KR101611588B1 - Apparatus for driving LED - Google Patents

Abstract

More particularly, the present invention relates to an LED constant current driving apparatus, and more specifically, a driving control chip unit and a driving unit are separately manufactured, a current flowing to an LED unit is driven by a constant current through a driving unit, The present invention relates to an LED constant current drive apparatus capable of controlling a high-capacity LED unit with a single drive control chip unit by generating a main heat loss in a drive unit rather than a drive control chip.

Description

Apparatus for driving LED < RTI ID = 0.0 >

More particularly, the present invention relates to an LED constant current driving apparatus, and more specifically, a driving control chip unit and a driving unit are separately manufactured, a current flowing to an LED unit is driven by a constant current through a driving unit, The present invention relates to an LED constant current drive apparatus capable of controlling a high-capacity LED unit with a single drive control chip unit by generating a main heat loss in a drive unit rather than a drive control chip.

In general, LEDs are eco-friendly and can respond to video signals with high response speeds of several nanoseconds. The LED can be driven by impulsive, color reproducibility is 100% or more, and the luminance, color temperature, etc. can be arbitrarily changed by adjusting the amount of red, green, and blue LED light. As such, LEDs are widely used as light sources for backlighting of LCD panels because they have advantages suitable for light and short life of LCD (Liquid Crystal Display) panels.

Also, in order to increase the output of the lighting device using the LED, a plurality of LEDs must be connected and used. In this case, in order to drive the plurality of connected LEDs, a voltage greater than the sum of the forward- Should be supplied.

In such an illumination device using a plurality of LEDs, a power source using a switching mode power supply (SMPS) is generally used for driving at a wide range of voltages.

However, since the conventional LED driving apparatus using SMPS uses high-speed switching, it is necessary to constitute a noise filter by generating a lot of noise, and besides, since many parts are used in circuit construction, it is difficult to constitute a circuit at low cost There was a problem.

In addition, since the conventional LED driving apparatus uses an electrolytic capacitor, it is not suitable for a long life. Almost all LED lighting apparatuses constitute a circuit together with an LED that emits light. Therefore, Which is further shortened.

Further, in a lighting apparatus having a plurality of LEDs, a voltage higher than the sum of the forward driving voltages of the LEDs must be supplied, so that it is difficult to configure a high power factor LED lighting apparatus in an environment where the input voltage fluctuates greatly.

In order to solve this LED driving problem, Korean Patent No. 10-986815 (hereinafter referred to as " Prior Art 1 ") discloses an LED constant-current driving circuit for driving a plurality of LEDs in series, Device is disclosed.

1, which is a circuit diagram of an LED constant current driving device according to an embodiment of the prior art 1, a current detecting unit 31 includes a current detecting unit 31, a current detecting unit 31, The output terminal of the current detector 31 is connected to the base terminal of the error amplifier 33 and the emitter terminal of the error amplifier 33 is connected to the power source 10. The collector terminal of the error amplifier 33 is connected to the sequential drive control chip The collector terminal of the error amplifier 33 is connected to the base terminal through resistors R10 to R14 and the collector terminal of the error amplifier 33 is connected to the LED unit And a plurality of transistors Q11 to Q15 connected to the cathodes of the LEDs of the LEDs 20 to 20, respectively. The emitter terminal of the transistor Q11 is connected to the output terminal of the LED unit 20 and the input terminal of the current detecting unit 31. The emitter terminals of the transistors Q12, Q13, Q14 and Q15 are connected to the collector terminals Q11, Q12, Q13, Respectively.

When rectified power is supplied from the power supply unit 10, each LED of the LED unit 20 emits light. The current flowing through the LED unit 20 is detected through the resistor R16 which is the current detecting unit 31 and the voltage by the current detected by the current detecting unit 31 is the reference voltage of the transistor Q10 The voltage that is varied by the current amplified and output by the error amplifier 33 is sequentially applied to the transistors Q10 of the drive control chip portion 35 Q11 to Q15.

Each of the transistors Q11 to Q15 of the sequential drive control chip section 35 has a voltage that is varied by the current amplified and output by the error amplifier 33 input to the base terminal to be less than the reference voltage of each of the transistors Q11 to Q15 And is turned on when the voltage input to the base terminal exceeds the reference voltage of each of the transistors Q11 to Q15 to turn on the LED 20 The current is cut off at both ends of the LED so as to be turned off.

That is, when the rectification power supplied from the power supply unit 10 to the LED unit 20 is increased, power is supplied to the LEDs 5, LED 4, LED 3, LED 2, and LED 1 connected to the sequential drive control chip unit 35 in accordance with the rectified power, LED2, and LED1 sequentially emit light. When the power supplied from the power supply unit 10 to the LED unit 20 is lowered, LEDs 1 and 2 connected sequentially to the drive control chip unit 35, LED3, LED4, and LED5 are turned off so that the LED1, LED2, LED3, LED4, and LED5 are sequentially turned off.

When the rectified power supplied to the LED unit 2 sequentially increases and exceeds a multiple of the driving power supply Vf of the LED, a large number of LEDs are driven corresponding to the size of the rectified power supply. The transistor controls the constant current to flow through the LED until the rectified power exceeds a multiple of the LED driving power and increases to a multiple of the next LED driving power. In this case, the sequential driving control chip 35 generates a continuous loss.

Even if the specific look as by reference to Figure 2, the rectified power is greater than the first driving power source (V _f) LED5 will begin to emit light, and it reaches to the second driving power source (2V _f) in the first driving power source (V _f) The transistor Q15 generates a heat loss so that a constant current flows through the LED 5. [ When the rectifying power again exceeds the second driving power (2V _f ), the LEDs 5 and 4 start to emit light and the transistor Q14 is turned on until the second driving power (2V _f ) reaches the third driving power (3V _f ) Heat loss occurs so that a constant current flows through the LEDs 5 and 4. The transistors Q15 to Q11 generate heat loss until the rectifying power exceeds the fifth driving power source 5V _f and the LEDs 5, LED 4, LED 3, LED 2, and LED 1 start emitting light. In particular, A lot of lead losses occur.

The current detecting unit 31, the error amplifying unit 33 and the sequential driving controlling unit 35 described above are designed and used as one integrated circuit (IC) for reliability and mass production. The maximum power of the LEDs connected in series within a controllable range is determined. However, in order to drive a large-capacity LED, a large number of LED modules including an integrated circuit and an LED are connected as shown in FIG. 3, .

Therefore, in order to realize a large-capacity LED driving circuit for illumination, the circuit becomes complicated and the manufacturing cost increases.

SUMMARY OF THE INVENTION An object of the present invention is to provide an LED driving apparatus capable of realizing a large-capacity LED in a simple and inexpensive manner.

Another object of the present invention is to separately manufacture a driving control chip unit and a driving unit, drive a current flowing through the LED unit through a driving unit with a constant current, and the driving control chip unit simply generates a driving control signal for controlling the driving unit, Is generated in the driving unit, not in the driving control chip part.

In order to accomplish the object of the present invention, an LED driving apparatus according to the present invention includes a power supply unit for supplying rectified power, an LED unit connected to at least one LED in series and emitting light using a rectified power supplied from a power supply unit, A driving control chip section for detecting the magnitude of current flowing through the LED section and generating a driving control signal for controlling the current flowing through the LED section with a constant current; And a driving unit for driving the current with a constant current.

Wherein the driving unit is manufactured separately from the driving control chip unit.

The driving control chip part compares the reference voltage and the comparison voltage generated by the detected current magnitude to amplify and output the detected current magnitude when the comparison voltage exceeds the reference voltage And a control signal generator for generating a drive control signal for driving a current flowing through the LED unit with a constant current according to a magnitude of a current amplified and outputted.

The driving unit includes a plurality of sequential driving units for driving a current flowing in an LED sequentially and selectively driven according to a magnitude of a rectified power source by a constant current in an LED unit. The sequential driving unit sequentially drives The emitter terminal is connected to the cathode of each LED to be selectively driven and the driving transistor drives the current flowing in the LED portion according to the driving control signal input to the base terminal by a constant current.

The LED driving device according to the present invention separates the driving control chip part and the driving part separately so that only the current for controlling the driving part flows through the driving control chip part and the current flowing through the LED part is driven by the constant current, So that the LED unit having a high capacity can be manufactured simply and inexpensively as one drive control chip unit.

FIG. 1 shows a circuit diagram of an LED constant current driving device according to an embodiment of the prior art 1. In FIG.
2 is a diagram for explaining heat loss generated in a conventional driving integrated circuit.
3 is a view for explaining an embodiment of a conventional large capacity LED.
4 is a functional block diagram for explaining an LED driving apparatus according to the present invention.
5 shows a circuit diagram according to an embodiment of the LED driving apparatus according to the present invention.

Hereinafter, the LED driving apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.

4 is a functional block diagram for explaining an LED driving apparatus according to the present invention.

The power supply unit 10 rectifies the AC power to generate a DC rectified power, and supplies the generated rectified power to the LED unit 300. In the LED unit 300, a plurality of LEDs are sequentially connected in series, and the LED unit 300 emits light using the rectified power supplied from the power supply unit 10. The power supply unit 10 includes a rectifying circuit for rectifying the AC power to the DC rectification power supply, for example, a bridge rectifier circuit, and rectifies the input AC power to generate a DC power in the form of a positive sine wave. The LED unit 300 sequentially emits LEDs corresponding to the driving voltage of the LEDs connected in series as the size of the rectifying power source sequentially increases.

2, the driving unit 200 increases the size of the rectified power supplied to the LED unit 300, so that the LED unit 300 is turned on and the LED unit 300 is turned on. As a result, At the driving voltage of the combination, the constant current is driven to flow through the LED unit 300 consisting of the current LED combination until the driving voltage of the next LED combination including the LEDs sequentially connected to the current LED combination is reached. The driving control chip unit 100 detects the magnitude of the current flowing through the LED unit 300 and drives the driving unit 200 based on the detected current magnitude to drive the LED unit 300 to drive the constant current to flow through the driving unit 200. [ And generates a driving control signal for driving the driving circuit.

Here, the driving control chip unit 100 compares a current detection unit that detects the magnitude of the current flowing through the LED unit 300 and a comparison voltage generated by the reference voltage and the detected current magnitude. When the comparison voltage exceeds the reference voltage, And a control signal generator for generating a drive control signal for driving a current flowing through the LED unit with a constant current according to a magnitude of an amplified output.

More specifically, the operation of the LED driving apparatus according to the present invention increases the size of the rectifier power supplied from the power supply unit 10 to the LED unit 300 to reach the driving voltage of the first LED of the LED unit 300 The first LED emits light and the electric current flowing in the LED part 300 of the LED combination consisting of only the first LED flows along the sequential driving part 1 to the sequential driving part m. The driving control chip unit 100 detects the magnitude of the current flowing through the LED unit 300 and is composed of a second LED whose magnitude of the rectified power supply is sequentially connected to the first LED and the first LED based on the detected current magnitude And generates a driving control signal for causing a constant current to flow through the LED unit 300 until it reaches the driving power source of the LED combination, and provides the driving control signal to the sequential driving unit 1.

On the other hand, the size of the rectified power supplied from the power supply unit 10 to the LED unit 300 increases to reach the driving voltage of the LED combination consisting of the first LED and the second LED sequentially connected to the LED unit 300 The first LED and the second LED emit light and the electric current flowing through the LED unit 300 flows along the sequentially driving unit 2 to the sequential driving unit m. The driving control chip unit 100 detects the magnitude of the current flowing through the LED unit 300 and detects the magnitude of the rectified power supply based on the detected current magnitude by using a third LED sequentially connected to the LED combination of the first LED and the second LED Generates a drive control signal for causing a constant current to flow through the LED unit 300 until reaching the drive power source of the next LED combination included therein, and provides the drive control signal to the sequential drive unit 2. Similarly, the LEDs constituting the LED unit 300 are sequentially added to the combination of the LEDs constituting the LED unit 300 so that a constant current flows even if the size of the rectification power source increases.

Even if the size of the rectifying power source is increased, most of the heat loss is generated in the sequential driving unit as the constant current flows through the LED unit 300. The driving control chip unit 100 simply detects the size of the current flowing through the LED unit 300 Thereby generating a drive control signal for controlling the driving unit 200. [ Since the drive control chip unit 100 and the drive unit 200 are manufactured separately from each other, heat loss hardly occurs in the drive control chip unit 100 even when the LED 300 having a large capacity is driven, A driving apparatus for driving a large capacity LED by causing heat loss can be manufactured simply and inexpensively.

5 shows a circuit diagram according to an embodiment of the LED driving apparatus according to the present invention.

5, the current detection unit 110 includes a resistor R18 connected to the output terminal of the LED unit 300 to which the plurality of LEDs LM1 to LM5 are connected in series. The error amplifier unit 120 includes a current The output terminal of the detection unit 110 is connected to the base terminal and the emitter terminal is connected to the power supply unit 10 and the collector terminal is connected to the drive signal generation unit 130. The drive signal generation unit 130 Includes a plurality of transistors Q1 to Q5 each having an output terminal connected to the base terminal of the error amplifier 120 and a collector terminal connected to the sequential driving unit 210 constituting the driving unit 200. [ The emitter terminal of the transistor Q5 is connected between the output terminal of the driving unit 200 and the input terminal of the current detecting unit 110 and the emitter terminals of the transistors Q4, Q3, Q2 and Q1 are connected to the collector terminals of the transistors Q5, Q4, Q3, And a sequential driving unit 210. [ Here, the LED constituting the LED unit 300 may be one LED having a large capacity or an LED module composed of a plurality of LEDs.

Here, the sequential driving unit 210 has a source terminal connected to the cathode of each LED sequentially selected and driven according to the magnitude of the rectified power in the LED unit 300, and the LED unit 300 is driven according to the driving control signal input to the gate terminal. A field effect transistor (FET) that drives a current flowing in a constant current circuit.

In the driving unit 200, the current flowing through the LED unit 300 of the LED combination selected according to the size of the rectified power source is inputted to the emitter terminal, and the base terminal is connected to the transistors Q1 to Qn constituting the driving signal generating unit 130. [ And a plurality of driving transistors Q9 to Q13 connected to the collector terminals of the transistors Q5 and Q5. The collector terminal of the transistor Q13 is connected to the input terminal of the current detection unit 110 and the collector terminals of the transistors Q12, Q11, Q10 and Q9 are connected to the emitter terminals of the transistors Q13, Q12, Q11 and Q10, respectively.

5, if the power is supplied from the power supply unit 10, each LED of the LED unit 300 emits light. The current flowing in the LED unit 300 is detected through the resistor R18 which is the current detecting unit 110 and the voltage by the current detected by the current detecting unit 110 is the reference voltage of the transistor Q1 The transistor Q7 of the error amplifier 120 is driven to amplify and output the current flowing through the LED unit 300 and the voltage fluctuated by the current amplified and outputted by the error amplifier 120 is outputted as the driving signal And is input to the base terminals of the transistors Q1 to Q5 of the generation unit 130. [

At this time, the transistor Q7 of the error amplifier 120 is an error amplifier which is a relative amplifier having a comparable voltage. In order to have an amplification degree with respect to an input voltage of 0 voltage or negative voltage in a general transistor, a bias current, If the bias voltage is not applied to the transistor Q7 as shown in FIG. 5 of the present invention, it operates as an error amplifier having a reference voltage Vbe. That is, the collector current does not flow unless the comparison voltage (the voltage generated by the current detected by the current detection unit 110) is equal to or higher than the Vbe voltage (the comparison voltage), and the collector current flows from the Vbe voltage do. Therefore, the transistor Q7 constituting the error amplifier 120 is used as an error amplifier.

The voltages of the transistors Q1 to Q5 of the driving signal generating unit 130 vary due to the current amplified and outputted by the error amplifier 120 inputted to the base terminal of the transistors Q1 to Q5, For example, the reference voltage of Q1 is Vbe of Q1, the reference voltage of Q2 is Vbe of Vce + Q2 of Q1, the reference voltage of Q3 is Vbe of Vce + Q2 of Qce of Q1, Is Vbe of Vce + Q2 of Q1 + Vce + Q4 of Q3 of Q3, and the reference voltage of Q5 is Vce of Vce + Q2 of Q1 + Vce of Qce of Q4 + Q4 of Q4).

When the size of the rectified power supplied to the LED unit 300 increases, power is supplied to the LED1, LED2, LED3, LED4, and LED5 that are sequentially connected according to the increasing rectified power. The magnitude of the current flowing through the combination of the LEDs selected by the LED unit 300 is detected according to the size of the power source and the current flowing through the collector terminals of the transistors Q1 to Q5 of the drive signal generation unit 130 . The magnitude of the current flowing through the collector terminal operates as a drive control signal to control the emitter current of each of the transistors Q9 to Q13 constituting the sequential driving unit 210 of the driving unit to control the LED unit 300 as a constant current.

Since only the control current for generating the drive control signal is input to the drive control chip unit 100 and the current flowing through the LED unit 300 is controlled by the drive unit 200 with a constant current, So that heat loss is generated in the driving unit 200 to be manufactured. Therefore, even if one integrated circuit including the current detector 110, the error amplifier 120, and the drive signal generator 130 is used, the large-capacity LED unit can be driven.

6 shows a circuit diagram according to another embodiment of the LED driving apparatus according to the present invention.

FIG. 6 is the same as the circuit diagram according to the embodiment of the present invention described above with reference to FIG. 5, except that there is no sequential driver circuit corresponding to LED1. In this case, the heat loss generated by the drive control chip 100 is not large, and thus the LED1 and the LED2 are increased to the rectified voltage for driving the LED1 and the LED2 It is possible to generate heat loss in the transistor Q1 of the drive control chip unit 100 without providing a separate sequential drive unit. When the LED1 and the LED2 can be driven, that is, when a rectified voltage equal to or higher than the threshold value is applied, the drive unit 200 generates heat loss.

The heat generated by the driving control unit 100 and the driving unit 200 can be selectively generated according to the size of the rectifying power source without causing the driving unit 200 to generate all of the heat loss generated by driving the large- The loss can be shared between the driving control chip unit 100 and the driving unit 200 and the circuit of the driving unit 200 can be simplified.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: power supply unit 100: drive control chip
110: current detector 120: error amplifier
130: driving signal generator 200:
300: LED section

Claims (6)

A power supply for supplying rectified power;
An LED unit having one or more LEDs connected in series and emitting light using a rectified power supplied from the power unit;
A drive control chip unit for detecting a magnitude of a current flowing through the LED unit and generating a drive control signal for controlling a current flowing in the LED unit with a constant current; And
And a driving unit for driving a current flowing sequentially to the LEDs constituting the LED unit by a constant current according to the driving control signal and the size of the rectifier garden,
The driving unit is manufactured separately from the driving control chip unit,
Wherein the driving unit includes a plurality of sequential driving units for driving a current flowing through LEDs sequentially and selectively driven according to the size of the rectifying power source,
Wherein the plurality of sequential drivers sequentially apply a current flowing through the LEDs after the first LED among the LEDs connected in series to the constant current source to selectively dissipate heat loss in the drive control chip portion and the drive portion according to the size of the rectification power source. And the LED driving device drives the LED driving device. delete The driving control apparatus according to claim 1,
A current detector for detecting a magnitude of a current flowing through the LED unit;
An error amplifier for comparing the reference voltage with a comparison voltage generated by the detected current magnitude and for amplifying and outputting the detected current magnitude when the comparison voltage exceeds the reference voltage; And
And a control signal generator for generating a drive control signal for driving a current flowing through the LED unit with a constant current according to the magnitude of the amplified output. delete delete delete

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