KR101123440B1 - Multi-control led driving circuit - Google Patents

Abstract

The multi-control LED driving circuit according to the present invention comprises a high voltage generator comprising a first transformer for boosting the power of the battery and an EMI filter for removing the noise of the power from the first transformer; A PFC unit having a switching FET operated according to a control signal from the PFC control unit to reduce peak current of an inrush power supply; A full-bridge rectifying unit for full-wave rectifying, a DC / DC converter including a smoothing unit controlling the power of the full-bridge rectifying unit by a DC voltage control unit and a booster for boosting the voltage from the smoothing unit; A transformer unit comprising a second transformer and a smoothing unit serving as a filter for removing ripples of power generated by the second transformer; A DC / AC inverter composed of four high voltage switching FETs driven by a PWM control unit according to a control signal to generate an AC power in the form of a pseudo sine wave which doubles the voltage from the second transformer; A voltage regulation output unit for stabilizing the output from the DC / AC inverter and outputting the rated load voltage since the buck is operated by the PWM control unit; Generates a signal with a modified duty cycle of high frequency and applies it to a DC / AC inverter to regulate the voltage to a peak value, generates a high voltage current, and is installed at the voltage regulation output to supply power at various points in the system A PWM control unit for adjusting the power factor at the power input terminal of the system to generate an average power and outputting an accurate load power since the error signal is received; A PFC controller synchronized with the PWM controller and configured to control the input power of the high voltage generator to a power having an average current / voltage value; DC voltage controllers are configured to match the power applied to the DC / DC converter to which the average power is applied to the output power.

Description

Multiple Control LED Driving Circuit {MULTI-CONTROL LED DRIVING CIRCUIT}

The present invention relates to a LED drive circuit, and to provide a multi-control LED drive circuit and a control method thereof capable of multiple control to adjust the power supply for inducing the operation of the LED to a suitable power supply at various points in the system.

LED lighting apparatuses are well known in the art, and in particular, LED lighting control apparatuses and methods thereof are disclosed in Korean Patent No. 10-0845305, which is representative of driving circuits that influence the performance of lighting. This LED (hereinafter referred to as LED) lighting control device changes the duty timing according to the amount of current flowing through the LED to maintain constant illumination of the LED light and to prolong its life, thereby preventing power loss. By using constant current method in device and installing LED lamps for different voltages according to the number of LED frames, it automatically compensates the voltage deviation of LED lamp, so that one LED can control several LED lights. .

In practice, the LED lighting controller sets the load reference current according to the dimming input and controls the LED duty according to the reference current, so that the voltage / current according to the load of the entire LED is output.

However, the LED lighting controller has no countermeasure against preventing malfunction due to deterioration of the performance of some components installed inside the system, except for adjusting the amount of current and voltage to the load. There is no technical disclosure on how to improve the performance of the system.

In order to solve this problem, it is highly desirable to stably generate high voltage and current for the variable input voltage current and to apply it to the load so that desired lighting can be achieved and the overall performance of the system is kept constant.

SUMMARY OF THE INVENTION The present invention is directed to providing an LED drive circuit capable of multiple control and a method of controlling the same so as to adjust the drive operating power of the LED to a suitable power source at various points in the system.

Another object of the present invention is to generate voltage / current for a variable input power supply at a rated voltage / current, and to optimize the control of the entire system to enable stable control of LED lighting. An LED driving circuit and a control method thereof are provided.

The multi-control LED driving circuit according to the present invention comprises a high voltage generator comprising a first transformer for boosting the power of the battery and an EMI filter for removing the noise of the power from the first transformer; A PFC unit having a switching FET operated according to a control signal from the PFC control unit to reduce peak current of an inrush power supply; A full-bridge rectifying unit for full-wave rectifying, a DC / DC converter including a smoothing unit controlling the power of the full-bridge rectifying unit by a DC voltage control unit and a booster for boosting the voltage from the smoothing unit; A transformer unit comprising a second transformer and a smoothing unit serving as a filter for removing ripples of power generated by the second transformer; A DC / AC inverter composed of four high voltage switching FETs driven by a PWM control unit according to a control signal to generate an AC power in the form of a pseudo sine wave which doubles the voltage from the second transformer; A voltage regulation output unit for stabilizing the output from the DC / AC inverter and outputting the rated load voltage since the buck is operated by the PWM control unit; Generates a signal with a modified duty cycle of high frequency and applies it to a DC / AC inverter to regulate the voltage to a peak value, generates a high voltage current, and is installed at the voltage regulation output to supply power at various points in the system A PWM control unit for adjusting the power factor at the power input terminal of the system to generate an average power and outputting an accurate load power since the error signal is received; A PFC controller synchronized with the PWM controller and configured to control the input power of the high voltage generator to a power having an average current / voltage value; DC voltage control units are configured to match the power applied to the DC / DC converter to which the average power is applied to the output power.

The present invention prevents malfunction due to deterioration of the performance of some components installed inside the system, blocks inrush current to cope with variations in input current and voltage, averages the power of the system and makes the load power at the output constant. To improve the performance.

1 is a schematic block diagram of a multiple control LED drive circuit according to the present invention;
2 is a circuit diagram showing a part of the multiple control LED driving circuit according to the present invention as a block diagram and detailing the parts of the present invention.
3 is a flow chart showing the operation of the multiple control LED drive circuit according to the present invention.

The present invention will be described in detail with reference to the accompanying drawings.

1 and 2, a power source such as a battery or a general commercial power source is applied to the high voltage generator 1 so as to generate a high voltage large current. That is, the high voltage generator 1 is composed of a first transformer T1 for boosting the power of the battery B and an EMI filter for removing noise of the power supply from the first transformer T1.

The power boosted by the first transformer T1 is applied to the PFC unit 2 operated by the PFC control unit 8 described later. The PFC section 2 includes a switching FET Q1 to reduce the peak current of the power supply to be infiltrated.

The DC / DC converter 3 operates the full bridge rectifier 11 for full-wave rectification and the power supply of the full bridge rectifier 11 by the DC voltage controller 9, so that the smoothing unit 12 controls the input average power. And a booster 13 for boosting the voltage from the smoothing part 12.

The transformer section 4 is composed of a high-pressure second transformer T2 and a filter section serving as a filter for removing ripples of power generated by the second transformer T2.

The DC / AC inverter 5 is composed of four high voltage switching FETs driven according to a control signal from the PWM controller 7 to generate a pseudo sine wave-type AC power that doubles the voltage from the second transformer T2. Let's do it.

The voltage regulating output unit 6 stabilizes the output from the DC / AC inverter 5 and outputs the rated load voltage since the buck is operated by the PWM control unit 7 as described in detail later.

The PWM controller 7 generates a signal having a modified duty cycle having a high frequency, for example, a frequency of 2M or more, and applies it to the DC / AC inverter 5 to adjust the voltage to a peak value to generate a high voltage current and to regulate the voltage. Receives error signal of power at various points in system from FET Q9 installed in section 6 and performs dimming operation to adjust power factor, generate average power and output accurate load power at system power input. .

 The PFC controller 8 is synchronized with the PWM controller 7 and causes the high voltage generator 1 to output the power having the average current / voltage value as the input power.

The DC voltage controller 9 causes the power applied to the DC / DC converter 3 to which the average power is applied to match the output power.

In more detail, as shown in FIG. 2, the high voltage generator 1 has a first transformer T1 via a coil L1 and a resistor R0 connected in parallel to filter the power of the battery B first. The first transformer T1 is applied to the PFC unit 2 via the diode D0.

The PFC unit 2 reduces the peak current of the switching FET Q1 which is turned on and off by the PFC control unit 8 according to a control signal having a predetermined duty cycle and the power applied according to the operation of the switching FET Q1. A coil L2, a capacitor C1, a resistor R1, and a capacitor C2, each of which is composed of a PFC stage and functions as an inductor connected in parallel.

The DC / DC converter 3 is a full bridge rectifier 11 consisting of diodes D1 to D4, a transistor Q2 switched by the DC voltage controller 9, and a power source DC power supply of the full bridge rectifier 11. It consists of a smoothing unit 12 consisting of a diode (D5) and a capacitor (C3) connected in parallel via a coil (L3) to smooth a constant power supply and boosters 13 for augmenting power from the smoothing unit 12 do.

The booster 13 is composed of two high voltage generating switching FETs Q3 and Q4, and these two high voltage generating switching FETs Q3 and Q4 receive a control signal via diodes D11 and D12. Operation is controlled by the DC voltage control unit 9 applied to them to output 170 V / A, for example.

Here, the DC voltage controller 9 applies a signal according to the duty ratio of the pulse width modulation control signal of the PWM controller 7 to the switching transistor Q2 to turn on and off at predetermined intervals, thereby blocking the inflow of inrush current and smoothing ( 12 to generate an average power supply and to apply to the booster (13).

The transformer unit 4 is composed of a high voltage secondary transformer T2, a coil L5 serving as a conductor, and a smoothing unit composed of a diode D6 and a capacitor C4 connected in parallel to operate to remove ripples and the like. do. In this case, the second transformer T2 is a boosting transformer so that the voltage is boosted to twice the input voltage, for example, 340 V / A.

The DC / AC inverter 5 is composed of a high voltage switching circuit section composed of high voltage switching FETs Q5 to Q8 for generating four high voltages. The high voltage switching FETs Q5 and Q8 and the high voltage switching FETs Q6 and Q7 of the switching circuit portion are paired, respectively, from the PWM controller 7 to the diodes D13, D14 and D15. They operate in accordance with the control signal applied via them to output an AC square wave or a modified sine wave voltage.

The voltage regulating output unit 6 is composed of a diode D7 and an inductor for maintaining the line voltage, and is installed at both ends of the coil L4 and the condenser C6 for detecting the output current and the output load to maintain the load power voltage. One geno diode (D8) and (D9), a capacitor (C7) for detecting the final current of the load power supply and FETs (Q9) for detecting the detected error of the power supply current (Feedback) to the PWM control unit (7) It is configured to stabilize the secondary current.

Thus, the present invention operates as shown in FIG.

First, in step 101, power is applied.

In step 102, the PWM controller 7 determines whether the power applied to the PFC unit 2 is an inrush current according to the DC power input based on the error signal at the output terminal. The PWM controller 7 controls the PFC controller 8 to control the switching FET Q1 so that the inrush current is interrupted.

In step 103, it is determined whether the average power flows as in step 101. If it is determined that the power is abnormal, in step 108, the PWM controller 7 receives an error signal. ) To operate transistor Q2 to reduce peak voltage and current.

In step 104, the DC / DC converter is operated, and in step 105, the AC / AC inverter is operated to stabilize the current and voltage.

In step 106, as in step 101, the voltage regulation output unit 6 detects an error, which detects a current error signal generated by the operation of the FET Q9. In this case, when the error signal is detected, the operation of the DC / DC converter is controlled by the PWM controller 7. If not and no error signal is detected, go to Step 107. In step 107, the dimming operation of the FET Q9 which detects an error signal of the voltage regulation output part is performed.

Thereafter, when the process proceeds to step 108 to detect an error signal according to the operation of the FET Q9, steps 102, 103, and 106 are performed according to the magnitude of the error detection signal. Otherwise, the process moves to step 109 to resume normal operation.

1: high voltage generation section 2: PFC section 3: DC / DC converter
4: transformer part 5: DC / AC inverter 6: voltage regulation output part
7: PWM control unit 8: PFC control unit 9: DC voltage control unit

Claims (3)

In the multiple control LED driving circuit,
A high voltage generator comprising a first transformer for boosting the power of the battery and an EMI filter for removing noise of the power from the first transformer;
A PFC unit having a switching FET operated according to a control signal from the PFC control unit to reduce peak current of an inrush power supply;
A full-bridge rectifying unit for full-wave rectifying, a DC / DC converter including a smoothing unit controlling the power of the full-bridge rectifying unit by a DC voltage control unit and a booster for boosting the voltage from the smoothing unit;
A transformer unit comprising a second transformer and a smoothing unit serving as a filter for removing ripples of power generated by the second transformer;
A DC / AC inverter composed of four high voltage switching FETs driven by a PWM control unit according to a control signal to generate an AC power in the form of a pseudo sine wave which doubles the voltage from the second transformer;
A voltage regulation output unit for stabilizing the output from the DC / AC inverter and outputting the rated load voltage since the buck is operated by the PWM control unit;
Generates a signal with a modified duty cycle of high frequency and applies it to a DC / AC inverter to regulate the voltage to a peak value, generates a high voltage current, and is installed at the voltage regulation output to supply power at various points in the system A PWM control unit for adjusting the power factor at the power input terminal of the system to generate an average power and outputting an accurate load power since the error signal is received;
A PFC controller synchronized with the PWM controller and configured to control the input power of the high voltage generator to a power having an average current / voltage value;
A multi-control LED driving circuit comprising a DC voltage control unit for matching the power applied to the DC / DC converter to which the average power is applied to the output power. The method of claim 1,
The DC / DC converter is composed of a diode and a capacitor connected in parallel via a coil that smoothes a full bridge rectifier composed of a plurality of diodes, a transistor operated by a DC voltage controller, and a DC power supply of the full bridge rectifier. Multiple control LED drive circuit comprising a booster to boost the power from the portion and the smoothing.
The method of claim 1,
The voltage regulating output unit includes a diode for maintaining the line voltage, a coil and a capacitor for detecting the output current, one or more xeno diodes installed at both ends of the output load, and a capacitor for sensing the final current of the load power. A multi-control LED drive circuit, comprising a plurality of FETs for detecting the detected error of the power supply current and feeding back to the PWM control unit.

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