KR100811837B1 - Inverter protection circuit - Google Patents

Abstract

An inverter protection circuit is provided to improve stability by stopping an inverter by inputting a specific signal into a microcomputer by an overcurrent protecting unit and an overvoltage protecting unit. An inverter protection circuit(10) includes an inverter(12), a microcomputer(13), an overcurrent protecting unit(15), and an overvoltage protecting unit(14). The inverter supplies a driving signal to a load(11) to control an operation of the load. The microcomputer supplies a driving voltage for operating the inverter and a driving signal serving as a level signal for controlling an output signal, and stops the input of the driving signal into the inverter. The overcurrent protecting unit receives a signal of the load and inputs a predetermined signal into the microcomputer so as to stop the inverter when an overcurrent is generated in the load. The overvoltage protecting unit inputs a predetermined signal into the microcomputer so as to stop the inverter.

Description

Inverter Protection Circuit {INVERTER PROTECTION CIRCUIT}

1 is a block diagram schematically showing a configuration according to an embodiment of the present invention.

FIG. 2 is a circuit diagram illustrating the configuration of FIG. 1 in more detail. FIG.

<Description of Signs of Major Parts of Drawings>

10: inverter protection circuit 11: load

12: inverter 13: microcomputer

14: overcurrent protection unit 15: overvoltage protection unit

The present invention relates to an inverter protection circuit of a backlight for a liquid crystal panel.

Recently, due to the rapid development of technology in the semiconductor industry, small, lighter weight and more powerful products are being produced. Among them, the liquid crystal display device is currently installed in almost all information processing equipment requiring a display device.

The liquid crystal display device has an optical property such as birefringence, photoreactivity, dichroism, and light scattering characteristics of a liquid crystal cell that applies voltage to a specific molecular array of liquid crystal, converts it into another molecular array, and emits light by the molecular array. It converts a change into a visual change, and is a display apparatus using the modulation of the light by a liquid crystal cell.

Since the liquid crystal display is a light-receiving element that does not emit light by itself, the liquid crystal panel is illuminated by using a backlight attached to the rear surface of the liquid crystal panel. The light transmittance of the liquid crystal panel is adjusted according to an applied electrical signal, and a still image or a moving image is correspondingly represented on the liquid crystal panel.

An inverter is usually used to drive the backlight of the liquid crystal display, and the inverter receives a driving signal from a power supply of a system to which the backlight is applied and a signal for adjusting the brightness of the backlight from the PWM generator. Control the operation.

In this case, when an overcurrent or overvoltage occurs in the backlight, an electric shock is applied to the backlight in an unprotected state, thereby causing damage.

An object of the present invention is to provide an inverter protection circuit which protects a backlight from overcurrent and overvoltage.

The present invention provides an inverter for controlling the operation by supplying a drive signal to the load; A microcomputer supplying a driving signal for controlling the output voltage and a driving voltage for operating the inverter, and stopping input of the driving signal to the inverter when a specific signal is input; An overcurrent protection unit for receiving the signal on the load side in real time and inputting a specific signal to stop the operation of the inverter when the overcurrent occurs on the load side; Receiving a real-time signal of the load side, if an overvoltage occurs on the load side, includes an overvoltage protection unit for inputting a specific signal to stop the operation of the inverter to the microcomputer.

In the present invention, when an overcurrent or an overvoltage occurs on the load side, the overcurrent protection unit and the overvoltage protection unit input a specific signal to the microcomputer to stop the operation of the inverter, so that the load operates in an abnormal state and receives an electric shock. Will be prevented.

  Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a block diagram schematically illustrating a configuration according to an embodiment of the present invention, and FIG. 2 is a circuit diagram illustrating the configuration of FIG. 1 in more detail.

First, the present invention, as shown in the accompanying drawings, Figures 1 and 2, 10 denotes an inverter protection circuit of the present invention, and the inverter 12 for supplying a drive signal to the load 11 to control the operation: The microcomputer 13 supplies a driving signal for controlling the output signal and a driving voltage for operating the inverter 12, and stops input of the driving signal to the inverter 12 when a specific signal is input: The overcurrent protection unit 14 receives a signal on the load 11 side in real time, and inputs a specific signal to stop the operation of the inverter 12 when the overcurrent occurs on the load 11 side. ) And: overvoltage protection for receiving a signal on the load 11 side in real time, and inputting a specific signal to stop the operation of the inverter 12 when the overvoltage occurs on the load 11 side. It characterized in that it comprises a portion (15).

For reference, the description of the present invention will be described one embodiment by applying the load 11 in two, it is noted that one or more of the number of the load 11 can be applied.

Here, the above-described load 11 of one embodiment of the present invention may be a CCFL (cold cathode ray tube) or EEFL (external electrode light emitting lamp), may be an LED (light emitting diode), and if necessary, a fluorescent lamp or an incandescent lamp It may also be the same general.

In addition, as long as it is the load which can be driven by another inverter, all are applicable.

Meanwhile, the above-described inverter 12 of the embodiment of the present invention receives power from a power supply of a main system such as a notebook and operates a full bridge circuit including an inverter FET for driving the load 11, It may be a FET driver IC for adjusting the brightness of the lamp 1 (11) by receiving the brightness control signal from the PWM signal generator, or may be a discrete circuit for implementing the above function.

In addition, the microcomputer 13 described above in one embodiment of the present invention, if the input voltage is changed to adjust the state of the load, at a predetermined frequency (normal design reference value 165 Hz ± 10 Hz) to the output terminal by a preset internal program An IC chip that outputs a square wave whose duty is determined.

In addition, the above-described overcurrent protection unit 14 of the embodiment of the present invention receives the signal of the load 11 side after the output terminal of the inverter 12, but when the LOW level due to the instant load short state, TURN -TR14 15 (Q14) (Q15) to be turned OFF: TURN-ON by TURN-OFF of TR14-15 (Q14) (Q15), and resistance 106 while passing through resistors 106-107 (R106) (R107). And FET16 (Q16) which conducts and transfers a 5V Ref value voltage-dropped to a specific signal to the microcomputer 13 according to the time constant of 107 (R106) (R107).

Here, the specific signal is, for example, 1.7V, but the embodiment is not limited thereto, and may be applied according to the characteristics of the system and the microcomputer 13.

At this time, discrete elements such as resistors, capacitors, and diodes are disposed in each of the terminals of the TR14 占 15 (Q14) (Q15) and the FET16 (Q16).

At this time, the emitter stages of the TR14 · 15 (Q14) and Q15 are inputted through the capacitor, the resistor, and the diode fed back from the load 11 below the output stage of the inverter 12 to the collector stage of the TR14 (Q14). The driving voltage input terminal VDDA drops through the resistor, the emitter terminal of TR14 (Q14) and the collector terminal of TR15 (Q15) are connected, and the driving voltage input terminal VDDA applied to the collector terminal of TR14 (Q14) is connected. It flows to TR15 (Q15), and the emitter of TR15 (Q15) is grounded to form a circuit.

In addition, the FET16 (Q16) is a MOS-FET, the gate terminal of which is connected between the collector terminal of the TR14 (Q14) and the driving voltage input terminal (VDDA), and the drain terminal of the resistor 106/107 (R106 connected in series with the 5V Ref input terminal). Is connected to the end of 107, and the source terminal is grounded to form a circuit.

On the other hand, the above-described overvoltage protection unit 15 of the present invention receives the signal of the load 11 side after the output terminal of the inverter 12, the LAMP LOW SIDE1 or LAMP due to the OPEN (opening) of the load 11 FETs 11 and 12 (Q11) and Q12 that are turned off when the LOW SIDE2 stage becomes LOW level; It is turned on by the TURN-OFF of the FETs 11 and 12 (Q11) and Q12, and specified according to the time constant of the resistors 106 and 108 (R106) and R108 while passing through the resistors 106 and 108 (R106) and R108. And a FET17 (Q17) that conducts and transfers the 5V Ref value, which is voltage-dropped as a signal, to the microcomputer 13.

Here, the specific signal is 3.3V as an embodiment, but the present invention is not limited thereto, and may be applied according to the characteristics of the system and the microcomputer 13.

At this time, discrete elements such as resistors, capacitors, and diodes are disposed in each of the terminals of FETs 11, 12 (Q11), Q12, and FET17 (Q17).

At this time, a signal fed back from the load 11 or less of the output terminal of the inverter 12 is input through the capacitor and the resistor, and the driving voltage is supplied to the drain terminal of the FET 11 (Q11). The input terminal VDDA drops through the resistor, the source terminal of FET11 (Q14) and the drain terminal of FET15 (Q15) are connected, the source terminal of FET12 (Q12) is grounded, and the gate terminal of FET17 (Q17) is VDDA. And the drain terminal of the FET11 (Q11), the drain is connected to one end of the resistor 108 (R108), the source terminal is grounded to form a circuit.

Referring to the operating state of the present invention configured as described above are as follows.

First, in the OCP (OVER CURRENT PROTECTION) state, the instantaneous load 11, that is, the lamp CCFL, the output falls to O LEVEL due to the SHORT, at this time, the load 11 side below the inverter 12, especially The VLFB signal (voltage signal), which is the voltage of the capacitor (generally designed on the output side of the inverter) connected to the output side of the inverter, is turned off.

Then, no operation signal is applied to the base end of TR14 · 15 (Q14) (Q15), and TR14 · 15 (Q14) (Q15) is turned off, whereby the voltage at the driving voltage input terminal VDDA is reduced by the resistance ( The voltage drops through R103), and the voltage is applied to the gate terminal of FET1 (Q16) so that FET1 (Q16) is turned on, so that the voltage input to the 5V Ref terminal is resistor 106 (R106) and resistor 108 (R108). The voltage drop, i.e., 1.7 V, is applied to the input side of the microcomputer 13 connected to the FAULT terminal through the time constant.

Then, the microcomputer 13 stops the output of the drive signal of the inverter 12 to stop the operation of the inverter 12 to protect the load 11 from overcurrent.

On the other hand, in the OVP (OVER VOLTAGE PROTECTION) state, the load 11, that is, the lamp CCFL is lowered by the LAMP LOW SIDE1 or LAMP LOW SIDE2 stage due to the OPEN.

Then, FET11 (Q11) and FET12 (Q12) are turned off, and accordingly, FET17 (Q17) is turned on, thereby driving voltage input terminal VDDA according to the time constant of resistor 106 (R106) and resistor 108 (R108). Voltage drop, i.e., falls to 3.3V, and is applied to the input side of the microcomputer 13 connected to the FAULT terminal.

Then, the microcomputer 13 stops the output of the drive signal of the inverter 12 to stop the operation of the inverter 12 to protect the load 11 from overvoltage.

 While the invention has been described and illustrated in connection with a preferred embodiment for illustrating the principles of the invention, the invention is not limited to the configuration and operation as such is shown and described.

Rather, it will be apparent to those skilled in the art that many changes and modifications to the present invention are possible without departing from the spirit and scope of the appended claims.

Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

According to the present invention, when an overcurrent or an overvoltage occurs on the load side, the overcurrent protection unit and the overvoltage protection unit input specific signals to the microcomputer to stop the operation of the inverter, thereby preventing the load from operating in an abnormal state and receiving an electric shock. The circuit safety and stability improvement effect are obtained.

Claims (8)

An inverter supplying a driving signal to a load to control an operation; A microcomputer supplying a driving signal for controlling the output signal and a driving voltage for operating the inverter, and stopping input of the driving signal to the inverter when a specific signal is input; An overcurrent protection unit configured to receive the signal on the load side in real time and to input a specific signal to stop the operation of the inverter when the overcurrent occurs on the load side; And an overvoltage protection unit configured to receive the signal on the load side in real time and to input a specific signal to stop the operation of the inverter when the overvoltage occurs on the load side. The inverter protection circuit according to claim 1, wherein the microcomputer is an IC chip that outputs a square wave whose duty is determined at a predetermined frequency to an output terminal by a preset internal program when an input voltage is changed to adjust a load state. . The method of claim 1, wherein the overcurrent protection unit receives a feedback signal from the load side after the output terminal of the inverter, and when the low level due to the instantaneous load short state TR14 · 15 and: FET16, which is turned on by the turn-off of TR14 · 15, conducts and transfers a 5V Ref value, which is voltage-dropped as a specific signal, to a microcomputer according to the time constant of resistor 106 · 107 while passing through resistor 106 · 107. Inverter protection circuit, characterized in that. 4. The inverter protection circuit according to claim 1 or 3, wherein the specific signal in the overcurrent protection unit is 1.7V. 4. The emitter terminal of the TR14 / 15 has a signal fed back from a load below the output terminal of the inverter through a capacitor, a resistor, and a diode, and a driving voltage input terminal (VDDA) passes through a resistor to the collector terminal of the TR14. Dropped, the emitter terminal of TR14 and the collector terminal of TR15 are connected so that the drive voltage input terminal VDDA applied to the collector terminal of TR14 flows to TR15, the emitter of TR15 is grounded, and FET16 is a MOS-FET. The gate terminal is connected between the collector terminal of the TR14 and the driving voltage input terminal (VDDA) input terminal, the drain terminal is connected to the end of the resistor 106, 107 connected in series with the 5V Ref input terminal, and the source terminal is grounded to form a circuit. Inverter protection circuit. The FET11 · 12 of claim 1, wherein the overvoltage protection part receives a feedback signal from a load side after an output terminal of the inverter, and is turned off when the LAMP LOW SIDE1 or LAMP LOW SIDE2 terminal becomes LOW due to the OPEN of the load. ; The FET17 is turned on by the TURN-OFF of the FETs 11 and 12, and conducts and transfers a 5V Ref value, which is voltage-dropped to a specific signal, to the microcomputer according to the time constant of the resistors 106 and 108 through the resistor 106 and 108. Inverter protection circuit, characterized in that. 7. The inverter protection circuit according to claim 1 or 6, wherein the specific signal in the overvoltage protection unit is 3.3V. 7. The gate terminal of the FET11, 12 has a signal fed back from the load below the output terminal of the inverter via a capacitor and a resistor, and a voltage drop across the driving voltage input terminal (VDDA) through the resistor at the drain of the FET11. The source terminal of FET11 is connected to the drain terminal of FET12, the source terminal of FET12 is grounded, the gate terminal of FET17 is connected between the driving voltage input terminal VDDA and the drain terminal of FET11, and the drain is connected to one end of the resistor 108. Inverter protection, the source terminal is grounded, the gate terminal of the FET17 is connected between the drain terminal of the FET11 (Q11) and the resistance of the drive voltage input terminal (VDDA), the source terminal is grounded to form a circuit Circuit.

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