KR20110114787A - The led lighting system - Google Patents

Abstract

The present invention is to collectively adjust the illuminance of the LED lighting device in proportion to the AC input voltage adjusted to the reference value while minimizing the change or addition of the configuration in the state of installing a large number of LED lighting devices, LED lighting within this range The illuminance of the device can be individually controlled by adjusting the reference value of the corresponding DC output current, while if the reference value is exceeded, the illuminance of the LED lighting device is kept constant regardless of the change of the AC input voltage. The aim is to provide an LED lighting system that compensates for power factor through the PFC IC even if the AC input voltage changes during the process.
In order to realize the above object, the present invention is connected to a plurality of LED lighting device power input terminal in parallel, the input voltage adjusting unit for adjusting the magnitude of the AC voltage input for adjusting the overall illuminance of the LED lighting load; And a feedback output current adjusting unit connected to input terminals of the plurality of LED lighting device output current feedback units to adjust the magnitude of the DC current input to the PFC IC for individual illumination control of the corresponding LED lighting load. In the PFC IC, an internal error amplifier inverting terminal connected to an INV terminal is connected to a ground terminal through a first resistor, and a reference value is applied to a non-inverting terminal so that the output of the internal error amplifier always corresponds to a reference value. It is kept constant and the output terminal of the output current feedback unit is connected to the COMP terminal, and the value corresponding to the reference value is output from the internal error amplifier of the PFC IC until the output value of the LED lighting load becomes the reference value. And collectively adjust the illumination of a plurality of LED lighting devices in proportion to the adjusted AC voltage, and within the range, the feedback output current adjusting unit It provides an LED lighting system characterized in that by adjusting the reference value of the output current feedback unit to adjust the illumination of the corresponding LED lighting load individually.

Description

LED lighting system {The LED lighting system}

The present invention relates to LED lighting, and more particularly, to an LED lighting system that can be selectively or individually adjusted the illumination of a plurality of installed LED lighting device as needed.

In general, as shown in FIG. 1, the LED lighting device applies a power factor correction IC (PFC IC) to supply a constant DC power to the LED lighting load while maintaining the power factor of the applied AC power.

The conventional LED lighting device 10, the LED lighting load including the LED is connected in parallel and in parallel, the AC power is rectified by the input of the switching element Q according to the operation of the switching element Q in the inductor L1, diode D1 and capacitor C1 A converter unit 11 for outputting DC power to a load, an output current feedback unit 12 for feeding back an output current of an LED lighting load operated by the converter unit 11, and the output current feedback unit 12 While maintaining the output current of the constant compared to the reference value while the switching of the switching element Q to detect the zero point of the current flowing into the inductor L2 magnetically coupled to the inductor L1 of the converter unit 11 to compensate for the power factor. It consists of the PFC IC 13 which controls.

The converter unit 11 includes a bridge diode BD connected to an AC voltage input terminal, an inductor L1 connected to one end of the bridge diode BD, a diode D1 connected to the other end of the inductor L1, and one end connected to a cathode of the diode D1. A capacitor C1 having the other end connected to the ground terminal, a resistor R1 having one end connected to the bridge diode BD, a resistor R2 having one end connected to the other end of the resistor R1 and the other end connected to the ground terminal, and a resistor R3 having one end connected to the bridge diode BD Capacitor C2, one end of which is connected to the other end of the resistor R3 and the other end of which is connected to the ground terminal, the inductor L2 of which one end is connected to the ground terminal and magnetically connected to the inductor L1 to form a transformer, and one end of the anode is at the other end of the inductor L2 Diode D2, with the cathode connected to the resistor R3 and the capacitor C2, the drain connected to the inductor L1 and diode D1 gradually. The switch includes a switching element Q connected to the ground terminal through a resistor R4.

The output current feedback unit 12 is connected to the LED lighting load in one end in series and maintains the output current of the LED lighting load in series, and the other end is connected to the ground terminal from the voltage drop of the resistor R5. The other end of the resistor R5 is connected to detect the output current and to be applied to the INV terminal of the PFC IC 13.

The PFC IC 13 includes an input terminal of an INV terminal, a COMP terminal, a MULT terminal, a CS terminal, a ZCD terminal, an output terminal of a GD terminal, and L6561, L6562, L6563, and Fairchild Semiconductor of ST Microelectronics having a VCC and a GND terminal. FAN 7527, FAN 7528, FAN 7529, etc. can be used, internally includes an error amplifier (ERROR-AMP), multiplier (MULTIPLIER), comparator (COMPARATOR), flip-flop (FLIP / FLOP), driver (DRIVER) .

The INV terminal receives a voltage corresponding to the output current detected by the resistor R5 inserted in series with the LED lighting load and applies it to the inverting terminal (-) of the internal error amplifier ERROR-AMP. Here, the reference voltage (Ref-V) is applied to the non-inverting terminal (+) of the error amplifier (ERROR-AMP) to maintain the voltage corresponding to the output current input through the INV terminal at the set reference value. Capacitor C3 is connected to the COMP terminal, the output of the amplifier (ERROR-AMP), to ensure operational stability.

The MULT terminal is connected to a resistor R1, which is a voltage divider, and a resistor R2, and sends the output value of the rectified power supply voltage to a multiplier. The multiplier multiplies the power supply voltage output value of the MULT terminal by the output value of the internal error amplifier and applies it to the inverting terminal (-) of the comparator.

The CS terminal is connected to the resistor R4 and the source contact of the switching element Q to sense the current value flowing in the inductor L1 and input the corresponding voltage value to the non-inverting terminal (+) of the comparator. The comparator compares the values input to the multiplier and the CS terminal and sends a signal to the flip-flop FLIP / FLOP which causes the reset state when the value of the CS terminal is large.

The ZCD terminal is connected to the other end of the inductor L2, and magnetically connected to the inductor L1 to send a signal to the flip-flop that detects the zero point of the current flowing through the inductor L2 forming the transformer and sets it to a set state.

The GD terminal is connected to the gate of the switching element Q to apply an output according to the set or reset signal in the flip-flop to the gate of the switching element Q through a driver DRIVER.

Meanwhile, the VCC terminal is connected to the cathode contact of the resistor R3, the capacitor C2 and the diode D2, and the GND terminal is connected to the ground terminal to supply power to the PFC IC 13.

The operation process of the conventional LED lighting device 10 having the configuration as described above is as follows.

AC voltage is rectified by the bridge diode BD connected to the AC voltage input terminal, and a constant value of DC power is supplied to the LED lighting load on the load side through the inductor L1, diode D1 and capacitor C1.

The LED lighting load applies a reference voltage (Ref-V) to maintain a constant illuminance of the LED lighting load to the non-inverting terminal (+) of the error amplifier in order to maintain the output current at the reference value to make the illumination constant. And it compares with the voltage corresponding to the output current of the LED lighting load input to the inverting terminal (-) connected to the INV terminal and outputs a value corresponding to the difference.

If the output current exceeds the reference value, as the current flowing through the resistor R5 increases, the voltage drop of the resistor R5 increases, so that the value at the error amplifier inverting terminal (-) connected to the INV terminal of the PFC IC 13 is greater than the reference value. The output of the error amplifier decreases as it increases, and when the output current does not reach the reference value, the voltage drop of the resistor R5 decreases as the current flowing through the resistor R5 decreases, so that the value at the error amplifier inverting terminal (-) is smaller than the reference value. The error amplifier's output increases.

On the other hand, the voltage rectified by the bridge diode BD is sensed by the resistor R1 and the resistor R2 and input to a multiplier connected to the MULT terminal. The voltage input to the multiplier is multiplied by the output of the increased or decreased error amplifier and input to the inverting terminal (-) of the comparator.

The current flowing through the switching element Q is sensed by the resistor R4, and the sensed voltage is input to the non-inverting terminal (+) of the comparator connected to the CS terminal.

The comparator compares the multiplier output with the sensed voltage and outputs a high level signal to the reset terminal of the flip-flop at a point where the value corresponding to the current flowing through the switching element Q becomes the value output from the multiplier of the MULT terminal. Turn off the switching element Q, which is connected to the GD terminal via a driver.

On the other hand, when the current flowing through the inductor L2 is zero at the ZCD terminal, the high level signal is output to the set terminal of the flip-flop, and the switching device Q connected to the GD terminal is turned on through the driver.

As described above, in the conventional LED lighting apparatus 10, the switching element Q is turned on at the point where the current flowing through the inductor L2 becomes zero, and the voltage value corresponding to the output current flowing through the LED lighting load is changed to INV of the PFC IC 13. PWM of the switching control signal output through the GD terminal when the feedback value is larger than the reference value by applying it to the inverting terminal (-) of the error amplifier connected to the terminal and comparing it with the preset reference voltage (Ref-V) value. By reducing the width, the output is reduced, and when it is smaller than the reference value, the switching element Q is turned off to increase the PWM width of the switching control signal output through the GD terminal to increase the output. Even if there is a change between 85 ~ 270V, the operating range of the load, the power factor is compensated and the illumination current is kept constant by adjusting the output current of the LED lighting load.

In the state where a large number of such conventional LED lighting device 10 is installed, when the user wants to adjust the illuminance of the LED lighting device to the desired brightness according to the surrounding environment, the conventional LED lighting device 10 is possible through phase control, In this case, not only the power factor through the PFC IC can be compensated, but also when the power factor is compensated, the configuration becomes complicated.

The present invention is to solve the above problems, the overall adjustment of the illumination of the LED lighting device in proportion to the AC input voltage adjusted to the reference value while minimizing the change or addition of the configuration in a number of LED lighting devices installed Within this range, the illuminance of the LED illuminator is individually adjusted by adjusting the reference value of the corresponding DC output current.If the illuminance of the LED illuminator is exceeded, the illuminance of the LED illuminator is exceeded regardless of the AC input voltage change. Its purpose is to provide a LED lighting system that maintains a constant and compensates the power factor through the PFC IC even if the AC input voltage fluctuates during this dimming process.

In order to achieve the above object, the present invention, the LED lighting load including the LED is connected in series and parallel, the converter unit for rectifying the input AC power supply to the LED lighting load in accordance with the operation of the switching element, the converter An output current feedback unit for feeding back the output current of the LED lighting load operated by the unit and an output current value of the output current feedback unit compared with a reference value to output a predetermined value while compensating for the power factor of the converter unit A plurality of LED lighting devices comprising a PFC IC for controlling the operation of the switching element; An input voltage adjusting unit connected to the plurality of LED lighting device power input terminals in parallel to adjust an amount of an AC voltage input for overall illumination control of the LED lighting load; And a feedback output current adjusting unit connected to input terminals of the plurality of LED lighting device output current feedback units to adjust the magnitude of the DC current input to the PFC IC for individual illumination control of the corresponding LED lighting load. In the PFC IC, an internal error amplifier inverting terminal connected to an INV terminal is connected to a ground terminal through a first resistor, and a reference value is applied to a non-inverting terminal so that the output of the internal error amplifier always corresponds to a reference value. It is kept constant and the output terminal of the output current feedback unit is connected to the COMP terminal, and the output current feedback unit is not output until the output value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit becomes a reference value. If the reference value is exceeded, the output value is output as a value corresponding to the difference between the output value and the reference value, and the output value of the LED lighting load. While the value corresponding to the reference value is output from the internal error amplifier of the PFC IC until the reference value is reached, the overall illumination of the plurality of LED lighting devices is proportionally adjusted in proportion to the adjusted AC voltage, and the feedback is within this range. The output current adjustment unit adjusts the reference value of the output current feedback unit to individually adjust and adjust the illuminance of the corresponding LED lighting load, while the output value of the LED lighting load is applied to the COMP terminal when the reference value exceeds the reference value. LED output, characterized in that the illumination value of the LED lighting device to maintain a constant irrespective of the AC voltage is adjusted while outputting a value corresponding to the difference between the output value of the output current feedback unit and the internal error amplifier output value of the PFC IC Provide a system.

Preferably, the output current feedback unit is connected to the LED lighting load in series one end and the other end is connected to the ground terminal to the second resistor for detecting the output current of the LED lighting load; An error amplifier for amplifying a difference between a voltage corresponding to an output current detected by the second resistor and a corresponding reference voltage adjusted by the feedback output current adjusting unit; And a diode having a cathode connected to the output of the error amplifier, wherein the anode of the diode is connected to the COMP terminal of the PFC IC.

Preferably, the output current feedback unit is connected to the LED lighting load in series one end and the other end is connected to the ground terminal to the second resistor for detecting the output current of the LED lighting load; An error amplifier for amplifying a difference between a voltage corresponding to an output current detected by the second resistor and a corresponding reference voltage adjusted by the feedback output current adjusting unit; And a photocoupler for transmitting the output of the error amplifier to the PFC IC, wherein the photocoupler has a cathode of a photodiode connected to an output of an error amplifier, an anode connected to an output voltage terminal, and a phototransistor. The COMP terminal can be connected to the collector, and the emitter can be connected to the ground terminal.

According to the LED lighting system of the present invention having the above configuration, even if the AC input voltage is changed to adjust the illuminance of the LED lighting device, the illuminance is constant only within the setting range of the conventional AC input voltage while compensating the power factor through the PFC IC. In contrast to this, the overall illumination intensity of a large number of installed LED lighting devices is collectively adjusted and the LEDs are kept within this range while keeping the voltage that changes to the reference value according to the change of AC input voltage while minimizing the change or addition of the configuration. The illuminance of the lighting device can be selected and adjusted individually by adjusting the reference value of the corresponding DC output current, while maintaining the illuminance at the reference value when the AC input voltage exceeds the reference value. Energy savings can be achieved by simply and efficiently selecting lighting devices, either globally or individually. Which becomes effective.

1 shows an example of a circuit diagram of an LED lighting apparatus to which a conventional PFC IC is applied.
FIG. 2 illustrates a circuit diagram of an LED lighting apparatus to which a PFC IC constituting a plurality of LED lighting systems according to an embodiment of the present invention is applied.
3 is a block diagram showing an LED lighting system according to an embodiment of the present invention installed by including a plurality of devices of FIG.
FIG. 4 illustrates the variation of the output current according to the variation of the AC input voltage in the system of FIG.
5 illustrates another circuit diagram of an LED lighting apparatus to which a PFC IC constituting a plurality of LED lighting systems according to an exemplary embodiment of the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are intended to be described in detail so that those skilled in the art can easily implement the present invention. It is not intended that the technical spirit and scope of the present invention is limited, and the same parts as in the conventional configuration may use the same reference numerals and names.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are intended to be described in detail so that those skilled in the art can easily implement the present invention. It is not intended that the technical spirit and scope of the present invention is limited, and the same parts as in the conventional configuration may use the same reference numerals and names.

FIG. 2 illustrates an example of a circuit diagram of an LED lighting apparatus to which a PFC IC including a plurality of LED lighting systems according to an exemplary embodiment of the present invention is applied, and FIG. 3 illustrates the implementation of the present invention including a plurality of the apparatus of FIG. 2. A block diagram of an LED lighting system according to an example is shown, and FIG. 4 illustrates a variation of an output current according to a variation of an AC input voltage in the system of FIG. 3.

As shown in FIG. 3, the LED lighting system 300 according to the embodiment of the present invention includes a plurality of LED lighting apparatuses 100 to which the PFC IC of FIG. 2 is applied and the plurality of LED lighting apparatuses 100 are input. The input voltage adjusting unit 110 collectively adjusts the illuminance of the entire LED lighting load by adjusting the magnitude of the input AC voltage connected in parallel to each stage and the LED lighting load by adjusting the DC output current fed back. It consists of a feedback output current adjusting unit 150 to adjust the illuminance of each.

From this, the LED lighting system 300 according to the embodiment of the present invention adjusts the illuminance by adjusting the output current of the LED lighting load while compensating for the power factor even if the conventional AC input voltage varies between 85 to 270 V, which is an operating range of the LED lighting load. Unlike the LED lighting device 10 that maintains a constant, the AC input voltage is adjusted between 0 to 270V with 100V as a reference value (may be 220V as a reference value), and it is between 0 to 100V as the reference value. Adjusts the total illuminance of the LED lighting load in proportion to the adjusted AC input voltage, selects to adjust the individual illuminance of the corresponding LED lighting load by adjusting the reference value of the DC output current fed back within this range, If the value is exceeded, the illumination intensity of the LED light load is kept constant regardless of the change of the AC input voltage.In the process of adjusting the illuminance of the LED light load, the adjustment of the AC input voltage is controlled. By controlling a non-phase controlled size, even if the AC input voltage variation enables the power factor correction through the PFC IC.

Hereinafter, with respect to the LED lighting device 100 of the LED lighting system 300 according to an embodiment of the present invention, the converter unit 11 and the PFC IC 13 of the conventional LED lighting device 10 are equally applicable. Descriptions of possible parts are briefly described or omitted, and there is a difference in the connection relationship between the output current feedback unit 13 and the PFC IC 14 and the input voltage adjusting unit 110 and the feedback output current adjusting unit. The description will be made in detail with reference to 150 as the center.

First, the plurality of LED lighting apparatuses 100 rectify AC power regulated and input by the input voltage adjusting unit 110, and according to the operation of the switching element Q, the DC power supply from the inductor L1, the diode D1 and the capacitor C1 to the LED lighting load. The output value of the converter unit 120 for outputting the output current, the output current feedback unit 130 for feeding back the output current of the LED lighting load supplied from the converter unit 120, and the output current of the output current feedback unit 130 as reference values. The reference value is proportional to the AC input voltage to be adjusted in comparison with that, and if the reference value is exceeded, the illuminance of the LED lighting load is constantly adjusted regardless of the change of the AC input voltage. And a PFC IC 140 that controls the switching of the switching element Q such that there is no change in sensing the zero point of the current flowing into the inductor L2 of 120 to compensate for the power factor. The.

Next, the input voltage adjusting unit 110 is connected to the AC voltage input terminals connected in parallel in the plurality of LED lighting apparatuses 100, for example, using a triac in the process of adjusting the illuminance of the LED lighting load. Instead of controlling the phase of the input voltage, for example, using a voltage regulator such as SLIDAX to control the magnitude of the AC input voltage, even if the AC input voltage fluctuates, the power factor compensation through the PFC IC 130 is possible and the entire LED Dimming the light load to the desired brightness at once.

In addition, the feedback output current adjusting unit 150 is connected to the input terminal of the output current feedback unit 130, respectively, and the magnitude of the DC current input to the PFC IC 140 for individual illumination control of the LED lighting load. To adjust.

The output current feedback unit 130, one end is connected in series with the LED light load in order to detect the output current of the LED light load, the other end is connected to the ground terminal, and to draw the voltage drop generated therein to detect the output current. A cathode is provided at an error amplifier U for amplifying the difference between the voltage corresponding to the output current detected by the resistor R5 and the reference voltage Ref-C, and the output of the error amplifier U. And a diode D3 connected to the anode of the PFC IC 140 at an anode thereof.

The voltage dropping from the resistor R5 is applied to the input side inverting terminal (-) of the error amplifier U through the resistor R6, the reference voltage Ref-C is applied to the non-inverting terminal (+), and an integrating circuit The capacitor C4 is connected between the input side and the output side of the error amplifier (U).

The output current feedback unit 130 configured as described above is not output until the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 110 becomes a reference value, and exceeds the reference value. A value corresponding to the difference between the written output value and the reference value is output to the COMP terminal of the PFC IC 140.

That is, until the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 110 becomes the reference value, the output value falling from the resistor R5 becomes smaller than the reference value, thereby causing the error amplifier (U). Since the diode D3 is turned off while the output value of the output signal increases, the output value of the error amplifier U of the output current feedback unit 130 is not output to the COMP terminal of the PFC IC 140.

In this case, the internal error amplifier is connected by connecting the ground terminal to the internal error amplifier inverting terminal (-) to which the INV terminal of the PFC IC 140 is connected through the resistor R7 and applying a reference value to the non-inverting terminal (+). Since the output terminal corresponds to the reference voltage Ref-V at all times, the COMP terminal of the PFC IC 140 maintains the output value corresponding to the reference voltage in the internal error amplifier.

However, when the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 110 exceeds the reference value, the output value falling from the resistor R5 is greater than the reference value, the output of the error amplifier (U) As the value decreases, the diode D3 is turned on so that the output value of the error amplifier U of the output current feedback unit 130 is output to the COMP terminal of the PFC IC 140.

In this case, the COMP terminal of the PFC IC 140 maintains a value reduced by the error amplifier U output value of the output current feedback unit at an output value corresponding to a reference voltage in the internal error amplifier.

Here, when collectively adjusting the illuminance of a plurality of LED lighting apparatus until the output current value of the LED lighting load becomes a reference value while being proportional to the AC voltage adjusted by the input voltage adjusting unit 110, the output current within this range While adjusting the reference value in the feedback output current adjusting unit 150 connected to the non-inverting terminal (+), which applies a reference value to the error amplifier U of the feedback unit 130, the illumination intensity of the corresponding LED lighting load is also individually. You can control the selection.

The feedback output current adjusting unit 150 may apply, for example, a variable resistor, and applies a reference value to both ends thereof, and connects the non-inverting terminal (+) of the error amplifier U to a variable contact therebetween. Let's do it.

The PFC IC 140 connects the ground terminal through the resistor R7 to the internal error amplifier inverting terminal (-) to which the INV terminal is connected, and applies a reference value to the non-inverting terminal (+) to always provide an internal error amplifier. The output value corresponds to the reference voltage.

The output terminal of the output current feedback unit 130 is connected to the COMP terminal of the PFC IC 140, and there is no output of the output current feedback unit 130 until the output current value of the LED lighting load becomes the reference value. Therefore, while the value corresponding to the reference voltage is output as it is from the internal error amplifier of the PFC IC 140, while adjusting the illuminance of the LED lighting load in proportion to the adjusted AC voltage, the output current value of the LED lighting load is set to the reference value. When exceeded, the output value of the output current feedback unit 130 applied to the COMP terminal is decreased and output from the value corresponding to the reference voltage in the internal error amplifier of the PFC IC 140, regardless of the change of the AC voltage. Keep illuminance of lighting load constant.

That is, until the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 110 becomes a reference value, the output value corresponding to the reference voltage is determined by the internal error amplifier of the PFC IC 140. Keep it.

Accordingly, in the multiplier of the PFC IC 140, the voltage rectified by the bridge diode BD of the converter unit 120 is divided by the resistor R1 and the resistor R2 to the input voltage value, and the PFC IC 140 is input. In the internal error amplifier of), the output value corresponding to the reference voltage is amplified by the preset gain, adjusted to the unit value, and multiplied so that the voltage input to the MULT terminal is output as it is.

In the comparator of the PFC IC 140, the output value of the multiplier is compared with the sensed voltage value of the CS terminal, and a high point is detected at the point where the detected voltage value becomes the output value of the multiplier (voltage value input to the MULT terminal). Outputs the level signal to the reset terminal of the flip-flop, turns off the switching element Q connected to the GD terminal through the driver, and detects the point where the current flowing in the inductor L2 becomes zero at the ZCD terminal to a high level signal. Outputs to the set terminal of the flip-flop and turns on the switching element Q connected to the GD terminal through a driver.

Therefore, when the adjusted AC input voltage is lower than the reference value, the illumination current of the LED lighting device is adjusted by changing the output current in proportion to the AC input voltage (voltage value input to the mult terminal).

However, when the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 110 exceeds the reference value, the COMP terminal of the PFC IC 140 output value corresponding to the reference voltage in the internal error amplifier Maintains the value reduced by the error amplifier (U) output value of the output current feedback unit 130.

Accordingly, in the multiplier of the PFC IC 140, the voltage rectified by the bridge diode BD of the converter unit 120 is sensed by the resistor R1 and the resistor R2, and the voltage is input to the MULT terminal. In the internal error amplifier of 140, the output value corresponding to the reference voltage is multiplied by the value reduced by the error amplifier (U) output value of the output current feedback unit 130, so that the voltage input to the MULT terminal is reduced and output. .

In the comparator of the PFC IC 140, the output value of the multiplier is compared with the sensed voltage value of the CS terminal, and the detected voltage value becomes the output value of the multiplier (the output at the voltage value input to the MULT terminal). Output value of the high-level signal to the reset terminal of the flip-flop in the error amplifier (U) output value of the current feedback unit 130 is reduced, and the turn-off switching element Q connected to the GD terminal through the driver is turned off. When the current flowing through the inductor L2 becomes zero at the ZCD terminal, the high level signal is output to the set terminal of the flip-flop, and the switching element Q connected to the GD terminal is turned on through the driver.

Therefore, if the adjusted AC input voltage is higher than the reference value, the output current is kept constant regardless of the variation of the AC input voltage (voltage value input to the mult terminal) to make the illumination of the LED lighting device constant.

Figure 4 shows the variation of the output current according to the change of the AC input voltage in the system 300 of Figure 3, the output current of the LED lighting device is 0 ~ 660V when the AC input voltage is changed to 0 ~ 270V It changes until 100V, which is set as the reference value, changes linearly in proportion to the AC input voltage, and when it exceeds 100V, the output current of the LED lighting device is constant at 660㎃.

And, in Table 1, with respect to the change in the output current according to the change in the AC input voltage of Figure 4, it can be confirmed the terminal voltage and current of the PFC IC 140 according to the change in the applied AC input voltage.

In addition, an example of another circuit diagram of the LED lighting device to which the PFC IC constituting a plurality of LED lighting system according to an embodiment of the present invention is as follows.

As shown in FIG. 5, the LED lighting device 200 to which the PFC IC is applied is the same as the LED lighting device 100, and a plurality of the LED lighting devices 100 are connected to the input terminals of the plurality of LED lighting devices 100. Illumination of each LED illumination load by adjusting the input voltage adjusting unit 110 which adjusts the illuminance of the entire LED illumination load collectively by adjusting the magnitude of the AC voltage input and connected in parallel, and the DC output current fed back. It is the same as the LED lighting system 300 according to the embodiment of the present invention, but the non-isolated LED lighting device according to the transformer connection method of the converter unit 220 is made of a feedback output current adjusting unit 150 to individually adjust the Unlike the (100), there is a difference in the output current feedback unit 230 from being divided into an insulating type, which will be described below.

In the LED lighting apparatus 200, the output current feedback unit 230 is not output until the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 210 becomes a reference value, When the reference value is exceeded, a value corresponding to the difference between the output current value and the reference value is output. At this time, a photocoupler PC is applied instead of the diode D3 of the LED lighting device 100 for insulation.

From this, the output current feedback unit 230 has one end connected in series to the LED lighting load and the other end connected to the ground terminal, and a resistor R5 for detecting the output current of the LED lighting load, and an output detected by the resistor R5. An error amplifier (U) for amplifying a difference between a voltage corresponding to a current and a reference voltage, and a photocoupler (PC) for transmitting an output of the error amplifier (U) to the PFC IC 240, In the photocoupler PC, the cathode of the photodiode is connected to the output of the error amplifier U, the anode is connected to the output voltage terminal, the COMP terminal is connected to the collector of the phototransistor, and the emitter is connected to the ground terminal. To be.

The output current feedback unit 230 configured as described above has an output value falling from the resistor R5 until the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 210 becomes a reference value. Since the output value of the error amplifier U becomes smaller than this reference value and the photodiode of the photocoupler PC does not emit light, the phototransistor is turned off, so that the error amplifier U of the output current feedback unit 230 is turned off. The output value of is not output to the COMP terminal of the PFC IC 240, the COMP terminal of the PFC IC 240 maintains the output value corresponding to the reference voltage in the internal error amplifier.

However, when the output current value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit 210 exceeds the reference value, the output value falling from the resistor R5 is larger than the reference value, the output of the error amplifier (U) As the value decreases, the photodiode of the photocoupler PC emits light according to the output value and the phototransistor is turned on, so that the error amplifier U of the output current feedback unit 230 corresponding to the difference between the output value and the reference value is turned on. The output value of is output to the COMP terminal of the PFC IC 240, the COMP terminal of the PFC IC 240 outputs the error amplifier (U) of the output current feedback portion at an output value corresponding to the reference voltage in the internal error amplifier Keep the value reduced by a value.

This invention is not limited to the above embodiments, various modifications are possible within the scope of the invention described in the claims, and such modifications are also included within the scope of the invention.

10: conventional LED lighting device
11, 120, 220: converter section
12: output current feedback unit
13, 140, 240: PFC IC
100, 200: LED lighting device applied to the LED lighting system according to the embodiment of the present invention
110, 210: Input voltage adjusting unit
130, 230: output current feedback unit
150, 250: feedback output current adjusting unit
300: LED lighting system according to an embodiment of the present invention

Claims (3)

A LED lighting load including an LED that is wired in parallel and a rectifier, a converter unit rectifying the input AC power and supplying the LED lighting load according to the operation of a switching element, and the LED lighting load supplied and operated by the converter unit. An output current feedback unit for feeding back an output current, and a PFC IC for controlling the operation of the switching element to compare the output current value of the output current feedback unit with a reference value and output a predetermined value while compensating for the power factor of the converter unit. A plurality of LED lighting devices configured;
An input voltage adjusting unit connected to the plurality of LED lighting device power input terminals in parallel to adjust an amount of an AC voltage input for overall illumination control of the LED lighting load; And,
And a feedback output current adjusting unit connected to input terminals of the plurality of LED lighting device output current feedback units, respectively, to adjust the magnitude of the DC current input to the PFC IC for individual illumination control of the corresponding LED lighting load.
In the PFC IC, an internal error amplifier inverting terminal connected to an INV terminal is connected to a ground terminal through a first resistor and a reference value is applied to a non-inverting terminal so that the output of the internal error amplifier is always constant to a value corresponding to the reference value. The output terminal of the output current feedback unit is connected to the COMP terminal,
The output current feedback unit does not output until the output value of the LED lighting load according to the AC voltage adjusted by the input voltage adjusting unit becomes a reference value, and if it exceeds the reference value, the output current feedback part corresponds to the difference between the output value and the reference value. Output as a value,
Until the output value of the LED lighting load becomes the reference value, the value corresponding to the reference value is output from the internal error amplifier of the PFC IC, and collectively adjusts the illumination intensity of a plurality of LED lighting devices in proportion to the adjusted AC voltage. Within this range, the feedback output current adjusting unit adjusts the reference value of the output current feedback unit to selectively adjust and adjust the illuminance of the corresponding LED lighting load.
When the output value of the LED lighting load exceeds the reference value, the AC value is adjusted while outputting a value corresponding to the difference between the output value of the output current feedback unit applied to the COMP terminal and the internal error amplifier output value of the PFC IC. LED lighting system, characterized in that to maintain a constant illuminance of the LED lighting device irrespective of the voltage. The method according to claim 1,
The output current feedback unit,
A second resistor having one end connected in series to the LED lighting load and the other end connected to the ground terminal for detecting an output current of the LED lighting load;
An error amplifier for amplifying a difference between a voltage corresponding to the output current detected by the second resistor and a reference voltage; And,
And a diode having a cathode connected to the output of the error amplifier.
And the anode of said diode is connected to the COMP terminal of said PFC IC. The method according to claim 1,
The output current feedback unit,
A second resistor having one end connected in series to the LED lighting load and the other end connected to the ground terminal for detecting an output current of the LED lighting load;
An error amplifier for amplifying a difference between a voltage corresponding to the output current detected by the second resistor and a reference voltage; And,
And a photocoupler for transmitting the output of the error amplifier to the PFC IC.
The photocoupler is characterized in that the cathode of the photodiode is connected to the output of the error amplifier, the anode is connected to the output voltage terminal, the COMP terminal is connected to the collector of the phototransistor, the emitter is connected to the ground terminal LED lighting system.

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