KR20050082707A - Circuit for supporting load of inverter - Google Patents

Abstract

The present invention relates to a load holding circuit of an inverter, and more particularly, to an inverter including an inverter controller, a switching circuit, a transformer, a plurality of cold cathode tubes, and a feedback circuit. And a signal adjusting circuit for sensing and a current adjusting circuit for changing a current value input to the inverter controller by adjusting a resistance value when an abnormality of each cold cathode tube is detected from the signal sensing circuit.

Therefore, according to the present invention configured as described above it is possible to prevent the generation of heat in the set or inverter by controlling the output current when the abnormality occurs in any one cold cathode tube to flow a constant current.

Description

Inverter load holding circuit {CIRCUIT FOR SUPPORTING LOAD OF INVERTER}

The present invention relates to an inverter, and more particularly, to a load holding circuit of an inverter using a plurality of cold cathode tubes connected in parallel.

In general, an inverter for a TFT LCD backlight refers to a DC / AC converter that drives a cold cathode tube by generating a high voltage using a transformer after converting DC power to AC power.

As shown in FIG. 1, the conventional inverter includes an on / off control circuit 11 and an on / off control circuit 11 for transmitting and blocking an input voltage of 12 V according to an on / off control signal input from the outside. The constant voltage circuit 12 converts the input voltage of 12V output through the constant voltage of 5V, which is a driving voltage, and outputs the constant voltage of 5V output from the constant voltage circuit 12 through the VDDA stage to drive the pulse type. An inverter controller 13 which outputs a driving signal and adjusts the luminance of the cold cathode tube 16 according to a dimming voltage input from the outside through the FB stage and a voltage fed back through the cold cathode tube, and a PDR of the inverter controller 13. Switching circuit 14 and switching circuit 14 for switching the input power of DC type inputted from the outside and outputting by switching according to the pulse type signal outputted from the stage and NDR stage, and outputting the AC power. A transformer 15 for boosting the AC power outputted from the transformer and outputting a high voltage, a plurality of cold cathode tubes 16 lit by the high voltage output from the transformer 15, and a current flowing through each of the cold cathode tubes 16. After sensing and changing to a voltage, the feedback circuit 17 outputs to the FB stage of the inverter controller 13, and the dimming circuit 18 generates a dimming voltage and outputs the output to the FB stage of the inverter controller 13 according to external control. )

Referring to the operation of such an inverter, when the on / off control signal (high) is input to the on / off control circuit 11 while the input voltage of 12V is supplied to the inverter, the on / off control circuit 11 is 12V. The input voltage is supplied to the constant voltage circuit 12, and the constant voltage circuit 12 changes the input 12V input voltage to a constant voltage and applies it to the inverter controller 13.

The inverter controller 13 generates a driving signal when a constant voltage of 5 V is applied to the VDDA stage, and then outputs the driving signal to the switching circuit 14. The switching circuit 14 changes the input power to an AC voltage according to the driving signal. And print it out. When the AC voltage is output from the switching circuit 14, the transformer 15 boosts the voltage to a high voltage and outputs the same to the respective cold cathode tubes 16 to light up each cold cathode tube 16.

On the other hand, the current passing through each cold cathode tube 16 is converted into a voltage in the feedback circuit 17 is input to the inverter controller 13, the inverter controller 13 checks the state of the cold cathode tube 16 through this. . In addition, when the dimming voltage is output from the dimming circuit 18 according to the user's adjustment or external control, the inverter controller 13 controls the switching circuit 14 to adjust the brightness of the cold cathode tube 16.

Herein, the operation of the feedback circuit 17 will be described in more detail. The sum of the output currents of the cold cathode tube 16, that is, the load, is Io, and Io is always kept constant by the inverter controller 13. This is because Vs (sense voltage) is kept constant by the internal compensation circuit of the inverter controller 13, and the smaller the resistance value of the sensing resistor Rs, that is, the smaller the Vs, the Io increases.

Vs is expressed as the product of Io and Rs. If the resistance value of the sensing resistor Rs is fixed, Io is always constant, where I1 = I2 = I3 = I4 = 1/4 * Io.

On the other hand, if any one of the cold cathode tubes 16 is broken or disconnected, Vs is kept constant, but Io is I2 + I3 + I4, and Io is constant so that I2 = I3 = I4 = 4/3 * Io. . The three loads generate the same energy as the previous four loads, so the variation in brightness is small, but each load current increases by about 30%, which increases the power by 30% for each load. As the power increases, the heat generated in the load increases to increase the stress in the set by 30%, increases the stress in the transformer 15 and the switch circuit 14, and increases the temperature by about 30%, causing malfunction or breakage.

That is, the conventional inverter has a problem in that when the output current is not interlocked with the load abnormality and the load is abnormal, heat is generated in the set or the inverter, thereby causing a malfunction or even a fire.

Therefore, an object of the present invention is to solve the above problems, and to prevent the generation of heat in the set or inverter by adjusting the output current when the abnormality occurs in any one cold cathode tube flows. .

Features of the present invention for achieving the above object,

An inverter controller which controls the system as a whole, a switching circuit which is switched according to a pulse signal output from the inverter controller, and changes the input power of a DC type input from the outside into an AC power source, and outputs from the switching circuit. A transformer for boosting AC power and outputting a high voltage, a plurality of cold cathode tubes lit by a high voltage output from the transformer, and a current flowing through each of the cold cathode tubes is sensed and changed into a voltage and outputted to the inverter controller. In the inverter comprising a feedback circuit,

A signal sensing circuit for detecting whether each of the cold cathode tubes is abnormal;

And a current regulating circuit for varying a current value input to the inverter controller by adjusting a resistance value when an abnormality of each cold cathode tube is detected from the signal sensing circuit.

Here, the signal detection circuit,

A diode switched according to whether or not the respective cold cathode tubes are abnormal;

A first FET interlocked with the switching of the diode,

And a second FET interlocked with the first FET.

Here also the diode,

Connected to the respective cold cathode tubes in a forward direction,

The first FET,

A gate is connected in parallel to the cathode of the diode, a drain is connected to a reference voltage terminal, a source is grounded to ground,

The second FET,

A gate is connected to the drain of the first FET, a drain is connected to the reference voltage terminal, and a source is grounded to ground.

Here, the current control circuit,

A third FET interlocked with the second FET of the signal sensing circuit;

It includes a load resistor for varying the current value input to the inverter controller in accordance with the switching of the third FET.

Here again the third FET,

A gate is connected to the drain of the second FET of the signal sensing circuit, a drain is connected to the reference voltage terminal, a source is grounded to ground,

The load resistance is,

It is connected to the drain of the first FET is connected in parallel with the sensing resistor of the inverter controller.

Here, the resistance value of each load resistance is

All the same,

The sum of the resistance values of the respective load resistances is

It is equal to sensing resistance.

Hereinafter, the configuration of the load holding circuit of the inverter according to the present invention will be described in detail with reference to FIGS. 2 and 3. In FIG. 2, the same parts as those of the inverter shown in FIG. 1 are given the same reference numerals as in FIG. 1, and description thereof will be omitted.

2 is a block diagram showing the configuration of an inverter to which the load holding circuit of the inverter according to the present invention is applied, and FIG. 3 is a circuit diagram showing each component of the load holding circuit of the inverter according to the present invention.

2 and 3, the load holding circuit 100 of the inverter according to the present invention includes a signal sensing circuit 110 and a current adjusting circuit 120.

The signal sensing circuit 110 is connected to the diode D1 connected to each of the cold cathode tubes 16 in a forward direction so as to be switched depending on whether or not the respective cold cathode tubes 16 are abnormal. A gate of the cathode of D1 is connected in parallel, a drain is connected to a reference voltage terminal, and the drain of the first FET Q1 is interlocked with the first FET Q1 and the source is grounded to the ground. A gate is connected to the drain, a drain is connected to the reference voltage terminal Vref, and a second FET Q2 having a source grounded to ground.

The current control circuit 120 has a gate connected to the drain of the second FET Q2 of the signal sensing circuit 110 so as to be interlocked with the second FET Q2 of the signal sensing circuit 110, and to the reference voltage terminal Vref. A drain is connected and connected to the drain of the first FET Q1 to vary the current value input to the inverter controller 13 according to the switching of the third FET Q3 and the source grounded to the ground. And a load resistor R _L connected in parallel with the sensing resistor Rs of the inverter controller 13. Here, the resistance values of each load resistor R _L are all the same, and the sum of the resistance values of each load resistor R _L is equal to the resistance value of the sensing resistor Rs.

Hereinafter, the operation of the load holding circuit of the inverter according to the present invention will be described in detail with reference to FIGS. 2 and 3.

Current is applied to the inverter controller 13 and the signal sensing circuit 110 through the respective cold cathode tubes 16. If the first cold cathode tube 16 is abnormally operated, the current is supplied to the signal sensing circuit 110. Is not authorized.

Then, the diode D1 of the signal sensing circuit 110 is turned off, which causes the first FET Q1 to be turned off.

When the first FET Q1 is turned off, the drain of the first FET Q1 is turned high by the applied voltage of the reference voltage terminal Vref, so that the second FET Q2 is turned on.

When the second FET Q2 is turned on, the drain of the second FET Q2 becomes the ground level, and the third FET Q3 of the current control circuit 120 is turned off.

When the third FET Q3 is turned off, the load resistor R _L is electrically disconnected from the sensing resistor Rs connected to the input terminal of the inverter controller 13.

On the other hand, the diode D1 of the signal sensing circuit 110 connected to the other cold cathode tube 16 is turned on, so that the first FET Q1 is turned on, and the second FET Q2 is turned off. The third FET Q3 is turned on to connect the load resistor R _L with the sensing resistor Rs connected to the input terminal of the inverter controller 13.

Then, the resistance value of the sensing resistor Rs increases due to the disconnection of the load resistor R _L connected to the cold cathode tube 16 in which an abnormality occurs. As the resistance of the sensing resistor Rs increases, Vs also increases, and Io decreases. The reduced Io here is I 2 + I 3 + I 4, which is lower than the initial Io.

Thus, the other cold cathode tube 16 generates brightness as much as the current decreases, but heat is not generated because it maintains the designed initial current.

Therefore, when an abnormality of any one of the cold cathode tubes occurs, the current is reduced by that much, and an overcurrent is applied to the remaining cold cathodes, thereby preventing heat from being generated.

As described above, according to the load holding circuit of the inverter according to the present invention, when an abnormality occurs in any one of the cold cathode tubes, the output current is adjusted so that a constant current flows, thereby preventing heat from being generated in the set or the inverter. have.

1 is a block diagram showing the configuration of a conventional inverter

Figure 2 is a block diagram showing the configuration of the inverter to which the load holding circuit of the inverter according to the present invention is applied

Figure 3 is a circuit diagram showing each component of the load holding circuit of the inverter according to the present invention

<Description of the symbols for the main parts of the drawings>

13 Inverter Controller 16 Cold Cathode Tube

17: feedback circuit 100: load holding circuit

110: signal detection circuit 120: current control circuit

D1: diodes Q1 to Q3: first to third FETs

R _L : load resistance

Claims (6)

An inverter controller which controls the system as a whole, a switching circuit which is switched according to a pulse signal output from the inverter controller, and changes the input power of a DC type input from the outside into an AC power source, and outputs from the switching circuit. A transformer for boosting AC power and outputting a high voltage, a plurality of cold cathode tubes lit by a high voltage output from the transformer, and a current flowing through each of the cold cathode tubes is sensed and changed into a voltage and outputted to the inverter controller. In the inverter comprising a feedback circuit, A signal sensing circuit for detecting whether each of the cold cathode tubes is abnormal; And a current adjusting circuit for adjusting a resistance value to change a current value input to the inverter controller when an abnormality of each cold cathode tube is detected from the signal sensing circuit. The method of claim 1, The signal detection circuit, A diode switched according to whether or not the respective cold cathode tubes are abnormal; A first FET interlocked with the switching of the diode, And a second FET interoperating with the first FET. The method of claim 2, The diode, Connected to the respective cold cathode tubes in a forward direction, The first FET, A gate is connected in parallel to the cathode of the diode, a drain is connected to a reference voltage terminal, a source is grounded to ground, The second FET, And a gate is connected to the drain of the first FET, a drain is connected to the reference voltage terminal, and a source is grounded to the ground. The method of claim 3, wherein The current control circuit, A third FET interlocked with the second FET of the signal sensing circuit; And a load resistor for varying a current value input to the inverter controller according to the switching of the third FET. The method of claim 3, wherein The third FET, A gate is connected to the drain of the second FET of the signal sensing circuit, a drain is connected to the reference voltage terminal, a source is grounded to ground, The load resistance is, The load holding circuit of the inverter, characterized in that connected to the drain of the first FET in parallel with the sensing resistor of the inverter controller. The method of claim 4, wherein The resistance value of each load resistance is All the same, The sum of the resistance values of the respective load resistances is The load holding circuit of the inverter, characterized in that the same as the sense resistance value.