KR100857301B1 - LED backlight driving circuit - Google Patents

Abstract

The present invention relates to an LED backlight driving circuit. The present invention provides a FET for supplying driving power as a constant duty ratio to an LED serving as a light source of a liquid crystal display, a feedback resistor for sensing the output voltage of the FET, and a constant current controller for maintaining a constant output current flowing through the LED; The sensing inductor further includes a main coil supplying pulse power to the LED by accumulating and discharging at a constant duty ratio according to the switching of the FET, and a sensing coil that senses the current state of the main coil and outputs it to the FET. And a PFC controller that performs switching of the FET according to the sensed voltage and the current state of the main coil. The present invention has the effect of supplementing the problem of cost increase and shortening the development period by applying a PFC constant voltage driving circuit, instead of using a higher heat resistant component according to the heat in the LED backlight driving circuit.

PFC, LED, Inductor, Drive, Circuit

Description

 LED backlight driving circuit

1 is a view showing a conventional LED backlight driving circuit.

2 is a view showing an LED backlight driving circuit of the present invention.

3 is a view showing another embodiment of a driving circuit of the LED backlight.

4 is a view showing another embodiment of a driving circuit of the LED backlight.

<Explanation of symbols on main parts of the drawings>

100-LED backlight drive circuit 103-inductor

103a-Main Coil 103b-Sensing Coil

106-FET 109-PFC Controller

112-Feedback Resistor 115-Switching Elements

118-Sensing Resistors 121-Comparators

123-LED 127-Capacitors

130-diode

The present invention relates to an LED backlight driving circuit.

In general, the driving of the LED is connected in series or parallel according to the application method of the LED and the power is turned on. Conventionally, a device for boosting or depressurizing according to the connection quantity and input voltage of the LED was required, and thus an AC-DC or DC-DC converter (converter) was used.

1 is a view showing a conventional LED backlight driving circuit.

The conventional LED backlight driving circuit 100 includes an inductor, a diode, a capacitor, a plurality of LEDs, a PWM controller, a FET, and a feedback resistor.

The LEDs 115 are combined in series or in parallel.

One terminal of the inductor 103 is connected in series with the positive terminal of the diode, and one terminal of the FET 106 is connected between one terminal of the inductor and the positive terminal of the diode. One terminal of the feedback resistor 118 is connected to the other terminal of the FET 106 and the other terminal of the feedback resistor 118 is grounded. The FET 106 is also connected to the PWM controller 121, which is connected to the other terminal of the inverter 103. The negative terminal of the diode 109 is connected to one terminal of the capacitor 112. The other terminal of capacitor 112 is grounded. The diode 109 serves to block the reverse flow of the output current to the LED 115, and the capacitor 112 serves to filter the output voltage to the LED 115.

When a DC power source is input from the outside, current flows from the inductor 103 to the FET 106 while the PWM controller 121 turns on the FET 106 to store energy in the inductor 103.

The PWM controller 121 senses the voltage of the feedback resistor 118, and turns off the FET when the voltage reaches the set voltage, and the energy of the inductor 103 passes the capacitor 112 through the diode 109. ) To power the LED 115. At this time, if the output voltage is continuously detected and lower than the set voltage, the FET 106 is turned on again and the above process is repeated.

At this time, the input / output parasitic capacitor and the inductor of the FET 106 are oscillated while oscillating to generate heat. Therefore, since a higher heat resistant component must be used in accordance with heat generation, there is a problem of cost increase, and a lot of attention is required in design, so there is a problem in that a development period is long.

The present invention applies a PFC constant voltage driving circuit to the LED backlight driving circuit, providing high efficiency and low heat generation.

The LED backlight driving circuit of the present invention maintains a constant FET for supplying driving power as a constant duty ratio to an LED serving as a light source of a liquid crystal display, a feedback resistor for sensing the output voltage of the FET, and an output current flowing through the LED. Sensing type including a constant current control unit for controlling, a main coil for supplying pulse power to the LED by accumulating / discharging at a certain duty ratio in accordance with the switching of the FET, and a sensing coil for sensing the current state of the main coil and outputs the FET And a PFC controller for switching the FET according to the inductor and the voltage sensed by the feedback resistor and the current state of the main coil.

In addition, the LED backlight driving circuit of the present invention includes a FET for supplying driving power as a constant duty ratio to an LED serving as a light source of a liquid crystal display, a feedback resistor for detecting an output voltage of the FET, and a constant duty according to switching of the FET. A sensing inductor including a main coil supplying pulse power to the LED by accumulating and discharging at a ratio, and a sensing coil sensing a current state of the main coil and outputting the current to the FET; a voltage sensed by the feedback resistor and the main coil; And a PFC controller for switching the FET according to a current state of the sensor, and a sensing resistor for detecting an output voltage of the LED and outputting the output voltage to the PFC controller.

The LED backlight drive circuit further includes a capacitor for filtering the output voltage to the LED and a diode to block the reverse flow of the output current to the LED. The PFC controller turns off the FET when the output voltage measured by the feedback resistor reaches a specific value, and turns on the FET when the output value of the sensing coil becomes 0 [V]. Perform control. The PFC controller also performs control to turn on the FET when the voltage applied to the LED is higher than the reference set value.

The constant current controller is configured to turn on / off the switching element by comparing a switching element for switching the current flowing in the LED on / off, a sensing resistor for sensing the current flowing in the LED array, and a current detected by the sensing resistor and a predetermined reference voltage. Comparator to turn off. At this time, the switching element is provided at the end of the LED.

The PFC controller has a constant current control algorithm that maintains a constant current flowing to the LED according to the value of the output voltage of the LED input from the sensing resistor, and the backlight driving circuit outputs the pulse type LED detected by the sensing resistor. A smoothing circuit converting a voltage into a DC value and providing the PFC controller, and an overvoltage detector for flowing an output voltage of the LED detected by the sensing resistor to ground when an overvoltage is detected with respect to a voltage applied to the LED. Include.

The current compensation circuit further includes a current compensating circuit which prevents the current of the LED from flowing to the PFC controller when a current exceeding the normal operating range of the PFC controller flows to the LED. The smoothing circuit is composed of an R-C parallel circuit. At this time, the smoothing circuit is located between the input terminal of the sensing resistor and the PFC controller.

The overvoltage detector is located between an input terminal node of the LED, a contact node between the smoothing circuit and the PFC controller, a divider resistor for distributing a voltage applied to the LED, a zener diode having a breakdown voltage value as an overvoltage value to be detected; When the switch is turned on due to the zener diode exceeding the breakdown voltage, the switching element includes a switching element for outputting the output voltage detected by the sensing resistor to the ground. When switching on, the overvoltage detector flows the detected output voltage to the ground only when the output voltage detected by the sensing resistor is higher than the offset voltage which becomes the overvoltage detection reference. In this case, the zener diode has a cathode located at the LED input terminal and an anode located at the control terminal of the switching element.

The backlight driving circuit further includes a pulse applying unit for applying pulse power to the LED, and the pulse applying unit includes a switch for performing an on / off operation according to a pulse signal received from a pulse controller, and forcing a high voltage to the FET. A reference power supply for turning off the FET is further included. In this case, the switching element is implemented by any one of a bipolar transistor (BJT) and a field effect transistor (FET).

The constant current controller is provided at the end of the LED, and the feedback resistor is located at the output terminal of the FET. In addition, a sense inductor is located between an external power source and the input terminal of the FET, and a sensing resistor is located at the end of the LED.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing an LED backlight driving circuit of the present invention.

The LEDs 123 are coupled in series or in parallel, and a plurality of LEDs are connected.

The FET 106 supplies driving power as a constant duty ratio to the LED 123 serving as a light source of the flat liquid crystal display.

The feedback resistor 112 is located at the output terminal of the FET 106 to sense the output voltage of the FET 106.

The constant current controller is provided at the end of the LED 123 to serve to keep the output current flowing in the LED 123 constant. The constant current control unit is provided at the end of the LED 123, the switching element 115 for switching the current flowing through the LED 123 on and off, the sensing resistor 118 for sensing the current flowing in the LED 123 array, The comparator 121 may be configured to compare the current sensed by the sensing resistor 118 with a predetermined reference voltage to turn on / off the switching element 115. In this case, the switching element 115 is implemented as one of a bipolar transistor (BJT) and a field effect transistor (FET).

The sensing inductor 103 is located between the external power supply 131 and the input terminal of the FET 106 to accumulate / discharge at a constant duty ratio according to the switching of the FET 106 to supply pulse power to the LED 123. The coil 103a and a sensing coil 103b which senses a current state of the main coil 103a and outputs it to the FET 106 are included.

A diode 130 for blocking the reverse flow of the output current to the LED 123 is connected to the output terminal of the sensing inductor 103, and a capacitor for filtering the output voltage to the LED 123 on the negative side of the diode 130 ( 127 is connected.

The PFC controller 109 performs switching of the FET 106 according to the voltage sensed by the feedback resistor 112 and the current state of the main coil 103a. In addition, when the output voltage measured by the feedback resistor 112 reaches a specific voltage, the FET 106 is turned off. When the output value of the sensing coil 103b becomes 0 [V], the FET 106 is turned off. Perform the control to turn ON. In addition, when the voltage applied to the LED is higher than the reference set value, the control to turn on the FET 106 is performed.

Next, another embodiment of the LED backlight driving circuit will be described.

3 is a view showing another embodiment of the driving circuit of the LED backlight, Figure 4 is a view showing another embodiment of the driving circuit of the LED backlight.

As shown, the LEDs 230 are connected in plural and are coupled in series or in parallel.

The FET 209 serves to supply driving power to the LED 230 as a constant duty ratio.

The feedback resistor 212 is located at the output terminal of the FET 209 to detect the output voltage of the FET 209.

The sensing inductor 203 is located between an external power supply and an input terminal of the FET 209 and accumulates / discharges at a constant duty ratio according to the switching of the FET 209 to supply pulse power to the LED 230 by the main coil 203a. And a sensing coil 203b which senses a current state of the main coil 203a and outputs it to the FET 209.

The output terminal of the sensing inductor 203 is connected to the diode 224 to block the reverse flow of the output current to the LED 230, the negative side of the diode 224 is a capacitor for filtering the output voltage to the LED 230 ( 227) is connected.

The PFC controller 206 performs switching of the FET 209 according to the voltage sensed by the feedback resistor 212 and the current state of the main coil 203a. When the output voltage measured by the feedback resistor 212 reaches a specific value, the FET 209 is turned off. When the output value of the sensing coil 203b becomes 0 [V], the FET 209 is turned off. Control to turn ON. In addition, the constant current control algorithm maintains a constant current flowing in the LED 230 according to the output voltage value of the LED 230 received from the sensing resistor 236.

The sensing resistor 236 is positioned at the end of the LED 230 to detect the output voltage of the LED 230 and output it to the PFC controller 206.

A smoothing circuit 233 is provided between the input terminal of the sensing resistor 236 and the PFC controller 206, which smoothes the output voltage of the pulse-shaped LED 230 detected by the sensing resistor 236. It converts into a DC value and provides the PFC controller 206, and consists of an RC parallel circuit.

An overvoltage detector 221 is positioned between the input terminal node of the LED 230 and the contact node of the smoothing circuit 233 and the PFC controller 206, and the overvoltage detector 221 is overvoltage with respect to a voltage applied to the LED 230. When this is detected, the output voltage of the LED 230 detected by the sensing resistor 236 flows to the ground. At this time, when the switch is turned on with an offset power supply circuit (not shown) at the lower end of one terminal of the switching element, only when the output voltage detected by the sensing resistor 236 is higher than the offset voltage which becomes the overvoltage detection reference. It is desirable to flow the detected output voltage to ground.

In addition, the overvoltage detector 221 includes a distribution resistor 239, a zener diode 242, and a switching element 245, and the distribution resistor 239 distributes the voltage applied to the LED 230. do. Zener diode 242 is connected to the cathode is located at the LED input terminal, the anode is located at the control terminal of the switching element, and serves as a breakdown voltage value of the overvoltage value to be detected.

The switching element 245 flows the output voltage detected by the sensing resistor 236 to ground when the switching element 245 is switched on due to the conduction of the zener diode 242 in excess of the breakdown voltage. At this time, an offset power supply circuit (not shown) is provided at one terminal of the switching element, and when the switching is turned on, the output is detected only when the output voltage detected by the sensing resistor is higher than the offset voltage serving as the overvoltage detection reference. It is desirable to flow the voltage to ground. In this case, the switching device 245 is implemented as one of a bipolar transistor (BJT) and a field effect transistor (FET).

3 and 4 further include a pulse applying unit for applying pulse power to the LED, the pulse applying unit adjusting the duty ratio (adjusting the brightness of the LED). And a reference power supply 218 for forcibly turning off the FET when a high voltage flows through the FET.

In addition, as another embodiment of the present invention similar to FIG. 3, but slightly different from FIG. 3, the current compensation circuit 251 may be further added. The current compensating circuit 251 compensates for the current of the LED within the normal operating range of the PFC controller when a high current flowing through the LED exceeds the normal operating range of the PFC controller.

As mentioned above, although this invention was demonstrated to the several example, this invention is not limited to a specific Example. Those skilled in the art will appreciate that various modifications and changes can be made without departing from the spirit of the invention.

The present invention has the effect of supplementing the problem of cost increase and shortening the development period by applying a PFC constant voltage driving circuit, instead of using a higher heat resistant component according to the heat in the LED backlight driving circuit.

Claims (23)

A Field Effect Transistor (FET) for supplying driving power as a constant duty ratio to the LED serving as a light source of the liquid crystal display, A feedback resistor for sensing the output voltage of the FET; A constant current adjusting unit for maintaining a constant output current flowing through the LED; A sensing inductor including a main coil supplying pulse power to the LED by accumulating / discharging at a constant duty ratio according to the switching of the FET, and a sensing coil sensing a current state of the main coil and outputting the current to the FET; Power Factor Correction (PFC) controller to switch the FET according to the voltage sensed by the feedback resistor and the current state of the main coil LED backlight driving circuit comprising a. A Field Effect Transistor (FET) for supplying driving power as a constant duty ratio to the LED serving as a light source of the liquid crystal display, A feedback resistor for detecting the output voltage of the FET; A sensing inductor including a main coil supplying pulse power to the LED by accumulating / discharging at a constant duty ratio according to the switching of the FET, and a sensing coil sensing a current state of the main coil and outputting the current to the FET; A power factor correction (PFC) controller for switching the FET according to the voltage sensed by the feedback resistor and the current state of the main coil; Sensing resistor that detects the output voltage of the LED and outputs it to the PFC controller LED backlight driving circuit comprising a. The LED backlight driving circuit according to claim 1 or 2, A capacitor to filter the output voltage to the LED, Diode to block the reverse flow of output current to the LED LED backlight driving circuit further comprising. 3. The PFC controller of claim 1, wherein the PFC controller turns off the FET when the output voltage measured by the feedback resistor reaches a specific value, and the output value of the sensing coil is set to 0 [V]. LED backlight driving circuit for performing a control to turn (ON) the FET when. The LED backlight driving circuit of claim 1, wherein the PFC controller performs control to turn on the FET when an applied voltage applied to the LED is higher than a reference setting value. The method of claim 1, wherein the constant current adjusting unit, Switching element to switch the current flowing through the LED on and off, A sense resistor that senses the current flowing through the LED array, Comparator to turn on / off the switching element by comparing the current sensed by the sensing resistor with a predetermined reference voltage LED backlight driving circuit comprising a. The method of claim 6, The switching device is LED backlight driving circuit, characterized in that provided at the end of the LED. The LED backlight driving circuit of claim 2, wherein the PFC controller has a constant current control algorithm that maintains a constant current flowing to the LED according to a value of the output voltage of the LED input from the sensing resistor. The method of claim 2, wherein the LED backlight driving circuit, A smoothing circuit converting the output voltage of the pulse type LED detected by the sensing resistor into a DC value and providing the same to the PFC controller; When an overvoltage is detected with respect to the voltage applied to the LED, the overvoltage detector sends an output voltage of the LED detected by the sensing resistor to the ground. LED backlight driving circuit further comprising. 10. The LED backlight driving circuit of claim 9, further comprising a current compensating circuit for preventing a current of the LED from flowing to the PFC controller when a current exceeding a normal operating range of the PFC controller flows to the LED. The LED backlight driving circuit according to claim 9, wherein the smoothing circuit is composed of an R-C parallel circuit. The method of claim 9, And the smoothing circuit is located between the input terminal of the sensing resistor and the PFC controller. The method of claim 9, And the overvoltage detector is located between an input terminal node of the LED and a contact node between the smoothing circuit and the PFC controller. The method of claim 9, wherein the overvoltage detector, Distribution resistors for distributing the voltage across the LED, A zener diode whose breakdown voltage value is an overvoltage value to be detected; Switching element that flows the output voltage detected by the sensing resistor to ground when the zener diode is turned on due to the excess of the breakdown voltage. LED backlight driving circuit comprising a. The method of claim 14, wherein the overvoltage detector, The LED backlight driving circuit, when switched on, flows the detected output voltage to the ground only when the output voltage detected by the sensing resistor is higher than the offset voltage which becomes an overvoltage detection reference. The method of claim 14, The zener diode is a LED backlight driving circuit, characterized in that the cathode is located at the LED input terminal and the anode is located at the control terminal of the switching element. The method according to claim 2 or 9 or 10, LED backlight driving circuit further comprising a pulse applying unit for applying a pulse power to the LED. The method of claim 17, wherein the pulse applying unit, A switch for performing an on / off operation according to a pulse signal received from a pulse controller; Reference power to forcibly turn off the FET when high voltage flows through the FET, LED backlight driving circuit further comprising. The method according to claim 6 or 14, The switching device is a LED backlight driving circuit implemented by any one of a bipolar transistor (BJT), a field effect transistor (FET). The method of claim 1, The constant current control unit LED backlight driving circuit, characterized in that provided at the end of the LED. The method according to claim 1 or 2, And the feedback resistor is located at an output terminal of the FET. The method according to claim 1 or 2, And the sensing inductor is positioned between an external power source and an input terminal of the FET. The method of claim 2, The sensing resistor is located at the end of the LED LED backlight driving circuit

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