JP6052674B2 - LED lighting device, lighting fixture using the same, and lighting system - Google Patents

Description

  The present invention relates to an LED lighting device, a lighting fixture using the same, and a lighting system.

  Conventionally, there is an LED lighting device that turns on an LED unit having a light emitting diode (LED (Light Emitting Diode) element) as a light source. FIG. 8 shows a circuit configuration diagram of a conventional LED lighting device. This LED lighting device turns on the LED unit 107 using the AC power source E101 as an input power source. The LED lighting device mainly includes a rectifier circuit 101, a power factor correction circuit 102, a PFC control circuit 103, a step-down converter circuit 104, and a step-down converter control circuit 105. Below, each structure of the conventional LED lighting device is demonstrated.

  The rectifier circuit 101 is constituted by a diode bridge circuit including a plurality of diodes (not shown). The rectifier circuit 101 rectifies the AC voltage applied from the AC power source E101 and outputs the rectified voltage to the subsequent power factor correction circuit 102.

  The power factor correction circuit 102 (PFC (Power Factor Correction) circuit) is composed of a boost chopper circuit. Then, a switching element (not shown) is subjected to switching control by the PFC control circuit 103, thereby generating a DC voltage obtained by boosting the output voltage of the rectifier circuit 101 and outputting the DC voltage to the subsequent step-down converter circuit 104.

  The step-down converter circuit 104 mainly includes a switching element Q101, an inductor L101, a capacitor C101, and a diode D101. Specifically, a series circuit of a switching element Q101 composed of an n-channel MOSFET, an inductor L101, a smoothing capacitor C101, and a current detection resistor R101 is connected between output terminals of the power factor correction circuit 102. A regenerative diode D101 is connected in parallel with the series circuit of the inductor L101, the capacitor C101, and the resistor R101. In addition, an LED unit 107 composed of a plurality of LED elements is connected in parallel with the capacitor C101. The switching element Q101 is subjected to switching control by the step-down converter control circuit 105, whereby the output voltage of the power factor correction circuit 102 is stepped down and applied to the LED unit 107. As a result, a DC LED current is supplied to the LED unit 107 to light it.

  The step-down converter control circuit 105 performs constant current control of the LED current by controlling the switching of the switching element Q101 based on the voltage across the resistor R101 (corresponding to the LED current).

  By the way, in order to improve safety, an LED lighting device that detects whether or not an LED unit (LED lamp) is mounted and stops the power circuit when the LED unit is not mounted has been proposed (for example, Patent Documents). 1).

JP 2012-160321 A

  However, the output of the LED lighting device of Patent Document 1 corresponds to only one LED unit, and it has not been considered that one or more detachable LED units are connected. When the number of connected LED units is one or more, it is necessary to widen the output voltage range of the LED lighting device, which causes problems such as increased stress of circuit components and generation of noise. .

  The present invention has been made in view of the above reasons, and its purpose is to prevent inconveniences such as increased stress of circuit components and generation of noise even when one or more LED units are connected. Another object of the present invention is to provide an LED lighting device that can be used, and a lighting fixture and a lighting system using the same.

  The LED lighting device of the present invention includes a plurality of output connectors connected in series between output terminals, a step-down converter circuit that supplies a direct current to the LED unit or the dummy unit connected to each of the output connectors, A step-down converter control circuit for controlling the output of the step-down converter circuit, and a number determination circuit for determining the number of the LED units connected to the output connector, the LED unit comprising: a light emitting unit comprising an LED element; and A first resistor connected in parallel to the light emitting unit; the dummy unit includes a second resistor having a resistance value different from a resistance value of the first resistor; Based on the resistance between both ends of the series circuit composed of the output connector, the number of connected LED units is determined, and the step-down converter control circuit is Depending on the connection number of the LED unit in which the number discriminating circuit has determined, and controlling the output of the buck converter circuit.

  In this LED lighting device, it is preferable that the step-down converter control circuit performs constant current control on the output current of the step-down converter circuit.

  In this LED lighting device, it is preferable that the step-down converter control circuit reduces the output current of the step-down converter circuit when the number of connected LED units is equal to or less than a first threshold value.

  In this LED lighting device, the output voltage of the step-down converter circuit is compared with a second threshold value, and when the output voltage of the step-down converter circuit is equal to or higher than the second threshold value, it is determined that the output is abnormal. The step-down converter control circuit comprising: an abnormality determination circuit; and a threshold control circuit that reduces the second threshold when the number of connected LED units determined by the number determination circuit is equal to or less than a third threshold. When the abnormality determination circuit determines that the output abnormal state is present, it is preferable to reduce the output of the step-down converter circuit.

  In this LED lighting device, it is preferable that the LED units connected to the output connector have the same specifications.

  In this LED lighting device, it is preferable that a resistance value of the second resistor is smaller than a resistance value of the first resistor.

  The lighting fixture of the present invention includes a plurality of output connectors connected in series between output terminals, a step-down converter circuit that supplies a direct current to an LED unit or a dummy unit connected to each of the output connectors, and the step-down converter A step-down converter control circuit for controlling an output of the converter circuit; and a number determination circuit for determining the number of the LED units connected to the output connector, wherein the LED unit includes a light emitting unit including an LED element, and the light emission A first resistor connected in parallel to the unit, the dummy unit includes a second resistor having a resistance value different from a resistance value of the first resistor, and the number determination circuit includes a plurality of the resistances Based on the resistance between both ends of the series circuit consisting of the output connector, the number of connections of the LED unit is determined, the step-down converter control circuit, An LED lighting device that controls the output of the step-down converter circuit according to the number of connected LED units determined by a number determining circuit, a light emitting unit composed of LED elements, and a first resistor connected in parallel to the light emitting unit And an LED unit to which a direct current is supplied from the LED lighting device, and an appliance main body to which the LED lighting device and the LED unit are attached.

  The lighting system of the present invention includes a plurality of output connectors connected in series between output terminals, a step-down converter circuit that supplies a direct current to an LED unit or a dummy unit connected to each of the output connectors, and the step-down converter A step-down converter control circuit for controlling an output of the converter circuit; and a number determination circuit for determining the number of the LED units connected to the output connector, wherein the LED unit includes a light emitting unit including an LED element, and the light emission A first resistor connected in parallel to the unit, the dummy unit includes a second resistor having a resistance value different from a resistance value of the first resistor, and the number determination circuit includes a plurality of the resistances Based on the resistance between both ends of the series circuit consisting of the output connector, the number of connections of the LED unit is determined, the step-down converter control circuit, The LED lighting device for controlling the output of the step-down converter circuit according to the number of connected LED units determined by the number determining circuit, a light emitting unit composed of LED elements, and a first connected in parallel to the light emitting unit A plurality of lighting fixtures each having a resistor and including a LED unit to which a direct current is supplied from the LED lighting device, a fixture main body to which the LED lighting device and the LED unit are attached, and a plurality of the lighting fixtures. And a controller.

  As described above, according to the present invention, the number of connected LED units is determined, and output control is performed according to the number of connected LED units. This is the case when one or more LED units are connected. However, it is possible to prevent problems such as increased stress of circuit components and generation of noise.

It is a circuit block diagram of the LED lighting device of Embodiment 1 of this invention. It is a circuit block diagram of the LED lighting device of another structure same as the above. (A) It is a wave form diagram of a drive signal. (B) It is a wave form diagram of inductor current. (C) It is a wave form diagram of LED current. (A) It is a wave form diagram of a drive signal. (B) It is a wave form diagram of inductor current. (C) It is a wave form diagram of LED current. It is a circuit block diagram of the LED lighting device of Embodiment 3. It is an external appearance perspective view of the lighting fixture of Embodiment 4. It is sectional drawing of a lighting fixture same as the above. It is a circuit block diagram of the conventional LED lighting device.

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

(Embodiment 1)
The circuit block diagram of the LED lighting device of this embodiment is shown in FIG. The LED lighting device of the present embodiment is for lighting the LED unit 7 using the AC power source E1 as an input power source. The LED lighting device according to the present embodiment mainly includes a rectifier circuit 1, a power factor correction circuit 2, a PFC control circuit 3, a step-down converter circuit 4, a step-down converter control circuit 5, and a number discrimination circuit 6. Below, each structure of an LED lighting device is demonstrated.

  The rectifier circuit 1 is composed of a diode bridge circuit composed of a plurality of diodes (not shown). The rectifier circuit 1 rectifies the AC voltage applied from the AC power source E1 that is a commercial power source and outputs the rectified voltage to the power factor improving circuit 2 at the subsequent stage.

  The power factor correction circuit 2 (PFC (Power Factor Correction) circuit) is composed of a step-up chopper circuit mainly including a transformer T1, a switching element Q1, a diode D1, and a capacitor C1. Specifically, a series circuit of a switching element Q1 composed of a primary winding n1 of an transformer T1, an n-channel MOSFET, and a current detection resistor R1 is connected between output terminals of the rectifier circuit 1. A series circuit of a backflow prevention diode D1 and a smoothing capacitor C1 is connected in parallel with the series circuit of the switching element Q1 and the resistor R1. The switching element Q1 has a gate connected to the PFC control circuit 3 via a resistor R2. The power factor correction circuit 2 generates a desired DC voltage obtained by boosting the output voltage of the rectifier circuit 1 by switching control (on / off drive) of the switching element Q1 by the PFC control circuit 3, Output to the step-down converter circuit 4.

  The PFC control circuit 3 performs switching control of the switching element Q1 based on the following input parameters. A series circuit of resistors R3 and R4 is connected between the output terminals of the rectifier circuit 1. The PFC control circuit 3 detects the input voltage value of the power factor correction circuit 2 by detecting the resistance voltage division of the output voltage of the rectifier circuit 1 by the resistors R3 and R4. The secondary winding n2 of the transformer T1 has one end connected to the circuit ground and the other end connected to the PFC control circuit 3 via the resistor R5. The PFC control circuit 3 detects the value of the current flowing through the primary winding n1 by detecting the voltage across the secondary winding n2. The connection point between the switching element Q1 and the resistor R1 is connected to the PFC control circuit 3 via the resistor R6. The PFC control circuit 3 detects the value of the current flowing through the switching element Q1 by detecting the voltage across the resistor R1. In addition, a series circuit of resistors R7 and R8 is connected in parallel with the capacitor C1. Then, the PFC control circuit 3 detects the output voltage value of the power factor correction circuit 2 by detecting the resistance voltage division of the voltage across the capacitor C1 (the output voltage of the power factor improvement circuit 2) by the resistors R7 and R8. .

  The PFC control circuit 3 then switches the switching element based on the input voltage value of the power factor correction circuit 2, the current value flowing through the primary winding n1, the current value flowing through the switching element Q1, and the output voltage value of the power factor correction circuit 2. Q1 is turned on / off (switching control). When the switching element Q1 is driven on / off, the output voltage of the rectifier circuit 1 is boosted. In the present embodiment, the PFC control circuit 3 performs feedback control so that the output voltage value of the power factor correction circuit 2 becomes a desired voltage value. Note that the configuration and control of the power factor correction circuit 2 and the PFC control circuit 3 are well known in the art and will not be described in detail.

  The step-down converter circuit 4 mainly includes a switching element Q2, an inductor L1, a capacitor C2, and a diode D2. Specifically, a series circuit of a switching element Q2, an inductor L1, an inductor L1, a smoothing capacitor C2, and a current detection resistor R9, which are n-channel MOSFETs, is connected between the output terminals of the power factor correction circuit 2. A regenerative diode D2 is connected in parallel with the series circuit of the inductor L1, the capacitor C2, and the resistor R9. Switching element Q2 has a gate connected to step-down converter control circuit 5 via resistor R10. Further, a series circuit 42 including three output connectors 41 is connected between both ends of the capacitor C2 (between the output ends of the step-down converter circuit 4), and the LED unit 7 is connected to each of the output connectors 41. . The step-down converter circuit 4 generates a DC voltage obtained by stepping down the output voltage of the power factor correction circuit 2 by switching control (on / off driving) of the switching element Q2 by the step-down converter control circuit 5. The voltage is applied across the series circuit 42 composed of the output connector 41 (LED unit 7).

  The LED unit 7 includes a light emitting unit 71 and a resistor R11 (first resistor). The light emitting unit 71 is configured by connecting a plurality of light emitting diodes (LED (Light Emitting Diode) elements) (not shown) in series connection, parallel connection, or a combination of series and parallel. The resistor R11 is connected in parallel to the light emitting unit 71, and is used for determining the number of connected LED units 7 described later. Then, by connecting the LED unit 7 to each of the three output connectors 41, each light emitting unit 71 is connected in series with the capacitor C2, and the direct current LED current I1 is supplied from the step-down converter circuit 4 so that the LED is connected. The element emits light.

  Moreover, the LED lighting device of this embodiment respond | corresponds to increase / decrease in the number of connection of the LED unit 7. FIG. When the number of connected LED units 7 is smaller than the number of output connectors 41 (for example, when the number of connected LED units 7 is one), the dummy connector 72 is connected to the output connector 41 to which the LED unit 7 is not connected. Are connected (see FIG. 2). The dummy unit 72 includes a resistor R12 (second resistor) that connects a pair of terminals. The resistance value r12 of the resistor R12 is sufficiently smaller than the resistance value r11 of the resistor R11 of the LED unit 7, and is a value that can be regarded as a resistance value r12≈0Ω with respect to the resistance value r11 of the resistor R11. For example, when the resistance value r11 of the resistor R11 is 100 kΩ, if the resistance value r12 <1 kΩ, the resistance value r12 can be regarded as 0Ω.

  The step-down converter control circuit 5 performs feedback control so that the LED current I1 supplied to the LED unit 7 becomes a target value. Specifically, the resistor R9 is connected in series to a series circuit 42 including three output connectors 41, and the step-down converter control circuit 5 detects the voltage across the resistor R9, whereby the current value of the LED current I1. Is detected. The step-down converter circuit 5 performs constant current control of the LED current I1 by performing switching control of the switching element Q2 so that the LED current I1 becomes a target value. Further, the step-down converter control circuit 5 performs dimming control on the LED unit 7 by increasing or decreasing the target value of the LED current I1.

  The step-down converter control circuit 5 of the present embodiment performs switching control of the switching element Q2 using a frequency fixing method that turns on the switching element Q2 at a predetermined cycle. The frequency fixing method will be described with reference to the timing charts shown in FIGS. FIG. 3A is a waveform diagram of the drive signal S1 output from the step-down converter control circuit 5 to the switching element Q2. FIG. 3B is a waveform diagram of the inductor current I2 flowing through the inductor L1. FIG. 3C is a waveform diagram of the LED current I1 flowing through the LED unit 7. First, the step-down converter control circuit 5 turns on the switching element Q2 by setting the drive signal S1 to the H level (time t0). When the switching element Q2 is turned on, a current flows to the capacitor C2 and each LED unit 7 via the inductor L1, and flows to the circuit ground via the resistor R9 for current detection. The step-down converter control circuit 5 detects the voltage across the resistor R9 and compares it with a threshold set based on the target value of the LED current I1. The step-down converter control circuit 5 turns off the switching element Q2 by setting the drive signal S1 to the L level when the voltage across the resistor R9 reaches the threshold value (time t1). When the switching element Q2 is turned off, the energy accumulated in the inductor L1 is released, and a regenerative current flows through the capacitor C2, each LED unit 7, and the diode D2. At time t2, all the energy stored in the inductor L1 is released, and the inductor current I2 becomes zero. Then, step-down converter control circuit 5 turns on switching element Q2 again at time t3 after a predetermined period from the timing (time t0) at which switching element Q2 was turned on last time. The step-down converter control circuit 5 performs constant current control so that the LED current I1 supplied to the LED unit 7 becomes a target value by repeating the above operation. Thus, in the frequency fixing method, the switching cycle (time t0 to t3) of the switching element Q2 is fixed. Furthermore, during one switching cycle of the switching element Q2, a conduction period T1 (time t0 to t2) in which current flows through the inductor L1, and a rest period T2 (time t2 to t3) in which no current flows through the inductor L1. Is a method provided.

  Here, when the step-down converter control circuit 5 performs switching control of the switching element Q2 using the frequency fixing method described above, the number of connections of the LED units 7 and the LED current I1 increase or decrease, so that the conduction period T1 is as follows. fluctuate.

  When the number of connected LED units 7 is large, the output voltage of the step-down converter circuit 4 (the voltage across the capacitor C2) becomes high, and the conduction period T1 becomes short. On the other hand, when the number of connected LED units 7 is small, the output voltage of the step-down converter circuit 4 becomes low and the conduction period T1 becomes long. Further, when the LED current I1 is large, the conduction period T1 becomes long. On the other hand, when the LED current I1 is small, the conduction period T1 is shortened.

  Therefore, when the number of LED units 7 connected is small and the LED current I1 is large (for example, when the number of LED units 7 connected is one and the LED unit 7 is fully lit (the LED current I1 is lit when rated)). The conduction period T1 becomes too long. As a result, as shown in FIGS. 4A to 4C, the switching element Q2 is turned on and the next switching is started during the period in which the inductor L1 flows the regenerative current (time t1a to t3 in FIG. 4). Will be in continuous mode. When the step-down converter circuit 4 operates in the continuous mode, there is a problem in that excessive stress occurs in components such as the switching element Q2 and the diode D2, leading to circuit failure.

  Therefore, the LED lighting device of the present embodiment includes a number discrimination circuit 6 that discriminates the number of connected LED units 7, and varies the target value of the LED current I1 according to the number of connected LED units 7.

  The number discriminating circuit 6 mainly includes a constant voltage generating circuit 61, a number detecting circuit 62, and a comparing circuit 63. Between the output terminals of the power factor correction circuit 2 (between both ends of the capacitor C1), a series circuit of a resistor R13, a constant voltage generation circuit 61, and the above-described current detection resistor R9 is connected. The constant voltage generation circuit 61 includes a Zener diode ZD1, and generates a predetermined constant voltage from the output voltage of the power factor correction circuit 2. In parallel with the constant voltage generation circuit 61, a series circuit of a resistor R14 and three output connectors 41 is connected. The number detection circuit 62 is constituted by a series circuit of a resistor R15, a resistor R16, and a resistor R17, and is connected in parallel with a series circuit of three output connectors 42 and a resistor R9. The connection point between the resistor R16 and the resistor R17 is connected to the comparison circuit 63. With the above configuration, the constant voltage generation circuit 61 generates a predetermined voltage across the series circuit 42 including the three output connectors 41. Then, the number detection circuit 62 outputs the resistance divided value of the voltage across the series circuit 42 to the comparison circuit 63 as a number detection signal. The comparison circuit 63 determines the number of connected LED units 7 by comparing the signal level of the number detection signal with a threshold value, and outputs the determination result to the step-down converter control circuit 5.

  Here, the voltage across the series circuit 42 is determined by the resistance across the series circuit 42. The LED unit 7 or the dummy unit 72 is connected to the output connector 41 (see FIGS. 1 and 2). As described above, the resistance value r12 of the resistor R12 included in the dummy unit 72 is set to a value sufficiently smaller than the resistance value r11 of the resistor R11 included in the LED unit 7. Therefore, as the number of connected LED units 7 increases, the resistance across the series circuit 42 increases and the voltage across the series circuit 42 also increases. As the voltage across the series circuit 42 increases, the signal level of the number detection signal output from the number detection circuit 62 also increases. In addition, a threshold value corresponding to the number of connected LED units 7 is set in the comparison circuit 63 in advance. Then, the comparison circuit 63 can determine the number of connected LED units 7 by comparing a preset threshold value with the signal level of the number detection signal. The value of the constant voltage generated by the constant voltage generation circuit 61 is set to a value at which the light emitting unit 71 of the LED unit 7 is not lit by this constant voltage.

  In the present embodiment, when the LED lighting device is turned on from the AC power supply E1, the step-down converter control circuit 5 obtains the connection number information of the LED units 7 from the comparison circuit 63 before starting the operation of the step-down converter circuit 4. get. Then, the step-down converter control circuit 5 sets a target value of the LED current I1 based on the number of LED units 7 connected. When the number of connected LED units 7 is larger than one (first threshold) (for example, when the number of connected LED units 7 is three as shown in FIG. 1), the step-down converter control circuit 5 The target value of the current I1 is set to the rated value, and the LED unit 7 is fully lit. On the other hand, when the number of connected LED units 7 is 1 (first threshold) or less (for example, when the number of connected LED units 7 is 1 as shown in FIG. 2), the step-down converter control circuit 5 Sets the target value of the LED current I1 lower than the rated value, and causes the LED unit 7 to be dimmed. If the number of LED units 7 connected is one and the target value of the LED current I1 is set to the rated value, as described above, the conduction period T1 is smaller than that when the number of LED units 7 connected is three. The operation mode of the step-down converter circuit 4 becomes a continuous mode (see FIG. 4). However, in this embodiment, when the number of connected LED units 7 is small (when the number of connected LED units 7 is 1 or less), the target value of the LED current I1 is set lower than the rated value. Thereby, it is possible to suppress the conduction period T1 from becoming too long, and to prevent the operation mode of the step-down converter circuit 4 from becoming the continuous mode. When the number of LED units 7 connected is zero, the step-down converter control circuit 5 stops the operation of the step-down converter circuit 4.

  Thus, in this embodiment, the number of LED units 7 connected is determined, and the LED current I1 is reduced when the number of LED units 7 connected is small. Thereby, even when the step-down converter circuit 4 is operated in a fixed frequency system, the transition to the continuous mode due to the small number of LED units 7 connected can be prevented. Therefore, excessive stress on components such as the switching element Q2 and the diode D2 can be suppressed, and circuit failure can be prevented and safety can be improved.

  Note that the LED lighting device of the present embodiment includes three output connectors 41, and a maximum of three LED units 7 can be connected. However, the number of output connectors 41 and the maximum number of LED units 7 that can be connected are three. It is not limited to individual.

  In the present embodiment, the LED current I1 is reduced when the number of LED units 7 connected is one (first threshold), but the first threshold is not limited to one. For example, when the number of connected LED units 7 is two or less, the LED current I1 may be reduced. Moreover, you may comprise so that LED current I1 may be reduced in steps as the number of LED units 7 connected decreases.

  Further, the configuration of the constant voltage generation circuit 61 is not limited to the Zener diode ZD1, and may be configured by, for example, a conventionally known regulator circuit capable of generating a constant voltage.

  Further, the power factor correction circuit 2 of the present embodiment is configured such that the input side and the output side are not insulated. Therefore, even before the operation of the power factor correction circuit 2, the constant voltage generation circuit 61 can generate a constant voltage when the LED lighting device is turned on from the AC power supply E1, and the LED unit 7 can be connected. The number can be determined.

(Embodiment 2)
The LED lighting device of the first embodiment operates the step-down converter circuit 4 using the frequency fixing method, whereas the LED lighting device of the present embodiment operates the step-down converter circuit 4 using the critical control method. Since the configuration of the LED lighting device is the same as that of the first embodiment (see FIGS. 1 and 2), description thereof is omitted.

  The step-down converter control circuit 5 of the present embodiment performs constant current control with the LED current I1 at a target value by performing switching control of the switching element Q2 using a critical control method that turns on the switching element Q2 when the inductor current I2 becomes zero. doing.

  Here, when the step-down converter control circuit 5 performs switching control of the switching element Q2 using the critical control method, the switching frequency of the switching element Q2 is as follows by increasing / decreasing the number of connected LED units 7 and the LED current I1. Fluctuates.

  When the number of connected LED units 7 is large, the output voltage of the step-down converter circuit 4 becomes high and the switching frequency becomes high. On the other hand, when the number of connected LED units 7 is small, the output voltage of the step-down converter circuit 4 is lowered and the switching frequency is lowered. Further, when the LED current I1 is increased, the switching frequency is set high. On the other hand, when the LED current I1 is reduced, the switching frequency is set low.

  Therefore, when the number of connected LED units 7 is small and the LED current I1 is large (for example, when the number of connected LED units 7 is one and all lights up), the switching frequency becomes low and approaches the frequency of the audible range. There was a problem that occurred.

  Therefore, in this embodiment, when the LED lighting device is powered from the AC power supply E1, the step-down converter control circuit 5 connects the number of LED units 7 to the comparison circuit 63 before starting the operation of the step-down converter circuit 4. Get information. Then, the step-down converter control circuit 5 sets a target value of the LED current I1 based on the number of LED units 7 connected. The method for determining the number of connected LED units 7 is the same as in the first embodiment.

  When the number of connected LED units 7 is larger than one (first threshold) (for example, when the number of connected LED units 7 is three as shown in FIG. 1), the step-down converter control circuit 5 The target value of the current I1 is set to the rated value, and the LED unit 7 is fully lit. On the other hand, when the number of connected LED units 7 is 1 (first threshold) or less (for example, when the number of connected LED units 7 is 1 as shown in FIG. 2), the step-down converter control circuit 5 Sets the target value of the LED current I1 lower than the rated value, and causes the LED unit 7 to be dimmed. If the number of connected LED units 7 is one and the target value of the LED current I1 is set to the rated value, the switching frequency approaches the audible range as described above, and noise may occur. However, in this embodiment, when the number of connected LED units 7 is 1 or less, the target value of the LED current I1 is set lower than the rated value, and the LED unit 7 is dimmed. Thereby, it can suppress that a switching frequency becomes low too much and generation | occurrence | production of a noise can be prevented. When the number of LED units 7 connected is zero, the step-down converter control circuit 5 stops the operation of the step-down converter circuit 4.

  Thus, in the present embodiment, the number of LED units 7 connected is determined, the LED current I1 is set to the rated value when the number of LED unit connections is large, and the LED current when the number of LED unit 7 connections is small. I1 is set lower than the rated value. Thereby, even when the step-down converter circuit 4 is operated by the critical control method, it is possible to prevent the generation of noise due to the small number of LED units 7 connected.

  Furthermore, in this embodiment, when the number of LED units 7 connected is large (when the number of LED units 7 connected is more than one), the target value of the LED current I1 is set to the rated value, so that the switching frequency is It can suppress becoming too high. Therefore, the fluctuation range of the switching frequency is not excessively widened, and the design constraints of the step-down converter circuit 4 can be reduced.

  In this embodiment, the LED current I1 is reduced when the number of LED units 7 connected is one (first threshold), but the first threshold is not limited to one. For example, when the number of connected LED units 7 is two or less, the LED current I1 may be reduced. Moreover, you may comprise so that LED current I1 may be reduced in steps as the number of LED units 7 connected decreases.

(Embodiment 3)
The circuit block diagram of the LED lighting device of this embodiment is shown in FIG. The LED lighting device of this embodiment includes a protection circuit 8 that stops the step-down converter circuit 4 when the output of the step-down converter circuit 4 is abnormal, in addition to the configurations of the LED lighting devices of the first and second embodiments. Since other configurations are the same as those of the first and second embodiments, the same components as those of the first and second embodiments are denoted by the same reference numerals and description thereof is omitted.

  The protection circuit 8 includes an output detection circuit 81 and an abnormality determination circuit 82 as main components. The output detection circuit 81 includes a series circuit of a resistor R18, a resistor R19, and a resistor R20, and is connected in parallel with the series circuit of the capacitor C2 and the resistor R9. A connection point between the resistor R19 and the resistor R20 is connected to the abnormality determination circuit 82. That is, the output detection circuit 81 outputs the resistance voltage division value of the output voltage of the step-down converter circuit 4 (the voltage across the capacitor C2) to the abnormality determination circuit 82 as an output voltage detection signal. Then, the abnormality determination circuit 82 compares the signal level of the output voltage detection signal with a threshold value (second threshold value). The abnormality determination circuit 82 determines that the step-down converter circuit 4 is in an output abnormal state when the signal level of the output voltage detection signal is greater than or equal to the threshold, and the step-down converter when the signal level of the output voltage detection signal is less than the threshold. The circuit 4 determines that the output is in a normal state. When the abnormality determination circuit 82 determines that the step-down converter circuit 4 has an abnormal output voltage, the step-down converter control circuit 5 reduces or stops the output of the step-down converter circuit 4.

  Here, the output voltage of the step-down converter circuit 4 increases or decreases according to the number of connected LED units 7. As the number of LED units 7 connected increases, the output voltage of the step-down converter circuit 4 also increases. Therefore, conventionally, it is necessary to set a threshold value based on the output voltage when the number of connected LED units 7 is the largest, and to prevent erroneous determination when the output is normal. However, when the threshold value is set in this way, when the number of connected LED units 7 is small, the difference between the signal level of the output voltage detection signal at normal time (resistance voltage division value of the output voltage) and the threshold value increases. Therefore, even if an abnormal connection of the LED unit 7 (for example, bad contact (contact failure)) occurs and the output voltage rises, there is a possibility that this abnormal output state cannot be detected, and excessive stress occurs in the LED unit 7. There was a problem to do.

  Therefore, in the present embodiment, the step-down converter control circuit 5 varies the threshold value (second threshold value) set in the abnormality determination circuit 82 based on the number of connected LED units 7. The method for determining the number of connected LED units 7 is the same as in the first and second embodiments. In the present embodiment, the step-down converter control circuit 5 also functions as a threshold control circuit that sets the threshold value (second threshold value) of the abnormality determination circuit 82.

  The step-down converter control circuit 5 gradually reduces the threshold value set in the abnormality determination circuit 82 as the number of connected LED units 7 decreases. For example, when the number of connected LED units 7 is 1 (third threshold value), the step-down converter control circuit 5 sets the threshold value lower than when the number of connected LED units 7 is 3. As described above, in the present embodiment, the step-down converter control circuit 5 varies the threshold value (second threshold value) set in the abnormality determination circuit 82 in accordance with the output voltage that varies according to the number of connected LED units 7. . Thereby, even when the number of connected LED units 7 is small, the difference between the signal level of the output voltage detection signal and the threshold value at the normal time does not widen. Therefore, the abnormality determination circuit 82 can more reliably detect the output abnormal state of the step-down converter circuit 4 due to the failure of the LED unit 7 or the connection abnormality, so that the output increase of the step-down converter circuit 4 is suppressed and safety is improved. Can be improved.

(Embodiment 4)
FIG. 6 is an external perspective view of the lighting fixture of this embodiment, and FIG. 7 is a cross-sectional view thereof. The lighting fixture of this embodiment is comprised by the LED lighting device 10 in any one of Embodiment 1-3, the LED unit 7 attached to the LED lighting device 10, and the fixture main body 11. FIG. In addition, although the LED lighting device of Embodiment 1-3 was demonstrated as an apparatus which can connect 1 to 3 LED units 7, the LED lighting device used for the lighting fixture of this embodiment is LED unit 7. One to four can be connected.

  The instrument body 11 is formed in a rectangular box shape, and is embedded in an opening provided in the ceiling 20 so that a lower surface thereof is flush with the ceiling 20. The appliance main body 11 houses the LED lighting device 10 and the LED unit 7. The LED lighting device 10 is fixed to the bottom surface of the fixture main body 11, and the output connector 41 led out from the LED lighting device 10 via the cable 43 is held by the structural material 12 provided in the fixture main body 11. Yes. The LED unit 7 or the dummy unit 72 is connected to each output connector 41. In the example shown in FIG. 7, two output connectors 41 are illustrated. The LED unit 7 is connected to one output connector 41, and the dummy unit 72 is connected to the other output connector 41. Further, the LED unit 7 not connected to the output connector 41 can be turned on by removing the dummy unit 72 from the output connector 41 and connecting a connector (not shown) to the output connector 41.

  Moreover, the lower surface of the instrument main body 11 has openings formed in a 3 × 3 grid shape, and four LED units 7 and five makeup plates 8 are attached so as to be exposed from the openings. As shown in FIG. 6, the LED units 7 are disposed at the four corners of the lower surface of the instrument body 11, and the plate 8 is disposed between the LED units 7 in a cross shape. The LED unit 7 includes a box-shaped housing 73 whose bottom surface is open and a substrate 74 on which the light emitting unit 71 and the resistor R11 are mounted. A translucent cover 75 is provided so as to cover the opening of the housing 73. It consists of

  The lighting fixture of this embodiment is provided with LED lighting device 10 in any one of Embodiments 1-3, and can obtain the same effect as in any one of Embodiments 1-3.

  Moreover, even if it is a case where a lighting system is comprised by the some lighting fixture mentioned above and the controller (not shown) which controls the lighting state of these lighting fixtures, etc., it is the same as that of any one of Embodiment 1-3. An effect can be obtained.

DESCRIPTION OF SYMBOLS 1 Rectification circuit 2 Power factor improvement circuit 3 PFC control circuit 4 Buck converter circuit 41 Output connector 5 Buck converter control circuit 6 Number discrimination circuit 61 Constant voltage generation circuit 62 Number detection circuit 63 Comparison circuit 7 LED unit 71 Light emission part R11 Resistance (first) 1 resistance)
R12 resistor (second resistor)

Claims (8)

A step-down converter circuit that has a plurality of output connectors connected in series between output terminals, and supplies a direct current to the LED unit or the dummy unit connected to each of the output connectors;
A step-down converter control circuit for controlling the output of the step-down converter circuit;
A number discriminating circuit for discriminating the number of the LED units connected to the output connector;
The LED unit has a light emitting unit composed of LED elements, and a first resistor connected in parallel to the light emitting unit,
The dummy unit has a second resistor having a resistance value different from the resistance value of the first resistor,
The number discriminating circuit discriminates the connection number of the LED units based on resistance between both ends of a series circuit composed of a plurality of the output connectors,
The step-down converter control circuit controls the output of the step-down converter circuit in accordance with the number of connected LED units determined by the number determination circuit. The LED lighting device according to claim 1, wherein the step-down converter control circuit performs constant current control on an output current of the step-down converter circuit. The LED lighting device according to claim 1, wherein the step-down converter control circuit reduces the output current of the step-down converter circuit when the number of connected LED units is equal to or less than a first threshold value. An abnormality determination circuit that compares the output voltage of the step-down converter circuit with a second threshold value, and determines that the output abnormal state is present when the output voltage of the step-down converter circuit is equal to or greater than the second threshold value;
A threshold control circuit for reducing the second threshold when the number of connected LED units determined by the number determination circuit is equal to or less than a third threshold;
4. The step-down converter control circuit reduces the output of the step-down converter circuit when the abnormality determination circuit determines that the output abnormality state is present. 5. LED lighting device according to the description. The LED lighting devices according to any one of claims 1 to 4, wherein the LED units connected to the output connector have the same specifications. 6. The LED lighting device according to claim 1, wherein a resistance value of the second resistor is smaller than a resistance value of the first resistor. The LED lighting device according to any one of claims 1 to 6,
An LED unit having a light emitting unit composed of an LED element and a first resistor connected in parallel to the light emitting unit, to which a direct current is supplied from the LED lighting device;
A lighting fixture comprising: the LED lighting device; and a fixture main body to which the LED unit is attached. A plurality of lighting fixtures according to claim 7;
And a controller for controlling the plurality of lighting fixtures.

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