FIG. 1, the lighting block 20 includes a rectification unit (first rectification unit) 21, a power factor improvement unit 22, a conversion unit (first conversion unit) 23, and a control unit (first control unit) 24. And a light source 25.

  The light source 25 is used to illuminate the surroundings of the lighting device 10. For example, as the light source 25, a light source device composed of a plurality of light emitting diodes (LEDs) is used. In addition, the light source 25 is not limited to the light source device using LED, A discharge lamp (fluorescent lamp), an incandescent lamp, etc. may be sufficient.

  The rectifier 21 is a circuit (so-called rectifier circuit) that rectifies the AC voltage of the AC power supply 40. More specifically, the rectification unit 21 rectifies (full-wave rectification) the AC voltage of the AC power supply 40 to generate a pulsating voltage and outputs it to the power factor improvement unit 22. The rectifier 21 is a circuit including a diode bridge, for example. The rectifier 21 has a pair of output terminals that output a pulsating voltage, one of which is connected to the ground. Hereinafter, the one connected to the ground among the pair of output terminals of the rectifying unit 21 is referred to as a ground terminal as necessary.

  The power factor improvement unit 22 is a circuit (so-called power factor improvement circuit) for improving the power factor related to the AC power supply 40. The power factor improving unit 22 shapes the waveform of the output voltage of the rectifying unit 21 so that the waveform of the current flowing through the lighting block 20 approaches a sine wave. In the present embodiment, the power factor improvement unit 22 has a function of reducing the current flowing through the lighting block 20 during a predetermined period.

  The power factor improving unit 22 will be described in more detail with reference to FIGS. As shown in FIG. 2, the power factor improving unit 22 includes a waveform shaping circuit 221 and a voltage shift circuit 222.

  The waveform shaping circuit 221 shapes the waveform of the output voltage of the rectifier 21 based on the input voltage proportional to the output voltage of the rectifier 21 so that the waveform of the current flowing through the lighting block 20 approaches a sine wave. The waveform shaping circuit 221 includes an inductor L22, a zero-cross detection circuit 2211, a control circuit 2212, a first voltage dividing circuit 2213, a voltage conversion circuit 2214, a current detection resistor R23, and a second voltage dividing circuit 2215. And a smoothing capacitor C21. The inductor L22 is an inductor for detecting zero crossing. The first voltage dividing circuit 2213 is a series circuit of resistors R21 and R22, and is electrically connected between a pair of output terminals of the rectifying unit 21. The first voltage dividing circuit 2213 gives the divided voltage obtained by dividing the output voltage of the rectifying unit 21 to the control circuit 2212 as a detection voltage Vin proportional to the output voltage of the rectifying unit 21. Voltage conversion circuit 2214 includes an inductor L21, a diode D21, and a switch SW21. The voltage conversion circuit 2214 is a so-called boost chopper circuit. The inductor L21 and the switch SW21 form a series circuit, and are electrically connected in parallel with the first voltage dividing circuit 2213 between the pair of output terminals of the rectifying unit 21. The switch SW21 is, for example, a semiconductor switching element such as a transistor. The anode of the diode D21 is electrically connected to the connection point between the inductor L21 and the switch SW21. The resistor R23 is a resistor for detecting a current flowing through the switch SW21, and is electrically connected between the switch SW21 and the ground terminal of the rectifying unit 21. The second voltage dividing circuit 2215 is a series circuit of resistors R24 and R25, and is electrically connected between the cathode of the diode D21 and the ground terminal of the rectifying unit 21. The second voltage dividing circuit 2215 supplies the divided voltage obtained by dividing the output voltage of the power factor improving unit 22 to the control circuit 2212 as a detection voltage Vout proportional to the output voltage of the power factor improving unit 22. The capacitor C21 is connected in parallel to the second voltage dividing circuit 2215. The capacitor C21 is an electrolytic capacitor. The inductor L22 is magnetically coupled to the inductor L21 of the voltage conversion circuit 2214. The zero cross detection circuit 2211 is configured to detect the zero cross point of the output voltage of the rectifier 21 based on the induced voltage of the inductor L22. However, the zero-cross detection circuit 2211 does not detect the zero-cross point in a strict sense, and the time when the output voltage of the rectifying unit 21 becomes equal to or lower than a predetermined threshold is set as the zero-cross point.

  The control circuit 2212 is configured to adjust the output voltage of the power factor improvement unit 22 by controlling the switch SW21 of the voltage conversion circuit 2214. The control circuit 2212 determines the peak value of the current flowing through the switch SW21 based on the detection voltage Vin of the first voltage dividing circuit 2213 and the detection voltage Vout of the second voltage dividing circuit 2215. The peak value is obtained by multiplying the detection voltage Vin and the detection voltage Vout. The control circuit 2212 turns on the switch SW21 when the zero cross point is detected by the zero cross detection circuit 2211, and turns off the switch SW21 when the current flowing through the switch SW21 reaches the peak value. As a result, the waveform of the average value of the current (that is, the waveform of the current flowing through the lighting block 20) approaches the power factor improving unit 22 to a sine wave.

  Thus, according to the waveform shaping circuit 221, the waveform of the current flowing through the lighting block 20 approaches a sine wave, so that the power factor related to the AC power supply 40 can be improved. However, the current flowing through the lighting device 10 is the sum of the current flowing through the lighting block 20 and the current flowing through the control block 30. Therefore, there is a possibility that improvement of the power factor related to the AC power supply 40 may be insufficient only by making the waveform of the current flowing through the lighting block 20 close to a sine wave. The control block 30 has a smoothing unit 32. Therefore, in the control block 30, when the output voltage of the rectifying unit 31 exceeds a predetermined value, a current flows through the capacitor of the smoothing unit 32 (the capacitor of the smoothing unit 32 is charged). Therefore, as shown in FIG. 4, the current I30 from the AC power supply 40 flows through the control block 30 only for a certain period in the half cycle Tp of the AC voltage of the AC power supply 40. In general, the current I30 flows through the control block 30 in the vicinity where the output voltage of the rectifying unit 31 reaches the maximum value. Such a change in the current I30 can cause current distortion due to the lighting device 10.

  Therefore, the power factor improvement unit 22 has a function (voltage shift function) for reducing the current flowing through the lighting block 20 during a predetermined period Td (see FIG. 4). The predetermined period Td is a period in which the current I30 from the AC power supply 40 flows through the circuit block (control block 30) connected to the AC power supply 40 in parallel with the lighting block 20. In particular, the predetermined period Td is a period during which the current from the AC power supply 40 flows through the capacitor of the smoothing unit 32. In the present embodiment, the predetermined period Td is included in the half cycle Tp of the AC voltage of the AC power supply 40.

  The voltage shift function described above is realized by the voltage shift circuit 222. The voltage shift circuit 222 reduces the current flowing through the lighting block 20 by changing the detection voltage Vin during the predetermined period Td. As illustrated in FIG. 3, the voltage shift circuit 222 includes a voltage adjustment circuit 2221, a switch control unit 2222, and a memory 2223.

  The voltage adjusting circuit 2221 is electrically connected between the connection point of the resistors R21 and R22 of the first voltage dividing circuit 2213 and the ground terminal of the rectifying unit 21. The voltage adjustment circuit 2221 is a series circuit of a switch SW22 and a Zener diode ZD21. For example, the switch SW22 is a semiconductor switching element such as a transistor. The Zener diode ZD21 has a cathode electrically connected to the connection point of the resistors R21 and R22 of the first voltage dividing circuit 2213 via the switch SW22, and an anode electrically connected to the ground terminal of the rectifying unit 21. . According to the voltage adjustment circuit 2221, when the switch SW22 is turned on and the detection voltage Vin is higher than the breakdown voltage of the Zener diode ZD21, the voltage adjustment circuit 2221 decreases to the breakdown voltage of the Zener diode ZD21.

  The switch control unit 2222 is configured to control the switch SW22. The switch control unit 2222 normally turns off the switch SW22. The switch control unit 2222 turns on the switch SW22 for a predetermined period Td. The memory 2223 is a storage unit that stores period information for specifying the predetermined period Td. The switch control unit 2222 is configured to specify the predetermined period Td based on the period information stored in the memory 2223. The period information includes the start time and duration of the predetermined period Td. The start point indicates a time Tw from the time when the AC voltage of the AC power supply 40 becomes 0V. The duration time indicates the length of the predetermined period Td. When the start time elapses after the detection voltage Vin becomes 0 V, the switch control unit 2222 turns on the switch SW22 for the duration. As a result, the voltage shift circuit 222 reduces the detection voltage Vin during the predetermined period Td. When the detection voltage Vin decreases, the peak value calculated by the waveform shaping circuit 221 also decreases. As a result, the current I20 flowing through the lighting block 20 decreases.

  As described above, the voltage shift circuit 222 is turned on during the predetermined period Td during which the current I30 from the AC power supply 40 flows to the circuit block (control block 30) connected to the AC power supply 40 in parallel with the lighting block 20. The current I20 flowing through 20 is reduced. Therefore, the waveform of the current flowing through the entire lighting device 10 (the sum of the current I20 flowing through the lighting block 20 and the current I30 flowing through the control block 30) can be brought close to a sine wave close to the waveform of the current I40 of the AC power supply 40. As a result, current distortion can be reduced. Therefore, the power factor (current distortion characteristic) related to the AC power supply 40 can be improved.

  Here, as shown in FIG. 4, the current I20 flowing through the lighting block 20 is reduced from Ip to Ib. The amount of decrease is set so that the value of the current I20 corresponding to the maximum value of the output voltage of the rectifier 21 changes from Ip to Ib. In particular, the decrease amount (Ip−Ib) of the current I20 is equal to the maximum value Id of the current I30 flowing through the control block 30 during the predetermined period Td (a value corresponding to the maximum value of the output voltage of the rectifier 31). The amount of decrease in current I20 (Ip−Ib) depends on the amount of decrease in detection voltage Vin. Therefore, the voltage adjustment circuit 2221 is designed such that the amount of decrease (Ip−Ib) of the current I20 matches the maximum value Id. Thereby, the power factor relating to the AC power supply 40 can be further improved.

  The conversion unit 23 is a circuit that converts the output voltage of the power factor improvement unit 22 (waveform shaping circuit 221) into a voltage required by the control unit 24. For example, the conversion unit 23 generates a DC voltage based on the output voltage of the power factor improvement unit 22. The conversion unit 23 is a DC-DC converter. Examples of the DC-DC converter include a step-down chopper circuit, a step-up chopper circuit, and a step-up / step-down chopper circuit.

  The control unit 24 is a circuit that turns on the light source 25 with the DC voltage output from the conversion unit 23. The controller 24 turns on and off the light source 25 and performs light control. In particular, the control unit 24 controls the light source 25 according to control signals (lighting signal, extinguishing signal, dimming signal) from the control unit 34 of the control block 30. As a method for controlling the light source 25, PWM control or the like can be given. The control unit 24 is configured by a microcontroller including a memory and a processor, for example. That is, the microcontroller functions as the control unit 24 by the processor executing the program stored in the memory.

1.1.2 Operation Next, an example of the operation of the lighting device 10 will be briefly described with reference to FIG. First, when the lighting device 10 starts operation, the waveform shaping circuit 221 of the power factor improving unit 22 shapes the waveform of the output voltage of the rectifying unit 21 so that the waveform of the current I20 flowing through the lighting block 20 approaches a sine wave. . Immediately after the operation of the lighting device 10 is started, the current I30 does not flow through the control block 30. When the time Tw elapses from the time when the AC voltage of the AC power supply 40 is 0 V and the absolute value of the AC voltage of the AC power supply 40 increases and the output voltage of the rectifying unit 31 exceeds a predetermined value, the capacitor of the smoothing unit 32 Current I30 begins to flow. As a result, the current I30 from the AC power supply 40 flows through the control block 30 only for a specific period (Td). At the same time, the voltage shift circuit 222 of the power factor improvement unit 22 reduces the current I20 flowing through the lighting block 20 for a predetermined period Td during which the current I30 flows from the AC power supply 40 to the control block 30. After the predetermined period Td, the waveform shaping circuit 221 shapes the waveform of the output voltage of the rectifier 21 so that the waveform of the current I20 flowing through the lighting block 20 approaches a sine wave again.

  In this way, the lighting block 20 reduces the current I20 flowing through the lighting block 20 by the power factor improving unit 22 to cancel the increase in the current I30 of the control block 30. As a result, the lighting block 20 maintains a state in which the waveform of the current of the lighting device 10 as a whole is a sine wave close to the waveform of the current I40 of the AC power supply 40. Therefore, according to the lighting device 10, current distortion can be reduced. As a result, an improvement in power factor (current distortion characteristics) regarding the AC power supply 40 can be expected.

1.1.3 Summary As described above, the lighting device 10 includes the power factor improving unit 22 that shapes the waveform of the output voltage of the rectifying unit 21 so that the waveform of the current I20 flowing through the lighting block 20 approaches a sine wave. Prepare. The power factor improving unit 22 has a function of reducing the current flowing through the lighting block 20 during a predetermined period Td during which the current I30 is flowing from the AC power supply 40 to the circuit block connected to the AC power supply 40 in parallel with the lighting block 20. Have. During the period in which the current flows in a circuit block different from the lighting block 20, it is considered that current distortion is likely to occur due to current consumption in another circuit block. At this time, the current I20 flowing through the lighting block 20 is reduced by the power factor improving unit 22. Therefore, current distortion can be reduced. Here, as a method of reducing current distortion, it is conceivable to provide a power factor correction circuit in the control block 30 as well. However, since the power factor correction circuit requires a switch and its control circuit, it leads to an increase in cost and power consumption. On the other hand, in the control block 30, if a resistor for suppressing current is provided in the smoothing unit 32, the maximum value of the current I30 flowing through the control block 30 can be reduced, thereby reducing current distortion. However, power loss occurs due to the resistance for current suppression, leading to an increase in power consumption. On the other hand, according to the lighting device 10, only the current flowing through the lighting block 20 is reduced during the predetermined period Td. Accordingly, current distortion can be reduced while suppressing increases in cost and power consumption.

  The power factor improvement unit 22 includes a waveform shaping circuit 221 and a voltage shift circuit 222. The waveform shaping circuit 221 shapes the waveform of the output voltage of the rectifying unit 21 based on the detection voltage Vin proportional to the output voltage of the rectifying unit 21 so that the waveform of the current I20 flowing through the lighting block 20 approaches a sine wave. Configured. The voltage shift circuit 222 is configured to reduce the current I20 flowing through the lighting block 20 by changing the detection voltage Vin during a predetermined period Td. Therefore, the power factor improvement unit 22 can be realized with a simple configuration, and an increase in cost can be suppressed.

  In addition, the lighting device 10 further includes a control block 30 that operates with power from the AC power supply 40 and controls the lighting block 20 as a circuit block. The control block 30 includes a power supply unit (31, 32, 33) that generates an operating voltage of the control block 30 using power from the AC power supply 40. The power supply unit (31, 32, 33) includes a capacitor (smoothing unit 32) that smoothes the voltage obtained by rectifying the AC voltage of the AC power supply 40. The predetermined period Td is a period in which the current I30 from the AC power supply 40 flows through the capacitor (smoothing unit 32). Generation of the current I30 during such a period tends to cause current distortion. If the current I20 flowing through the lighting block 20 is reduced by the power factor improving unit 22 during the period, the current distortion can be further reduced.

  The lighting device 10 further includes a storage unit (memory 2223) that stores period information for specifying the predetermined period Td. The power factor improving unit 22 is configured to specify the predetermined period Td based on the period information stored in the storage unit 2223. The period in which the current I30 from the AC power supply 40 flows through the capacitor (smoothing unit 32) is not random but occurs at a fixed timing. Therefore, if period information for specifying the predetermined period Td is stored in the storage unit (memory 2223) in advance, the period during which the current I30 from the AC power supply 40 flows to the capacitor (smoothing unit 32) is detected. This circuit becomes unnecessary. Thereby, the predetermined period Td can be determined with a simple configuration, and an increase in cost can be suppressed.

1.1.4 Lighting fixture The lighting device 10 of the present embodiment described above is provided in a lighting fixture 100 as shown in FIG. The luminaire 100 is, for example, a luminaire (so-called staircase guide light) installed on the wall surface of a stair landing that serves as an evacuation route for a building. As shown in FIG. 5, the lighting fixture 100 includes a lighting device 10 and a fixture main body 110 that holds the lighting device 10. In particular, the instrument body 110 is elongated. The light source 25 of the lighting device 10 is disposed in the central portion in the longitudinal direction of the fixture body 110, and the sensor 35 of the lighting device 10 is disposed on one surface in the short direction in the central portion of the fixture body 110 in the longitudinal direction. Yes. In the lighting fixture 100, the light source 25 can be turned on when a person is detected by the sensor 35. Since such a lighting fixture 100 includes the lighting device 10, current distortion can be reduced while suppressing an increase in cost.

1.2 Embodiment 2
1.2.1 Configuration FIG. 6 shows a lighting device 10A according to the second embodiment. The lighting device 10A includes a lighting block 20A and a control block 30A.

  The control block 30 </ b> A includes a rectification unit 31, a smoothing unit 32, a conversion unit 33, a control unit 34, a sensor 35, and a detection unit 36. As shown in FIG. 7, the detection unit 36 includes a current detection resistor R <b> 31 and a detection circuit 361. The resistor R31 is electrically connected between the rectifying unit 31 and the smoothing unit 32. The detection circuit 361 is configured to detect the current I30 flowing through the smoothing unit (capacitor) 32 based on the voltage across the resistor R31. The detection circuit 361 determines that the current I30 flows through the smoothing unit 32 when the voltage across the resistor R31 exceeds the threshold value. The detection circuit 361 is configured to output the detection signal S30 to the voltage shift circuit 222A of the power factor improvement unit 22A of the lighting block 20A while the current I30 flows through the smoothing unit 32 (see FIG. 9). That is, the detection unit 36 notifies a predetermined period Td, which is a period during which the current I30 from the AC power supply 40 flows to the smoothing unit 32, by the detection signal S30. The resistance value of the resistor R31 is selected so as not to excessively suppress the current flowing through the control block 30A. In particular, it is preferable that the resistance value of the resistor R31 is generally set to a value smaller than the resistance value of the resistor used for current suppression.

  The lighting block 20 </ b> A includes a rectification unit 21, a power factor improvement unit 22 </ b> A, a conversion unit 23, a control unit 24, and a light source 25. The power factor improving unit 22A includes a waveform shaping circuit 221 and a voltage shift circuit 222A. In the voltage shift circuit 222A, as shown in FIG. 8, the switch control unit 2222 is configured to receive the detection signal S30 from the detection circuit 361. The switch control unit 2222 controls the switch SW22 based on the detection signal S30 received from the detection circuit 361. More specifically, the switch control unit 2222 turns on the switch SW22 while receiving the detection signal S30 from the detection circuit 361. Accordingly, the switch control unit 2222 keeps the switch SW22 on for a predetermined period Td. Thus, the power factor improvement unit 22A is configured to specify the predetermined period Td based on the period during which the current I30 is detected by the detection unit 36. In the present embodiment, the switch control unit 2222 does not need to detect when the detection voltage Vin becomes 0V.

1.2.2 Operation Next, an example of the operation of the lighting device 10A will be briefly described with reference to FIG. First, when the lighting device 10A starts operation, the waveform shaping circuit 221 of the power factor improvement unit 22A shapes the waveform of the output voltage of the rectifying unit 21 so that the waveform of the current I20 flowing through the lighting block 20A approaches a sine wave. . Immediately after the start of the operation of the lighting device 10A, the current I30 does not flow through the control block 30. When the current I30 begins to flow through the smoothing unit 32 and the voltage across the resistor R31 exceeds the threshold value, the detection circuit 361 starts outputting the detection signal S30 to the voltage shift circuit 222A (time T1). When the voltage shift circuit 222A receives the detection signal S30 from the detection circuit 361, the voltage shift circuit 222A turns on the switch SW22 and decreases the current I20 flowing through the lighting block 20. Thereafter, when a predetermined period Td elapses, the current I30 no longer flows through the smoothing unit 32, the voltage across the resistor R31 becomes equal to or lower than the threshold value, and the detection circuit 361 stops outputting the detection signal S30 (time T2). . Since the voltage shift circuit 222A does not receive the detection signal S30 from the detection circuit 361, the voltage shift circuit 222A turns off the switch SW22. Thereafter, the waveform shaping circuit 221 again shapes the waveform of the output voltage of the rectifying unit 21 so that the waveform of the current I20 flowing through the lighting block 20A approaches a sine wave. In this way, the lighting block 20A reduces the current I20 flowing through the lighting block 20A by the power factor improving unit 22A to cancel the increase in the current I30 of the control block 30A. Thus, the lighting block 20A maintains a state where the current waveform of the entire lighting device 10A is a sine wave close to the waveform of the current I40 of the AC power supply 40. Therefore, according to the lighting device 10A, current distortion can be reduced. As a result, the power factor (current distortion characteristics) related to the AC power supply 40 can be improved.

1.2.3 Summary As described above, the lighting device 10 </ b> A can reduce the distortion of current in the same manner as the lighting device 10. In particular, in the lighting device 10 </ b> A, the control block 30 </ b> A further includes a detection unit 36 that detects a current I <b> 30 flowing from the AC power supply 40 to the capacitor (smoothing unit 32). The power factor improving unit 22A is configured to specify the predetermined period Td based on the period in which the current I30 is detected by the detecting unit 36. In this case, the current I20 flowing through the lighting block 20A can be reduced while the current I30 is actually flowing from the AC power supply 40 to the capacitor (smoothing unit 32). Therefore, current distortion can be reliably reduced.

  By the way, in Embodiment 1, the power factor improvement part 22 exhibits a voltage shift function according to the period information memorize | stored in the memory 2223 irrespective of the structure of the control block 30. FIG. On the other hand, in the present embodiment, when the control block 30 of the first embodiment is used instead of the control block 30A, the voltage shift circuit 222A of the lighting block 20A cannot receive the detection signal S30. For this reason, the power factor improvement unit 22A cannot exhibit the voltage shift function described above. Therefore, whether or not the power factor improvement unit 22A exhibits the voltage shift function can be determined depending on whether or not the detection unit 36 is provided in the control block. For example, when the influence on the current distortion of the control block cannot be ignored, the detection unit 36 may be provided in the control block. In this case, the power factor improvement unit 22A can exhibit a voltage shift function and reduce current distortion. On the other hand, when the influence on the distortion of the current of the control block can be ignored, the power factor improvement unit 22A does not exhibit the voltage shift function unless the detection unit 36 is provided in the control block. Therefore, the power factor improvement unit 22A can be used in common for the lighting devices 10 having different control blocks.

  Note that the lighting device 10 </ b> A of the present embodiment can also be provided in a lighting fixture 100 as shown in FIG. 5, similarly to the lighting device 10.

2. The embodiment of the present invention is not limited to the above embodiment. The above embodiment can be variously modified according to the design or the like as long as the object of the present invention can be achieved. Below, the modification of the said embodiment is enumerated.

  For example, FIGS. 10A to 10C show modifications of the voltage adjustment circuit 2221 according to the first and second embodiments.

  The voltage adjustment circuit 2221B illustrated in FIG. 10A reduces the detection voltage Vin using a voltage drop of the diode. The voltage adjustment circuit 2221B includes diodes D22 and D23 and switches SW23 and SW24. The diode D22 has an anode electrically connected to a connection point (see FIG. 2) of the resistors R21 and R22 of the first voltage dividing circuit 2213, and a cathode electrically connected to the anode of the diode D23. The cathode of the diode D23 is electrically connected to the ground terminal of the rectifying unit 21. The switch SW23 is electrically connected between the anode of the diode D22 and the control circuit 2212. The switch SW24 is electrically connected between the anode of the diode D23 and the control circuit 2212. In the case of the voltage adjustment circuit 2221B, the switch controller 2222 turns on the switch SW23 and turns off the switch SW24 when not reducing the current I20 flowing through the lighting block 20 (20A). The switch control unit 2222 turns off the switch SW23 and turns on the switch SW24 when reducing the current I20 flowing through the lighting block 20 (20A). At this time, the detection voltage Vin decreases due to the voltage drop of the diode D22. Note that the voltage adjustment circuit 2221B may further include a pair of a diode and a switch. In this case, the number of diodes connected to the control circuit 2212 through the switch can be changed. Accordingly, the power factor improvement unit 22 (22A) can have a function of adjusting the amount of decrease in the current I20 flowing through the lighting block 20 (20A). In this case, since an appropriate amount of decrease in the current I20 can be set according to the control block 30 (30A), the current distortion can be further reduced.

  The voltage adjustment circuit 2221C illustrated in FIG. 10B reduces the detection voltage Vin by using the voltage drop of the transistor and the breakdown voltage of the Zener diode. The voltage adjustment circuit 2221C includes a resistor R26, a Zener diode ZD22, a transistor Tr21, and switches SW25 and SW26. The Zener diode ZD22 has an anode electrically connected to the ground terminal of the rectifying unit 21, and a cathode electrically connected to a connection point (see FIG. 2) of the resistors R21 and R22 of the first voltage dividing circuit 2213 via the resistor R26. It is connected. The resistor R26 is electrically connected between the base and collector of the transistor Tr21. The switch SW25 is electrically connected between the connection point of the resistors R21 and R22 and the control circuit 2212. The switch SW26 is electrically connected between the emitter of the transistor Tr21 and the control circuit 2212. In the case of the voltage adjustment circuit 2221C, the switch control unit 2222 turns on the switch SW25 and turns off the switch SW26 when the current I20 flowing through the lighting block 20 (20A) is not reduced. The switch control unit 2222 turns off the switch SW25 and turns on the switch SW26 when reducing the current I20 flowing through the lighting block 20 (20A). At this time, the detection voltage Vin decreases due to the breakdown voltage of the Zener diode ZD22 and the voltage drop of the transistor Tr21. The voltage adjustment circuit 2221C may have a shunt regulator instead of the Zener diode ZD22. In this case, the accuracy of the decrease amount of the detection voltage Vin can be improved.

  The voltage adjustment circuit 2221D illustrated in FIG. 10C reduces the detection voltage Vin using the voltage regulator RG21. The voltage adjustment circuit 2221D includes a voltage regulator RG21 and switches SW27 and SW28. The voltage regulator RG21 has an input terminal electrically connected to a connection point (see FIG. 2) of the resistors R21 and R22 of the first voltage dividing circuit 2213. The switch SW27 is electrically connected between the connection point of the resistors R21 and R22 and the control circuit 2212. The switch SW28 is electrically connected between the output terminal of the voltage regulator RG21 and the control circuit 2212. In the case of the voltage adjustment circuit 2221D, the switch controller 2222 turns on the switch SW27 and turns off the switch SW28 when the current I20 flowing through the lighting block 20 (20A) is not reduced. The switch control unit 2222 turns off the switch SW27 and turns on the switch SW28 when reducing the current I20 flowing through the lighting block 20 (20A). At this time, the output voltage of the voltage regulator RG21 is supplied to the voltage adjustment circuit 2221 instead of the detection voltage Vin. Therefore, the detection voltage Vin can be reduced to the output voltage of the voltage regulator RG21.

  For example, in the first embodiment, the lighting block 20 includes a storage unit (2223) that stores period information for specifying a predetermined period (Td). However, such a storage unit (2223) may be included in the control block 30. In this case, period information is given from the control block 30 to the lighting block 20. In this case, appropriate period information can be given for each control block 30. For example, even when the control block 30 is replaced, the predetermined period Td can be set to a period suitable for the control block 30 after replacement.

  The predetermined period Td is preferably the entire period during which the current I30 flows from the AC power supply 40 to the circuit blocks (control blocks 30, 30A) connected to the AC power supply 40 in parallel with the lighting blocks 20 and 20A. However, it does not necessarily have to coincide with the whole period. If the predetermined period Td partially overlaps with the period in which the current I30 flows from the AC power supply 40 to the circuit block (control blocks 30, 30A), the distortion of the current can be reduced. In particular, in the first and second embodiments, the predetermined period Td is a period in which the current I30 from the AC power supply 40 flows through the capacitor 32, but is not particularly limited. In short, if current distortion occurs due to current flowing through the circuit block, the power factor improvement unit 22 (22A) reduces the current I20 of the lighting block 20 (20A) in accordance with this timing. Good. Further, the decrease amount (Ip−Ib) of the current I20 does not necessarily need to coincide with the maximum value Id of the current I30 flowing through the control block 30 during the predetermined period Td. The amount of decrease in current I20 (Ip-Ib) is not particularly limited as long as current distortion can be reduced.

  In the modified example, the lighting devices 10 and 10A may not include the light source 25 and the sensor 35 as components. Moreover, the structure of the rectification | straightening part 21 and the rectification | straightening part 31 is an example, Comprising: It can change into an equivalent circuit. Similarly, the configurations of the conversion unit 23 and the conversion unit 33 are examples, and can be changed to equivalent circuits. The operations of the control unit 24 and the control unit 34 are examples, and can be changed as appropriate.

  Moreover, the lighting fixture 100 is not limited to a stairway guide light, It may be a lighting fixture of various uses, such as a street lamp and an interior lamp.

3. Aspect As is apparent from the embodiment and the modification described above, the lighting device (10; 10A) of the first aspect is a lighting block (20;) that turns on the light source (25) with electric power from the AC power supply (40). 20A). The lighting block (20; 20A) includes a rectification unit (21), a power factor improvement unit (22; 22A), a conversion unit (23), and a control unit (24). The rectifier (21) is configured to rectify the AC voltage of the AC power supply (40). The power factor improving unit (22; 22A) shapes the waveform of the output voltage of the rectifying unit (21) so that the waveform of the current (I20) flowing through the lighting block (20; 20A) approaches a sine wave. Configured. The said conversion part (23) is comprised so that the output voltage of the said power factor improvement part (22; 22A) may be converted into a DC voltage, and may be output. The control unit (24) is configured to light the light source (25) with a DC voltage output from the conversion unit (23). The power factor improving unit (22; 22A) has a function of reducing the current flowing through the lighting block (20; 20A) for a predetermined period (Td). The predetermined period (Td) is a period in which current (I30) flows from the AC power supply (40) to the circuit block connected in parallel to the lighting block (20; 20A) to the AC power supply (40). . According to the first aspect, it is possible to reduce current distortion while suppressing increases in cost and power consumption.

  The lighting device (10; 10A) of the second aspect can be realized by a combination with the first aspect. In the second aspect, the power factor improving section (22; 22A) includes a waveform shaping circuit (221) and a voltage shift circuit (222; 222A). In the waveform shaping circuit (221), the waveform of the current (I20) flowing through the lighting block (20; 20A) approaches a sine wave based on the detection voltage (Vin) proportional to the output voltage of the rectifier (21). In this way, the output voltage waveform of the rectifier (21) is shaped. The voltage shift circuit (222; 222A) reduces the current (I20) flowing through the lighting block (20; 20A) by changing the detection voltage (Vin) during the predetermined period (Td). Composed. According to the 2nd aspect, a power factor improvement part (22) can be implement | achieved with a simple structure, and the increase in cost can be suppressed.

  The lighting device (10) of the third aspect can be realized by a combination with the first or second aspect. In the third aspect, the lighting device (10) operates as electric power from the AC power supply (40) as the circuit block and controls the lighting block (20; 20A). Is further provided. The control block (30; 30A) includes a power supply unit (31, 32, 33) that generates an operating voltage of the control block (30; 30A) using electric power from the AC power supply (40). The power supply unit (31, 32, 33) includes a capacitor (32) for smoothing a voltage obtained by rectifying the AC voltage of the AC power supply (40). The predetermined period (Td) is a period during which the current (I30) from the AC power supply (40) flows through the capacitor (32). According to the third aspect, current distortion can be further reduced.

  The lighting device (10) of the fourth aspect can be realized by a combination with any one of the first to third aspects. In the fourth aspect, the lighting device (10) further includes a storage unit (2223) that stores period information for specifying the predetermined period (Td). The power factor improvement unit (22) is configured to identify the predetermined period (Td) based on the period information stored in the storage unit (2223). According to the 4th aspect, predetermined period (Td) can be determined with a simple structure, and the increase in cost can be suppressed.

  The lighting device (10A) of the fifth aspect can be realized by a combination with the third aspect. In the fifth aspect, the control block (30A) further includes a detection unit (36) for detecting a current (I30) flowing from the AC power supply (40) to the capacitor (32). The power factor improvement unit (22A) is configured to identify the predetermined period (Td) based on a period during which the current (I30) is detected by the detection unit (36). According to the fifth aspect, current distortion can be reliably reduced.

  The lighting device (10; 10A) of the sixth aspect can be realized by a combination with any one of the first to fifth aspects. In the sixth aspect, the power factor improving section (22; 22A) has a function of adjusting the amount of decrease in the current flowing through the lighting block (20; 20A). According to the sixth aspect, current distortion can be further reduced.

  The lighting fixture (100) of the seventh aspect includes any one of the lighting devices (10; 10A) of the first to sixth embodiments, and a fixture main body (110) that holds the lighting device (10; 10A). And comprising. According to the seventh aspect, it is possible to reduce current distortion while suppressing increases in cost and power consumption.

10, 10A lighting device 20, 20A lighting block 21 rectifying unit 22, 22A power factor improving unit 221 waveform shaping circuit 222 voltage shift circuit 2223 memory (storage unit)
23 Conversion Unit 24 Control Unit 25 Light Source 30, 30A Control Block 32 Smoothing Unit (Condenser)
36 detector 40 AC power supply 100 lighting fixture 110 fixture body I20 current I30 current Td predetermined period Vin detection voltage

Claims (7)

Equipped with a lighting block that turns on the light source with power from the AC power supply,
The lighting block is
A rectifying unit for rectifying the AC voltage of the AC power source;
A power factor improving unit that shapes the waveform of the output voltage of the rectifying unit so that the waveform of the current flowing through the lighting block approaches a sine wave;
A converter that converts the output voltage of the power factor improving unit into a DC voltage and outputs the DC voltage;
A controller that turns on the light source with a DC voltage output from the converter;
Have
The power factor improving unit has a function of reducing a current flowing through the lighting block during a predetermined period in which a current flows from the AC power source to a circuit block connected to the AC power source in parallel with the lighting block.
Lighting device. The power factor improving unit is
Based on a detection voltage proportional to the output voltage of the rectifier, a waveform shaping circuit that shapes the waveform of the output voltage of the rectifier so that the waveform of the current flowing through the lighting block approaches a sine wave;
A voltage shift circuit that reduces the current flowing through the lighting block by changing the detection voltage during the predetermined period;
Having
The lighting device according to claim 1. As the circuit block, further comprising a control block that operates by power from the AC power supply to control the lighting block,
The control block has a power supply unit that generates an operating voltage of the control block with power from the AC power supply,
The power supply unit has a capacitor for smoothing a voltage obtained by rectifying the AC voltage of the AC power supply,
The predetermined period is a period in which a current from the AC power source flows through the capacitor.
The lighting device according to claim 1 or 2. A storage unit for storing period information for specifying the predetermined period;
The power factor improvement unit is configured to identify the predetermined period based on period information stored in the storage unit.
The lighting device according to claim 1. The control block further includes a detection unit that detects a current flowing from the AC power source to the capacitor,
The power factor improvement unit is configured to identify the predetermined period based on a period during which the current is detected by the detection unit.
The lighting device according to claim 3. The power factor improvement unit has a function of adjusting the amount of decrease in the current flowing through the lighting block.
The lighting device according to claim 1. A lighting device according to any one of claims 1 to 6;
An instrument body holding the lighting device;
Comprising
lighting equipment.

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