KR20080013152A - Over voltage protection circuit in inverter - Google Patents

Abstract

An over-voltage protection circuit in an inverter is provided to improve the reliability of a product by stably operating a circuit of the inverter even if a voltage supplied to the inverter is over-voltage. Plural FETs(Field Effect Transistor)(105) receive a DC voltage from a power supplier to convert it into an AC voltage. A PWM(Pulse Width Modulation) controller(103) outputs a PWM signal to convert the DC voltage into an AC voltage. A main controller(104) outputs a signal for driving a gate of the FET according to the PWM signal. A transformer(106) boosts the AC voltage by a predetermined level. A voltage drop unit(201) drops the DC voltage by a predetermined level to supply it to the FETs. A relay(202) is connected in parallel to the voltage drop unit to supply the DC voltage to the FETs. A voltage detecting unit(204) compares the DC voltage dropped by the voltage drop unit with the reference voltage. A switching unit(203) outputs a switching signal for switching the relay.

Description

Over voltage protection circuit in inverter

1 is a schematic block diagram of a conventional backlight inverter.

2 is a schematic block diagram of an overvoltage protection circuit of an inverter for a backlight according to the present invention.

<Description of the code used in the main part of the drawing>

105: FET 201: voltage drop

202: relay 203: switching unit

204: a voltage detector

The present invention relates to an overvoltage protection circuit of an inverter for a backlight which is operated even when the voltage supplied is overvoltage.

In general, liquid crystal display devices (LCDs), unlike CRTs (Cathod Ray Tubes), do not have self-luminous properties and require a backlight, which is called a backlight, but consumes low power. It is one of the widely used flat panel displays because of its advantages such as being small and portable.

In order to supply power to the LCD backlight, a series of configurations are required in which the DC power supplied from the LCD's power supply is converted to AC power and boosted by a transformer to a high voltage.

A configuration of a conventional backlight inverter will be described with reference to FIG. 1.

1 is a schematic block diagram of a conventional backlight inverter, and includes a connection portion 101 connected to a power supply device (not shown) and a circuit at a later stage when a voltage input through the connection portion 101 is an overvoltage. A fuse for protection 102, a PWM controller 103 for generating a pulse width modulation signal (PWM signal) for converting a DC voltage to an AC voltage, and a PWM signal input from the PWM controller 103 A main controller 104 for outputting a gate driving signal, a plurality of FETs 105 for switching a DC voltage inputted by the gate driving signal output from the main controller 104 into an AC voltage, and It is composed of a transformer 106 for boosting the AC voltage output from the plurality of FETs 105 to a predetermined level according to the turns ratio of the primary side and the secondary side, and supplying it to the lamp for backlight. Here, a high voltage of about 600 [V] or more is required to drive a lamp in a general backlight inverter. That is, when the power supply and the inverter are connected through the connection portion 101, a DC voltage of a predetermined level is supplied from the power supply. Supplied to the inverter. The input voltage (DC voltage) is supplied to the plurality of FETs 105 through the fuse 102.

Meanwhile, in order to generate an AC voltage having a predetermined frequency, the PWM controller 103 generates and outputs a PWM signal having a predetermined period, and the main controller 104 uses the PWM signal supplied from the PWM controller 103. To generate and output gate driving signals GSH1 to GSL2 for switching the plurality of FETs 105. As the high levels GSH1 and GSH2 and the low levels GSL1 and GSL2 of the gate driving signals are sequentially and repeatedly outputted among the plurality of FETs 105, the plurality of FETs 105 are repeatedly switched, thereby inputting a DC voltage. Is converted to AC voltage. Thereafter, the transformer 106 boosts the converted AC voltage to a predetermined level according to the winding ratio and supplies the converted AC voltage to the lamp.

However, conventionally, when the inverter and the power supply are connected to receive power from the power supply, the DC voltage initially input may be unstable, or overvoltage or in-rush current may occur. In this case, in the conventional backlight inverter, since the power input from the power supply is directly supplied to the plurality of FETs 105 through the connection portion 101 and the fuse 102, the initial unstable voltage, overvoltage, inrush There is a problem that a plurality of FETs are damaged due to current.

In addition, if the inverter is excessively operated while the FET is damaged, an overcurrent flows to the FET, resulting in a breakdown of the FET, a short circuit of the fuse, and the like, thereby preventing the circuit from operating as a whole.

The present invention is to provide an overvoltage protection circuit of the inverter to improve the reliability of the product by operating the circuit in the inverter stably even when the voltage supplied to the backlight inverter is overvoltage.

The present invention comprises: a plurality of FETs for receiving a DC voltage from a power supply and converting it into an AC voltage; A PWM controller for outputting a pulse width modulated signal to convert the input DC voltage into an AC voltage having a predetermined frequency; A main controller configured to output gate driving signals of the plurality of FETs in response to a pulse width modulation signal output from the PWM controller; A transformer for boosting an AC voltage output from the plurality of FETs to a predetermined level and supplying the lamp to a lamp; A voltage drop unit for dropping a DC voltage input from the power supply device to a predetermined level and supplying the plurality of FETs; A relay connected in parallel with the voltage drop unit to supply a DC voltage input from the power supply to the plurality of FETs; A voltage detector comparing the DC voltage dropped in the voltage drop with a preset reference voltage; And a switching unit configured to output a switching signal for switching the relay according to a comparison result of the voltage detector.

Hereinafter, exemplary embodiment (s) of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the elements of each drawing, it should be noted that the same elements are denoted by the same reference numerals as much as possible even if they are displayed on different drawings. In addition, in the following description there are shown a number of specific details, such as components of the specific circuit, which are provided only to help a more general understanding of the present invention that the present invention may be practiced without these specific details. It is self-evident to those of ordinary knowledge in Esau. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Fig. 2 is a schematic block diagram of the overvoltage protection circuit of the backlight inverter according to the present invention. As shown in Fig. 2, between the connection portion 101 and the fuse 102 shown in Fig. 1, the connection portion 101 is shown. A voltage drop unit 201 for voltage dropping the DC voltage input through the power source; a relay 202 for switching the DC voltage input through the connection unit 101 to be transmitted to the fuse 102; A voltage detector 204 for detecting a level of the voltage dropped in the lower part 201 and comparing the voltage level higher than a preset reference voltage; and a switching unit for switching the relay 202 under the control of the voltage detector 204. (203) further.

In addition, when the voltage input through the voltage dropping unit 201 or the relay 202 is an overvoltage, a fuse 102 to protect a circuit at a later stage and a pulse width modulation signal for converting a DC voltage into an AC voltage. PWM controller 103 for generating a PWM signal, a main controller 104 for outputting a gate driving signal according to the PWM signal input from the PWM controller 103, and a output from the main controller 104. A plurality of FETs 105 for converting a DC voltage inputted by a gate driving signal into an AC voltage, and AC voltages output from the plurality of FETs 105 at predetermined levels according to turns ratios of the primary and secondary sides. And a transformer 106 for boosting and supplying the lamp to the backlight lamp. In the circuit of the present invention, the power supply and the inverter are connected through the connection portion 101, and when the DC voltage is supplied from the power supply, Switching unit 203 It maintains the relay 202 in the off state. Therefore, the input DC voltage is dropped to a predetermined level through the voltage drop unit 201.

The voltage detector 204 compares whether or not the level of the DC voltage dropped by the voltage drop unit 201 is equal to or less than the preset reference voltage. When the voltage detector 204 determines that the voltage falls below the reference voltage, the voltage detector 204 controls the switching unit 203 to relay 202. Turn on. Accordingly, the DC voltage supplied from the power supply is supplied to the plurality of FETs 105 through the fuse 102 in a state where no voltage loss occurs through the relay 202. On the other hand, the voltage detection unit 204 detects the voltage. When the dropped voltage is greater than or equal to the preset reference voltage, since the input DC voltage is an overvoltage or an inrush current, the voltage detector 204 controls the switching unit 203 to turn the relay 202 on. Turn it off.

Accordingly, the DC voltage (overvoltage, inrush current, etc.) input through the connection portion 101 is not directly transmitted to the fuse 102 through the relay 202, and is predetermined level through the voltage drop portion 201. The fuse is delivered to the fuse 102 and the plurality of FETs 105 in a low voltage drop state. Therefore, it is possible to prevent the FET 105 from being damaged due to overvoltage, inrush current, or the like.

Meanwhile, in order to generate an AC voltage having a predetermined frequency, the PWM controller 103 generates and outputs a PWM signal having a predetermined period, and the main controller 104 uses the PWM signal supplied from the PWM controller 103. To generate and output gate driving signals GSH1 to GSL2 for switching the plurality of FETs 105.

As the high levels GSH1 and GSH2 and the low levels GSL1 and GSL2 of the gate driving signals are sequentially and repeatedly outputted among the plurality of FETs 105, the plurality of FETs 105 are repeatedly switched, thereby inputting a DC voltage. Is converted to AC voltage. Thereafter, the transformer 106 boosts the converted AC voltage to a predetermined level according to the winding ratio and supplies the converted AC voltage to the lamp.

As described above, in the detailed description of the present invention, specific embodiment (s) have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiment (s), but should be defined by the claims below and equivalents thereof.

The present invention drops the input DC voltage to a predetermined level, compares the level of the dropped DC voltage with a preset reference level, and directly supplies the DC voltage to the FET or drops the voltage to a predetermined level according to the result. In this case, when the input DC voltage is an overvoltage or an inrush current, the FET is prevented from being damaged by the input voltage, thereby improving the reliability of the circuit.

Claims (1)

A plurality of FETs receiving a DC voltage from a power supply and converting the same into an AC voltage; A PWM controller for outputting a pulse width modulated signal to convert the input DC voltage into an AC voltage having a predetermined frequency; A main controller configured to output gate driving signals of the plurality of FETs in response to a pulse width modulation signal output from the PWM controller; A transformer for boosting an AC voltage output from the plurality of FETs to a predetermined level and supplying the lamp to a lamp; A voltage dropping unit supplying the plurality of FETs by dropping the DC voltage input from the power supply to a predetermined level; A relay connected in parallel with the voltage drop unit to supply a DC voltage input from the power supply to the plurality of FETs; A voltage detector comparing the DC voltage dropped in the voltage drop with a preset reference voltage; And And a switching unit for outputting a switching signal for switching the relay according to a comparison result of the voltage detection unit.

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