KR100673639B1 - Backlight inverter - Google Patents

Abstract

A backlight inverter is provided to detect the abnormal state of a lamp by separating a lamp current detector from a voltage detector by using a differentiator, N-channel switching devices and diodes when a power supplying signal is applied. A backlight inverter includes a switching driving unit(401) that generates a square wave signal, a transformer(402) that outputs an alternate current to a lamp(403), first and second resonance capacitors(C1,C2), a voltage detecting unit(Vsns) that detects voltages of nodes to which the first and second resonance capacitors are connected to output a feedback signal to the switching driving unit through an IC, a differentiator(404) that converts a power source signal into a differentiated signal, an N-channel switching device(M1) to be turned on and off when the converted signal is applied, a diode(D1), and a lamp current detector(Isns). The N-channel switching device(M1) is connected to the ground terminals of the first and second resonance capacitors(C1,C2) and is turned on or off when the converted signal is applied from the differentiator(404). The diode(D1) connects the N-channel switching device(M1) to the ground terminals of the first and second resonance capacitors(C1,C2) according to the turning on/off of the N-channel switching device(M1).

Description

Backlight Inverter {BACKLIGHT INVERTER}

1 is a circuit diagram of a backlight inverter according to the prior art,

2 is a circuit diagram of another backlight inverter according to the related art;

3 is a circuit diagram of another backlight inverter according to the related art;

4 is a circuit diagram of a backlight inverter according to the present invention;

5 is an equivalent circuit of a backlight inverter initially applied to a power signal;

6 is an equivalent circuit of a backlight inverter after a power signal is applied.

* Description of Major Symbols in Drawings *

401: switching driver 402: transformer

403: Lamp 404: Differential

Isns: Lamp current detector Vsns: Voltage detector

D1: diode M1: N-channel switching element

A: power signal B: differential signal

C1, C2: first and second resonance capacitors

The present invention relates to a backlight inverter, and by implementing a backlight inverter using a differentiator and an N-channel switching element and a diode, it is possible to stabilize the current flowing in the lamp early and to constantly control the lamp current, The present invention relates to a backlight inverter capable of detecting a state more easily.

In general, the backlight inverter has a function of turning on a lamp by converting a low voltage DC voltage into a high voltage AC voltage and maintaining a constant brightness of a user by maintaining a constant amount of current flowing through the lamp, that is, uniformity. The basic function is to have a luminance.

In recent years, however, a function of stably operating a backlight inverter by detecting an abnormal abnormal state of a lamp has also emerged as an important function.

 The reason is that since the final output voltage of the backlight inverter is a high voltage, when an abnormality occurs in the lamp load stage, it may cause a fire accident.

This necessity is increasingly demanded in conjunction with the recent entry into force of the PL law.

1 shows a circuit diagram of a backlight inverter according to the prior art.

As shown in FIG. 1, the backlight inverter of FIG. 1 includes a switching driver 101, a transformer 102, resonant capacitors C1 and C2, a voltage detector Vsns, and a lamp current detector Isns. Consists of.

In the backlight inverter of FIG. 1 configured as described above, the high voltage induced in the transformer 102 is applied to the hot end of the lamp, and the cold end is connected to the ground through the resistor R1. In the cold stage of the 103, the current of the backlight inverter is sensed.

This type of backlight inverter is mainly used for LCD panels of 32 inches or less having a relatively small length of the lamp 103.

In the backlight inverter as described above, a high voltage is induced at the output terminal of the transformer 102, and the lamp 103 emits light at the induced voltage. At this time, a lamp current sensed connected to the cold end of the lamp 103 is sensed. Since the current I3 flowing through the lamp 103 is directly sensed through negative Isns, the current I3 flowing through the lamp is constant regardless of the amount of the current I2 flowing through the resonance capacitors C1 and C2. Can be controlled.

In addition, a separate lamp voltage detector Vsns is disposed between the resonant capacitors C1 and C2 to separate the lamp current detector Isns and the voltage detector Vsns, thereby making it easier to detect a lamp abnormal state. have.

For example, when the lamp is opened, an example is described. When the lamp is opened, the potential of the lamp current sensing unit Isns becomes close to 0V and the potential of the hot end of the transformer 102 rises.

In this case, an IC (not shown) outputs a feedback signal corresponding to the result to the switching driver 101, and the switching driver 101 receives a square wave signal having a duty width increased by the feedback signal. The output increases the potential of the voltage sensing unit Vsns.

Therefore, when the lamp current detector Isns and the voltage detector Vsns are separated, information about the potential of the lamp current detector Isns and the potential of the voltage detector Vsns can be simultaneously transmitted to the IC. IC can detect the abnormal state of the lamp more easily.

2 shows a circuit diagram of another conventional backlight inverter.

As shown in FIG. 2, the backlight inverter of FIG. 2, like the backlight inverter of FIG. 1, includes a switching driver 201, a transformer 202, resonance capacitors C1 and C2, a voltage sensing unit Vsns, and a lamp. It consists of a current sensing unit (Isns).

However, in comparison with the backlight inverter of FIG. 1, in the backlight inverter of FIG. 1, the cold end of the lamp is grounded through the resistor R1, whereas the backlight inverter of FIG. Since the cold end is directly grounded, the current I3 flowing through the cold end of the lamp 203 cannot be directly detected.

Accordingly, in order to control the current I3 flowing through the lamp 203, a resistor R1 is connected between one side of the secondary coil of the transformer 202 and the ground, and the lamp is connected between the secondary coil and the resistor R1. Connect the current sensing unit Isns.

In this case, the current sensed by the lamp current sensing unit Isns is a current I1 induced by the transformer 202. Accordingly, a current value that can be controlled by an IC (not shown) is the resonance capacitor ( The current I2 flowing through C1 and C2 and the current I3 flowing through the lamp are added together.

However, since the lamp impedance is considerably large at the beginning of driving, but gradually decreases after driving, the current I3 flowing in the lamp 203 initially flows less and then gradually increases over time, thereby resonating capacitors. The current I2 flowing to C1 and C2 gradually decreases over time.

In addition, in the backlight inverter of FIG. 2, since the cold end of the lamp is directly grounded, it is not necessary to form a long feedback line, thereby reducing the unit cost of the product. Like the backlight inverter of FIG. 1, the lamp current sensing Since the unit Isns and the voltage sensing unit Vsns are separated, a lamp abnormal state can be easily detected.

3 shows a circuit diagram of another backlight inverter according to the related art.

As shown in FIG. 3, the backlight inverter of FIG. 3, like the backlight inverter of FIG. 2, has a switching driver 301, a transformer 302, resonance capacitors C1 and C2, a voltage sensing unit Vsns, and a lamp. It consists of a current sensing unit Isns, and the cold end of the lamp 303 is directly grounded.

Accordingly, as in the backlight inverter of FIG. 2, the transformer 302 may be configured to control the current I3 flowing through the lamp 303 because the current I3 flowing through the cold end of the lamp 303 may not be directly detected. A resistor R1 is connected between one side of the secondary coil and ground, and a lamp current detector Isns is connected between the secondary coil and the resistor R1.

However, in comparison with the backlight inverter of FIG. 2, the backlight inverter of FIG. 2 has a structure in which a lamp current sensing unit and a voltage sensing unit are separated, whereas the backlight inverter of FIG. 3 includes the resonance capacitors C1 and C2. There is a difference in that the lamp current sensing unit Isns and the voltage sensing unit Vsns are connected by connecting the ground side and one side of the secondary coil.

Accordingly, in the backlight inverter of FIG. 3, when the current I3 flowing in the lamp increases, the resonance capacitors C1 and C2 are reduced using the characteristic that the current I2 flowing to the resonance capacitors C1 and C2 decreases. Since it is possible to directly detect the current I2 flowing through), it is possible to constantly control the lamp current I3 according to the change in the lamp impedance.

In addition, as in the backlight inverter of FIG. 3, since the cold end of the lamp is directly grounded, the backlight inverter of FIG. 3 does not need to form a long feedback line, thereby reducing the cost of the product.

However, in the backlight inverter of FIG. 1 as described above, when the length of the lamp is longer, a higher high voltage is required for the lamp discharge. At this time, when a high voltage of 2 KV or more is applied, the corona phenomenon and the breakdown voltage of the transformer are destroyed. Since there may be a safety problem, there was a problem that can not be used in 40-inch or larger LCD panel in which a long straight lamp or a U-shaped lamp is used.

In addition, since expensive wires are required to form a long feedback line at the cold end of the lamp, there is a problem in that the cost of the product increases.

On the other hand, the backlight inverter of FIG. 2 as described above has a problem in that the current flowing through the lamp is changed due to the initial driving and subsequent change in the lamp impedance, so that the current flowing through the lamp cannot be constantly controlled.

Meanwhile, in the backlight inverter of FIG. 3 as described above, as the lamp current detection unit and the voltage detection unit are connected, the potential induced in the resonance capacitor acts as a resistance of the lamp current detection unit, and thus the potential of the lamp current detection unit is 0V. As a result, the potential difference between the lamp current detection unit in the normal operation and the lamp current detection unit in the abnormal lamp condition is only 0.2V to 0.4V.

Therefore, if the inductor value of the transformer and the integer value of the shutdown circuit are not precisely controlled, the shutdown circuit may operate even during normal operation, which may cause a problem in that the backlight inverter is stopped.

The present invention has been proposed to solve the above problems, and when the power signal is applied, the lamp current detection unit and the voltage detection unit are separated by using a differentiator, an N-channel switching element, and a diode, so that an abnormal state of the lamp can be more easily detected. The purpose is to provide a backlight inverter.

In addition, the present invention, by connecting the lamp current sensing unit and the voltage sensing unit using the differential and N-channel switching element and diode during normal operation after the power signal is applied, thereby stabilizing the current flowing through the lamp early, thereby Another object is to provide a backlight inverter capable of constantly controlling the current at all times.

In addition, another object of the present invention is to provide a backlight inverter capable of lowering the cost of a product by directly grounding the cold end of the lamp.

The objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. It will also be appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The backlight inverter according to the present invention for achieving the above object, the switching driver for generating a square wave signal for controlling the lamp current by a feedback signal corresponding to the magnitude of the lamp current; A transformer for boosting a square wave signal generated by the switching driver to a winding ratio of a primary coil and a secondary coil and outputting an alternating current to the lamp; First and second resonance capacitors connected in parallel to one side of the secondary coil of the transformer; A voltage connected between the first and second resonant capacitors to sense a voltage of a node to which the first and second resonant capacitors are connected, and output a feedback signal corresponding to the result to the switching driver through an IC Sensing unit; A differentiator for converting the power signal into a differential signal ('differential signal') when the power signal of the backlight inverter is applied; An N-channel switching element connected to the ground sides of the first and second resonance capacitors and turned on / off when the differential signal is applied; According to the on / off operation of the N-channel switching element, a node (hereinafter referred to as a 'connection node') formed by connecting the N-channel switching element and the ground side of the first and second resonance capacitors is grounded, or the connection node A diode connecting the other side of the secondary coil of the transformer; And detecting a voltage corresponding to the lamp current through a voltage detecting resistor connected to the other side of the secondary coil of the transformer and grounded at the other side of the secondary coil, and comparing the detected voltage with a preset reference voltage. And a lamp current detector configured to output a feedback signal corresponding to a result to the switching driver through an IC.

Here, the differentiator, when the power signal of the backlight inverter is applied, converts the power signal of the backlight inverter into a differential signal of the high type to turn on the N-channel switching device.

In this case, the diode is characterized in that the voltage sensing unit and the lamp current detection unit is separated by grounding the connection node.

On the other hand, the differential is characterized in that after the power signal of the backlight inverter is applied, converts the power signal of the backlight inverter into a differential signal of the low form to turn off the N-channel switching element.

In this case, the diode is characterized in that for connecting the connection node and the other side of the secondary coil to connect the voltage sensing unit and the lamp current sensing unit.

On the other hand, the N-channel switching element is characterized in that the N-channel FET.

In this case, the N-channel FET is characterized in that the differential signal is applied to the gate terminal, the source terminal is connected to the ground side of the first and second resonance capacitors, the drain terminal is grounded.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be.

In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

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

4 shows a circuit diagram of a backlight inverter according to the present invention.

As shown in FIG. 4, the backlight inverter according to the present invention is a backlight inverter that turns on the lamp 403 by converting a low voltage DC voltage into a high voltage AC voltage, and includes a switching driver 401, a transformer 402, The first and second resonance capacitors C1 and C2, the voltage sensing unit Vsns, the differentiator 404, the N-channel switching element M1, the diode D1, and the lamp current sensing unit Isns are included. .

Here, the switching driver 401 generates a square wave signal for controlling the lamp current by a feedback signal corresponding to the current magnitude of the lamp 403.

In addition, the transformer 402 boosts the square wave signal generated by the switching driver 401 to the turns ratio of the primary coil and the secondary coil and outputs an alternating current to the lamp 403.

At this time, the alternating current output from the transformer 402 includes a distortion component because the square wave signal is an induced alternating current, and in order to make the alternating current included in the distortion component into an alternating current having almost no distortion component. The first and second resonance capacitors C1 and C2 are connected in parallel to one side of the secondary coil of 402.

In addition, the voltage sensing unit Vsns is connected between the first and second resonance capacitors C1 and C2 to determine the voltage of the node to which the first and second resonance capacitors C1 and C2 are connected. The sensing signal is output to the switching driver 401 through an IC (not shown).

On the other hand, the differentiator 404 is configured by connecting the resistor R2 and the capacitor C3 in parallel, and when the power signal A of the backlight inverter is applied, converts the power signal A to the differential signal ( To b).

In addition, the N-channel switching device M1 is turned on / off when the differential signal B converted by the differentiator 404 is applied. At this time, the N-channel switching device M1 is a bipolar junction of the N-channel. A transistor BJT, a field effect transistor (FET), a metal oxide semiconductor field effect transistor (MOSFET), a metal semiconductor field effect transistor (MESFET), or the like may be used.

In the following description, the N-channel switching device M1 will be described based on the FET of the N-channel. However, the technical idea of the present invention can be applied to all devices that can be used for switching devices as well as N-channel FETs. Thus, although the description herein focuses on N-channel FETs, the concept and scope of the present invention is not limited to N-channel FETs.

Accordingly, the differential signal B is applied to the gate terminal of the N-channel FET M1, the source terminal is connected to the ground sides of the first and second resonance capacitors C1 and C2, and the drain terminal is It is grounded.

On the other hand, the diode D1 grounds the connection node C according to the on / off operation of the N-channel FET M1, or the secondary coil of the connection node C and the transformer 402. Connect the other side of the (D).

In addition, the lamp current detector Isns is connected to the other side D of the secondary coil of the transformer 402 and has a voltage detecting resistor R1 grounded at the other side D of the secondary coil. The voltage corresponding to the lamp current is sensed and a feedback signal corresponding to a result of comparing the detected voltage with a preset reference voltage is output to the switching driver 401 through an IC.

Since the backlight inverter of the present invention configured as described above has a structure in which the cold end of the lamp 403 is directly grounded, there is no need to form a long feedback line, thereby reducing the cost of the product. do.

Hereinafter, a process of operating the backlight inverter of the present invention configured as described above will be described in detail with reference to FIGS. 4 to 6.

5 illustrates an equivalent circuit of the backlight inverter initially applied with the power signal A, and FIG. 6 illustrates an equivalent circuit of the backlight inverter after the power signal A is applied.

First, when the power signal A of the backlight inverter is applied, that is, when the power signal A of the backlight inverter is changed from a low to a high signal, the gate of the N-channel FET M1 is applied. The differential signal B having a high shape is applied by the differentiator 404, and thus, the FET M1 of the N-channel is turned on.

Accordingly, since the diode D1 is connected to the ground in the reverse direction and the connection node C is grounded, the backlight inverter according to the present invention may be configured with an equivalent circuit as shown in FIG. 5.

On the other hand, after the power signal A of the backlight inverter is applied, that is, when the power signal A of the backlight inverter maintains a high signal, the differentiator 404 is applied to the gate of the N-channel FET M1. By the low differential signal B is applied, the N-channel FET M1 is turned off.

Therefore, the connection node C and the other side D of the secondary coil are connected by the diode D1, and thus, the voltage sensing unit Vsns and the lamp current sensing unit Isns are connected. Therefore, the backlight inverter according to the present invention may be configured as an equivalent circuit of the type shown in FIG.

In general, it is preferable to detect an abnormal state of the lamp as soon as the power signal is applied, and to perform a normal inverter operation thereafter if the abnormal state of the lamp is not detected.

Therefore, the backlight inverter according to the present invention has a configuration in which the lamp current detection unit and the voltage detection unit are separated at the initial stage of application of the power signal so that the lamp abnormal state can be more easily detected. Since the voltage sensing unit is connected to have a configuration that can control the current of the lamp constantly, the current flowing through the lamp can be stabilized early so that the lamp current can be always controlled constantly, and the lamp abnormality can be more easily controlled. It will have a detectable effect at the same time.

One preferred embodiment of the present invention described above is disclosed for the purpose of illustration, various substitutions, modifications and changes within the scope without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains Modifications may be made and such substitutions, changes and the like should be regarded as belonging to the following claims.

As described above, the backlight inverter according to the present invention can detect a lamp abnormal state more easily by separating the lamp current sensing unit and the voltage sensing unit by using a differentiator, an N-channel switching element, and a diode when a power signal is applied. It works.

In addition, the lamp current sensing unit and the voltage sensing unit are connected by using differentiator and N-channel switching element and diode during normal operation after power signal is applied, thereby stabilizing the current flowing through the lamp early, and thus the current flowing through the lamp is always constant. There is an effect that can be controlled.

In addition, by directly grounding the cold end of the lamp, there is no need to form a long feedback line, there is an effect that can reduce the unit cost of the product.

Claims (7)

In a backlight inverter that turns on a lamp by converting a low voltage DC voltage into a high voltage AC voltage, The backlight inverter, A switching driver for generating a square wave signal for controlling lamp current by a feedback signal corresponding to a lamp current magnitude; A transformer for boosting a square wave signal generated by the switching driver to a winding ratio of a primary coil and a secondary coil and outputting an alternating current to the lamp; First and second resonance capacitors connected in parallel to one side of the secondary coil of the transformer; A voltage connected between the first and second resonant capacitors to sense a voltage of a node to which the first and second resonant capacitors are connected, and output a feedback signal corresponding to the result to the switching driver through an IC Sensing unit; A differentiator for converting the power signal into a differential signal (hereinafter, referred to as a differential signal) when a power signal of the backlight inverter is applied; An N-channel switching element connected to the ground sides of the first and second resonance capacitors and turned on / off when a signal converted in the differentiator is applied; According to the on / off operation of the N-channel switching element, the node (hereinafter referred to as 'connection node') formed by connecting the N-channel switching element and the ground side of the first and second resonance capacitors is grounded, or the connection node A diode connecting the other side of the secondary coil of the transformer; And A result of comparing the detected voltage with a preset reference voltage by detecting a voltage corresponding to the lamp current through a voltage detecting resistor connected to the other side of the secondary coil of the transformer and grounded at the other side of the secondary coil And a lamp current detector for outputting a feedback signal corresponding to the switching driver through an IC. The method of claim 1, wherein the differentiator is And when the power signal of the backlight inverter is applied, converts the power signal of the backlight inverter into a differential signal of a high type to turn on the N-channel switching element. The method of claim 1, wherein the differentiator is And after the power signal of the backlight inverter is applied, converting the power signal of the backlight inverter into a low differential signal to turn off the N-channel switching element. The method of claim 2, The diode is a backlight inverter, characterized in that to ground the connection node to separate the voltage sensing unit and the lamp current sensing unit. The method of claim 3, And the diode connects the connection node and the other side of the secondary coil to connect the voltage sensing unit and the lamp current sensing unit. The method according to any one of claims 1 to 3, And said N channel switching element is an N channel FET. The method of claim 6, wherein the N-channel FET, And said differential signal is applied to a gate terminal, a source terminal is connected to ground sides of said first and second resonant capacitors, and a drain terminal is grounded.

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