KR20110137174A - Led driving device - Google Patents

Abstract

PURPOSE: An LED operation apparatus is provided to control a power efficiency calibrator according to a current amount of an LED, thereby utilizing the output of the power efficiency calibrator as a boost circuit for LED operation. CONSTITUTION: An LED part(800) comprises an LED(810). A control part(600) uniformly controls a current supplied to the LED part by receiving current feedback of the LED part. A rectifier part(200) rectifies an AC power source(100). A power efficiency calibrator(300) controls power efficiency of power rectified in the rectifier part according to a control signal of the control part. A switching part(400) switches output power of the power efficiency calibrator according to the control signal of the control part. A transformer(500) converts power applied according to the switching operation of the switching part according to a predetermined winding ratio. A synthesizing part(700) rectifies both end current outputted in the transformer. An efficiency improvement part(900) acquires maximum efficiency improvement effects by changing an inductance value.

Description

LED driving device {LED driving device}

The present invention relates to LED, and more particularly, to an LED (Light Emitting Diode) driving device with improved power supply efficiency.

In general, currently widely used light emitting diodes (LEDs) are widely used for transmitting various signals or emitting light in electronic products such as home appliances, TVs, and monitors.

When the voltage applied to the LED is greater than or equal to the threshold voltage, a current starts to flow in the LED to generate light. In order to drive the LED, a low voltage DC power is supplied using a battery, a battery, or a power supply.

As a device for supplying the low voltage DC power supply described above, a power supply device is mainly used. The power supply device receives commercial AC power and converts it into a predetermined DC power supply, and converts it into a LED driving power and supplies it to the LED. do.

At this time, the power supply for driving the LED is controlled according to the dimming (Dimming) signal from the outside and the brightness of the LED can be adjusted accordingly.

On the other hand, the conventional power supply device described above is electromagnetically coupled with the primary coil and the primary coil receiving the AC power in order to convert the commercial AC power into a predetermined DC power source is a secondary that converts the voltage according to the turns ratio A circuit that uses a transformer with a coil and drives the LED using the DC voltage of the transformer is added, which causes a problem of low power conversion efficiency and complexity of the circuit.

1 and 2 show a LED driving method according to the prior art.

1 is a diagram illustrating a driving method having a plurality of channels (CHANNELs below a plurality of LED series connection modules) according to the prior art, in which a plurality of channels are connected to the output of a DC output or a BOOST circuit to drive in parallel. . It has a constant current method in which a transistor and a resistor are connected to the rear of each channel. However, when the deviation of each channel occurs, the current is adjusted by changing the resistance of the transistor. However, this poses a problem for efficiency because it is, after all, like a resistive load.

2 is also an exemplary road driving method having a plurality of channels according to the prior art, a method of adding a boost circuit for each channel. Using this method, a boost circuit is used for each channel, and current can be matched without a constant current circuit using a transistor or the like. However, the LED driving method of FIG. 2 has a loss in the process of boosting the direct current back to the boost circuit, and there is a problem in that the circuit is complicated because a boost circuit such as the number of channels is used.

like this. As shown in FIG. 1 or FIG. 2, when driving a high voltage or a plurality of channels, a problem of complexity and efficiency of a circuit occurs in the conventional methods.

The technical problem to be achieved by the present invention is to solve the conventional problems by directly driving the LED of the secondary power stage using the primary power source, by providing an LED drive device to improve the driving efficiency, to simplify the circuit and efficiency To increase.

LED driving device according to a feature of the present invention for solving this problem,

An LED unit including at least one light emitting element;

Rectifying unit for receiving rectified AC power;

A switching unit for switching the rectified power according to an external control signal;

A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;

A synthesizer for rectifying, synthesizing and outputting currents at both ends output from the transformer;

An efficiency improving unit for charging and discharging corresponding to the frequency of the output of the synthesis unit and supplying a current to the LED unit;

And a control unit for controlling the switching unit so that the current supplied to the LED unit is fed back and the current supplied to the LED unit is constant.

LED driving device according to another feature of the present invention for solving this problem,

An LED unit including at least one light emitting element;

Rectifying unit for receiving rectified AC power;

A switching unit for switching the rectified power according to an external control signal;

A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;

A synthesizing unit configured to drive the LED by rectifying and synthesizing the currents at both ends output from the transformer;

An efficiency improving unit connected to a rear end of the LED unit and configured to charge / discharge in response to a frequency of a current flowing in the LED unit;

And a control unit for controlling the switching unit so that the current supplied to the LED unit is fed back and the current supplied to the LED unit is constant.

LED driving device according to another feature of the present invention for solving this problem,

An LED unit including at least one light emitting element;

A control unit which receives the current from the LED unit and controls the current supplied to the LED unit to be constant;

Rectifying unit for receiving rectified AC power;

A power efficiency correction unit adjusting power efficiency of the power rectified by the rectifier according to a control signal of the controller;

A switching unit for switching the output power of the power efficiency correction unit according to a control signal of the control unit;

A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;

A synthesizing unit configured to drive the LED by rectifying and synthesizing the currents at both ends output from the transformer;

And an efficiency improving unit for charging and discharging corresponding to the output frequency of the synthesis unit and supplying the discharge unit to the LED unit.

LED driving device according to another feature of the present invention for solving this problem,

An LED unit including at least one light emitting element;

A control unit which receives the current from the LED unit and controls the current supplied to the LED unit to be constant;

Rectifying unit for receiving rectified AC power;

A power efficiency correction unit adjusting power efficiency of the power rectified by the rectifier according to a control signal of the controller;

A switching unit for switching the output power of the power efficiency correction unit according to a control signal of the control unit;

A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;

A synthesizing unit configured to drive the LED by rectifying and synthesizing the currents at both ends output from the transformer;

It is connected to the rear end of the LED unit, and includes an efficiency improving unit for charging and discharging corresponding to the frequency of the current flowing in the LED unit.

The efficiency improving unit is a coil having a predetermined inductance, characterized in that connected in series with each LED of the LED unit in series.

The coil of the efficiency improving unit increases energy efficiency by charging / discharging energy according to the output frequency of the transformer.

The inductance of the coil of the efficiency improving unit may obtain the maximum efficiency improvement effect by changing the inductance value according to the driving type such as the driving power of the LED channel and the frequency supplied from the LED driving power supply.

The switching unit switches primary power using various (Half OR Full Bridge, Push-pull, etc.) topologies, and transfers the switched power to the primary coil of the transformer for driving the LED.

The output of the transformer is output from the secondary coil in accordance with the power supply waveform of the primary coil side, which is the output of the switching unit, rectified to the + power in the rectifier circuit to drive the LED, and the switching supplied to the primary coil The output is changed according to a negative switching waveform.

In addition, the output of the transformer may be added to the Vpeak reduction circuit, the current balance circuit and the like between the LED, it is characterized in that the DC smoothing circuit, such as the existing electric cap, the boost circuit is omitted.

The control unit controls the secondary output of the transformer for directly driving the LED by controlling the switching unit on the transformer primary side by receiving the output current of the LED unit feedback.

In the embodiment of the present invention, by providing a driving device for directly driving the LED by using the isolation transformer by controlling the primary PFC output voltage, the DC (DC) conversion is not performed, it is possible to increase the efficiency. In addition, there is no need for an electric cap (ELEC-CAP) in the DC converter and a circuit such as a BOOST circuit (IC, IC peripheral circuit, inductor for BOOST, ELEC-CAP, FET, DIODE, etc.) is not required. Can be simplified. In addition, by providing a control integrated circuit for LED direct drive, the LED is driven without an electric cap, boost circuit, etc. in the output stage of the transformer, so the output voltage can be designed according to the voltage of the LED channel from low voltage to high voltage, The number of channels in the LED can be reduced. In addition, the output of the transformer by the control IC for driving the LED DIRECT is directly output to the LED unit through rectification of the diode, so that the LED driving current can be varied by the duty of the frequency in the control unit. In addition, it is possible to convert the LED driving current.

In addition, if necessary, the LED driving device has a variability that allows the output of the power efficiency correction unit to be used as a boost circuit for driving the LED by breaking the power efficiency correction unit according to the amount of current of the LED.

The provision of this control unit enables direct driving of LEDs using isolated transformers driven by various switching topologies (SWITCHING TOPOLOGY, Half OR Full Bridge, Push-pull, Flyback, Forward, etc.) for improved efficiency and simplified circuits. Done. In addition, since the output can be variously designed using a control unit frequency, duty, PFC voltage change, etc., there is an advantage that the design becomes easy.

In addition, in the embodiment of the present invention, by adding an efficiency improving unit and driving a plurality of LEDs by using an efficiency improving coil having an efficiency improving unit having an inductance value, energy efficiency is achieved by achieving higher efficiency than conventional methods. Many savings can be achieved.

This breaks the conventional method of converting DC / DC which drives in order of AC power, primary DC, secondary LED, and boosting DC to drive multiple LEDs. In the circuit that simplifies the circuit and increases the efficiency by driving the LED by using the direct insulation transformer, the output current is made close to the square wave to the sine wave, and the continuity of the output by discharging the charged energy when the output is off Can be maximized to increase efficiency.

This inserts an efficiency improvement coil to increase efficiency in LED driving using an insulation transformer for increasing efficiency, and thus, the efficiency improvement effect is superior to that of the LED driving method using a conventional DC. In addition, in the method of directly driving the LED after rectification using an insulated transformer, other semiconductor devices requiring high breakdown voltage due to high output voltage in series driving of a plurality of LEDs by increasing efficiency with only an efficiency improving coil having inductance. Unlike the circuit, the circuit can be easily configured using only the efficiency coil having sufficient breakdown voltage.

1 or 2 is an exemplary view showing a conventional LED driving method.
3 is a configuration diagram showing an LED driving apparatus according to a first embodiment of the present invention.
4 and 5 are each waveform diagram of FIG.
6 is a configuration diagram showing an LED driving apparatus according to a second embodiment of the present invention.
7 is a configuration diagram showing an LED driving apparatus according to a third embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

3 is a configuration diagram of the LED driving apparatus according to the first embodiment of the present invention.

Referring to FIG. 3, in the first embodiment of the present invention, the AC input unit 100, the AC rectifier 200 (including DC), the power efficiency correcting unit 300, the switching unit 400, the transformer 500, and the controller 600, the synthesis unit 700, the LED unit 800, and the efficiency improvement unit 900.

In the block diagram of FIG. 3, the internal circuit components are only schematic illustrations for explanation, not actual connection relationships, and other components are additionally connected, and the detailed configuration is not shown because the internal configuration of the block is well known in the art. Did.

The LED unit 800 includes an LED 810 therein and emits light according to the supply of current. The current supplied to the LED is fed back to the controller 600 by using a device such as a transistor, a resistor, or the like (not shown).

The controller 600 receives the current from the LED unit 800 and controls the current supplied to the LED unit 800 to be constant.

The rectifier 200 receives the AC AC power supply 100 and rectifies the rectifier 200.

The power efficiency corrector 300 adjusts the power efficiency of the power rectified by the rectifier 200 according to the control signal of the controller 600, and may be omitted as necessary.

The switching unit 400 switches the output power of the power efficiency correcting unit 300 according to the control signal of the control unit 600. When there is no power efficiency correcting unit 300, the switching unit 400 outputs the output signal of the rectifying unit 200. Switch.

The transformer 500 converts the power applied according to the switching of the switching unit 400 according to a predetermined turns ratio and outputs the outputs at both ends. A partial output waveform is schematically illustrated in FIG. 3.

The synthesizer 700 rectifies, synthesizes, and outputs currents at both ends output from the transformer using diodes 710 and 720, respectively.

The efficiency improving unit 900 charges and discharges the internal coil L1 in response to the frequency of the square wave signal output from the combining unit 700, and directly drives the LED unit 800 with this waveform.

The efficiency improving unit 900 is a coil (L1) having a predetermined inductance, it is characterized in that connected in series with the LED 810 of the LED unit 800 in series.

The coil L1 of the efficiency improving unit 900 increases energy efficiency by charging / discharging energy according to the output frequency of the transformer 500.

The inductance of the coil of the efficiency improving unit 900 may obtain the maximum efficiency improvement effect by changing the inductance value according to the driving type such as the driving power of the LED channel and the frequency supplied from the LED driving power supply.

In the embodiment of the present invention, the booster circuit, various additional circuits, and the like are omitted, thereby simplifying the circuit and significantly reducing the manufacturing cost.

The switching unit 400 switches primary power using various (Half OR Full Bridge, Push-pull, etc.) topologies as necessary, and transfers the switched power to the primary coil of the transformer for driving the LED.

The output of the transformer 500 outputs from the secondary coil according to the power supply waveform of the primary coil side, which is the output of the switching unit 400, and rectifies it to + power in the rectifier circuit to drive the LED, 1 The output is changed according to the switching waveform of the switching unit 400 supplied to the difference coil.

In addition, the output of the transformer 500 may be added a Vpeak reduction circuit, a current balance circuit, and the like between the LED, it is characterized in that the DC smoothing circuit, such as a conventional electric cap, a boost circuit is omitted.

The control unit 600 controls the secondary output of the transformer for directly driving the LED by controlling the switching unit of the transformer primary side by receiving the feedback of the output current of the LED unit.

The operation of the LED driving device will be described with reference to the waveforms of FIGS. 4 and 5 as follows.

Referring to FIG. 3, the AC power is input from the AC input unit 100 and converted into DC through the AC rectifying unit 200.

Then, the power efficiency correction unit 300 is output at a predetermined voltage.

The switching unit 400 switches in a switching method using a half or a full bridge, and switches the primary PFC output voltage under the control of the controller 600.

If necessary, the controller 600 may control the switching unit 400 or the power efficiency calibration unit 300 to obtain a desired output voltage.

Then, the output voltage of the switching unit 400 generates an induced current according to a predetermined turns ratio through the insulating transformer 500 for driving the LED. 4 or 5, switching signals are output to both ends of the insulation transformer 500 according to the output signals SWITCHING SIGNAL1 and SWITCHING SIGNAL2 of the switching unit 400, and the two outputs are respectively synthesized units ( After rectification by the diodes 710 and 720 of the 700 (SECONDARY DIODE OUT1, SECONDARY DIODE OUT2), the signal is synthesized and outputted as one + power supply.

Then, the efficiency improving unit 900 charges and discharges in response to the frequency of the output signal of the internal coil (L1) and outputs the waveform of the signal approximating the sine wave (LED INPUT VOLT, LED INPUT CURRENT) LED unit 800 To drive the LED 810.

Here, the waveform when the efficiency improving unit 900 is not used is shown in FIG. 4, and the output waveform when the efficiency improving unit 900 is used is shown in FIG. 5.

Referring to FIG. 4 or 5, an output waveform close to the square wave of FIG. 4 is deformed to be a sine wave as a pulse due to the effect of charging / discharging by the coil L1 having an inductance.

These waveforms may be transformed into a pulse current including direct current or a half-wave rectified shape with zero points by various variables such as the capacity of coil L1, output frequency and output current, and switching topology. In addition, the efficiency improving coil L1 of the efficiency improving unit 900 may be designed to have an inductance that obtains maximum efficiency according to such a variable, thereby maximizing efficiency.

 The configuration of the first embodiment may be variously modified according to the shape and driving method of the coil.

In the first embodiment of the present invention, the LED unit 800 is directly driven by the output voltage of the transformer 500, and the LED is directly driven without going through an electric cap or a boost circuit as in the prior art. Therefore, the circuit can be simplified.

3, the control unit 600 receives a driving current from the LED unit 800 and generates a switching signal and a control signal PFC CONTROL to control an input signal of the transformer 500. This makes it possible to control the output of the transformer 500 that directly drives the LED.

The control unit 600 of FIG. 3 is merely an example for direct LED driving, and the topology of the switching unit 400 (Half OR Full Bridge, Push-pull, Flyback, Forward, etc.) or a control method of the control unit 600 may be necessary. It is possible to modify accordingly. In addition, the power efficiency calibration unit 300 may be omitted if necessary, and in some cases, an additional circuit for reducing current balance or Vpeak may be added. In addition, the function of the controller may be added or reduced depending on the topology, additional circuits, and the like.

The control unit 600 controls the output of the insulation transformer 500 for directly driving the LED by controlling the switching unit 400 of the primary side by receiving the driving signal of the LED unit 800 on the secondary side of the transformer 500. Done.

The feedback input FEEDBACK of the integrated circuit is an LED driving current, and the controller 600 receives peak and RMS of the LED driving current.

The control unit according to the embodiment of the present invention may add an output control function in various ways as needed, and the control method may selectively use one function of frequency control, duty control, PFC control, or add all functions. It may be.

One example of such a modification will be described with reference to FIG. 6.

6 is a configuration diagram showing an LED driving apparatus according to a second embodiment of the present invention.

Referring to FIG. 6, in the second embodiment, the position of the efficiency improving unit 910 is modified to the rear end of the LED unit 800 in the first embodiment, and the detailed description thereof will be omitted since the remaining parts are the same and the same in operation.

7 is a configuration diagram illustrating an LED driving apparatus according to a third embodiment of the present invention.

FIG. 7 illustrates that the coils L! And L2 of the efficiency improving unit 900 are connected in parallel with the LEDs 810 and 820 of the LED unit 800 in the first embodiment. In the case of including, all operations are similar. Therefore, detailed description is omitted.

In addition, there may be an embodiment using a plurality of LEDs in the second embodiment of FIG. 6, and various modifications may be made as necessary.

As described above, in the exemplary embodiment of the present invention, by providing the integrated circuit which directly drives the LED by using the insulation transformer by controlling the output voltage of the first power efficiency correcting unit, DC conversion is not performed, thereby increasing efficiency. .

In addition, there is no need for the electric cap (ELEC-CAP) of the DC converter and no circuit such as BOOST circuit (IC, IC peripheral circuit, inductor for BOOST, ELEC-CAP, FET, DIODE, etc.) Can be simplified.

In addition, by providing a control integrated circuit for LED direct drive, the LED is driven without an electric cap, boost circuit, etc. in the output stage of the transformer, so the output voltage can be designed according to the voltage of the LED channel from low voltage to high voltage, The number of channels in the LED can be reduced.

In addition, the output of the transformer by the control unit for LED direct drive is output to the LED directly through the rectification of the diode, so that the LED drive current in the control unit can be changed using the duty of the frequency, in the case of the resonance type by the conversion of frequency It is also possible to convert the LED drive current.

In addition, if necessary, the controller controls the output voltage of the power efficiency correction unit 300 according to the amount of current of the LED, thereby having a variability that can be used as a BOOST circuit for driving the power efficiency correction unit 300.

This LED driver provides direct driving of LEDs using insulated transformers driven by various switching topologies (SWITCHING TOPOLOGY, Half OR Full Bridge, Push-pull, Flyback, Forward, etc.) to improve efficiency and simplify circuits. This becomes possible.

In addition, since the output can be designed in various ways using the frequency, duty, PFC voltage change of the control unit, there is an advantage that the design becomes easy.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (8)

An LED unit including at least one light emitting element;
Rectifying unit for receiving rectified AC power;
A switching unit for switching the rectified power according to an external control signal;
A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;
A synthesizer for rectifying, synthesizing and outputting currents at both ends output from the transformer;
An efficiency improving unit for charging and discharging corresponding to the frequency of the output of the synthesis unit and supplying a current to the LED unit;
And a controller configured to control the switching unit so that the current supplied to the LED unit is fed back and the current supplied to the LED unit is constant. An LED unit including at least one light emitting element;
Rectifying unit for receiving rectified AC power;
A switching unit for switching the rectified power according to an external control signal;
A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;
A synthesizing unit configured to drive the LED by rectifying and synthesizing the currents at both ends output from the transformer;
An efficiency improving unit connected to a rear end of the LED unit and configured to charge / discharge in response to a frequency of a current flowing in the LED unit;
And a controller configured to control the switching unit so that the current supplied to the LED unit is fed back and the current supplied to the LED unit is constant. An LED unit including at least one light emitting element;
A control unit which receives the current from the LED unit and controls the current supplied to the LED unit to be constant;
Rectifying unit for receiving rectified AC power;
A power efficiency correction unit adjusting power efficiency of the power rectified by the rectifier according to a control signal of the controller;
A switching unit for switching the output power of the power efficiency correction unit according to a control signal of the control unit;
A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;
A synthesizing unit configured to drive the LED by rectifying and synthesizing the currents at both ends output from the transformer;
And an efficiency improving unit for charging and discharging corresponding to the output frequency of the synthesis unit and supplying the discharge unit to the LED unit. An LED unit including at least one light emitting element;
A control unit which receives the current from the LED unit and controls the current supplied to the LED unit to be constant;
Rectifying unit for receiving rectified AC power;
A power efficiency correction unit adjusting power efficiency of the power rectified by the rectifier according to a control signal of the controller;
A switching unit for switching the output power of the power efficiency correction unit according to a control signal of the control unit;
A transformer for converting the power applied according to the switching of the switching unit according to a predetermined turns ratio and outputting the power to both ends;
A synthesizing unit configured to drive the LED by rectifying and synthesizing the currents at both ends output from the transformer;
And an efficiency improving unit connected to a rear end of the LED unit and configured to charge / discharge in response to a frequency of a current flowing in the LED unit. The method according to any one of claims 1 to 4,
The efficiency improving unit is a coil having a predetermined inductance, LED driving device, characterized in that connected in series with each LED of the LED unit in series. The method of claim 5,
The coil of the efficiency improving unit increases energy efficiency by charging / discharging energy according to the output frequency of the transformer, and the inductance of the coil of the efficiency improving unit increases the driving power of the LED channel and the frequency supplied from the LED driving power supply. Inductance value is determined according to the driving type of the LED driving device. The method of claim 6,
The synthesizing unit includes a first and a second diode for rectifying the power of both ends output from the transformer, and the LED driving device, characterized in that for synthesizing the output of the first and second diodes. The method of claim 7, wherein
LED output device, characterized in that the output of the both ends of the transformer is a square wave of opposite phase.

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