KR20070074088A - A discharge circuit of power supply unit for pdp - Google Patents

Abstract

A discharge circuit of a power supply unit for a PDP is provided to forcibly discharge the power supply unit in case of forcible termination or erroneous operation by performing the discharge process using a driving voltage rather than a standby voltage. A discharge circuit of a power supply unit for a PDP includes a sustain voltage driver(11), an address voltage driver(12), a microcomputer(10), and a discharge circuit(20). The sustain voltage driver supplies power to a sustain electrode. The address voltage driver supplies power to an address electrode. The microcomputer detects a power state of the sustain voltage driver and the address voltage driver, and outputs a corresponding control signal according to the detected power state. The discharge circuit receives the control signal from the microcomputer and discharges a sustain voltage supply unit and an address voltage supply unit.

Description

Discharge Circuit of PD Power Supply Unit {A DISCHARGE CIRCUIT OF POWER SUPPLY UNIT FOR PDP}

1 is a discharge circuit diagram of a conventional PDP power supply device

Figure 2 is a block diagram of the discharge circuit of the present invention PDPC power supply

Figure 3 is a detailed circuit diagram of the discharge circuit of the present invention PDPC power supply

* Explanation of symbols for the main parts of the drawings *

10; Micom 20; Discharge circuit

21; A driving voltage output unit 22; Discharge drive

TR2; Transistor FET2; Field Effect Transistor

R11-R18; Resistance D11; diode

ZD1; Constant voltage diodes OPTO-COUPLER; Optocoupler

The present invention relates to a discharge circuit of a power supply for a plasma display panel.

In general, PD (hereinafter, referred to as "PDP") has a high luminance characteristic due to its structural characteristics, and requires a high voltage during driving, so that driving power control is an important factor for reliability of PDP operation.

Therefore, when looking at the power supply terminal supplied to the PDP, the upper plate and the lower plate is configured to be bonded to each other, the upper plate is configured with a scan electrode and a sustain electrode formed in parallel with each other, the lower plate is composed of an address electrode.

The electrodes are discharge gas provided between the upper plate and the lower plate with a predetermined voltage applied from a power supply device, that is, a sustain power supply unit supplying power to the sustain electrode and an address power supply unit supplying power to the address electrode. The color of the phosphor is excited by the ultraviolet rays generated by discharging the color.

As such, the PDP driven by a predetermined voltage applied to the electrodes has a direct relation with a panel (screen realization) in which the output of the power supply is an available part. For example, when the power supply malfunctions or is forcibly shut down. It is necessary to discharge the electric charges charged in the capacitor of the sustain power supply unit and the address power supply unit to forcibly reduce the reliability.

Thus, as shown in FIG. 1, the power supply device includes a discharge circuit for discharging the voltages of the sustain power supply VS and the address power supply VA, wherein the discharge circuit is a microcomputer (not shown). The drive signal is received from the transistor (R1) through R2 and capacitor (C1) and connected to the base terminal of transistor (Q1), and the collector terminal of transistor (Q1) through diode (D1) resistor (R3). In addition to the standby power is applied, the standby power is connected to the gate terminal of the field effect transistor FET1 through the resistors R4 and R5.

In addition, between the source terminal and the drain terminal of the field effect transistor (FET1) and the capacitor (C) for charging the voltage of the sustain power supply (VS) through the resistor (R6) (R7), diode (D2), resistor (R8) and The capacitor C for charging the address power supply VA (not shown) is connected.

In the conventional discharge circuit configured as described above, an on-off signal is applied from the microcomputer (not shown) to the transistor Q1 of the discharge circuit in a state where power is normally applied, so that the field effect transistor FET1 is turned off to sustain power. The capacitor VS of the supply unit VS and the address power supply unit VA are respectively charged.

However, when the power supply malfunctions or is forcibly terminated, the standby power applied to the gate terminal of the field effect transistor FET1 of the discharge circuit is first shut off, so that the field effect transistor FET1 cannot be driven. Since the FET1 is not driven, the charges charged in the capacitor C of the sustain power supply VS and the address power supply VA cannot be forcibly discharged, and thus remain charged.

Therefore, the charging voltage of the capacitor C causes a malfunction of the power supply device due to overcharging when the power is normally applied again, thereby lowering the reliability.

Accordingly, an object of the present invention is to allow the discharge circuit to operate even in the event of a power malfunction or forced termination of the PDP power supply.

Another object of the present invention is to provide reliability to a power supply for a PDP.

The present invention provides a sustain power supply unit for supplying power to the sustain electrode to achieve the above object; An address power driver for supplying power to the address electrode; A microcomputer for detecting a power state from the sustain power driver and the address power driver and outputting a control signal corresponding to the detected power state; And a discharge circuit for discharging the sustain power supply unit and the address power supply unit while driving the control signal from the microcomputer.

The discharge circuit includes a driving voltage output unit for outputting a driving voltage from the microcomputer; And a discharge driver for discharging the capacitors of the sustain power supply unit and the address power supply unit while being driven on / off by the driving voltage from the drive voltage output unit.

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

2 is a discharge circuit block diagram of the power supply device for the present invention PD, Figure 3 is a detailed circuit diagram of the discharge circuit of the power supply device for the present invention, the present invention is a sustain power driver 11, an address power driver 12 ), The microcomputer 10, and the discharge circuit 20.

The sustain power driver 11 supplies power to the sustain electrode.

The address power driver 12 supplies power to the address electrode.

The microcomputer 10 detects a power state from the sustain power driver 11 and the address power driver 12 and outputs a control signal corresponding thereto according to the detected power state.

The discharge circuit 20 receives a control signal from the microcomputer 10 and operates a transistor TR2, a resistor R10, a resistor R11, a diode D11, and an optocoupler OPTO− which supplies a driving voltage. A driving voltage output unit 21 composed of a COUPLER; A diode for discharging the capacitor C of the sustain power supply 110 and the address power supply 120 while driving on / off by receiving a driving voltage supplied from the OPTO-COUPLER of the driving voltage output unit 21. And a discharge driver 22 composed of a D12, a resistor R12-R15, a constant voltage diode ZD1, a field effect transistor FET2, and a discharge resistor R16-R18.

According to the present invention configured as described above, when the power supply is normal, the sustain power supply unit 11 and the address power supply unit 12 are in a normal power state, and thus, in the microcomputer 10, the driving voltage output unit 21, which is a discharge circuit 20. The driving signal is applied to the base terminal of the transistor TR2 to turn on the transistor TR2.

Therefore, the driving power supply VDD flows through the resistor R11, the optocoupler OPTO-COUPLER, the diode D11, the collector terminal and the emitter terminal of the transistor TR2, and the opto-coupler OPTO-COUPLER The operation of the opto-coupler (OPTO-COUPLER) causes the microcomputer 10 to recognize that the power supply is in a normal state, while the collector terminal of the transistor TR2 creates a low potential, that is, a ground state. .

Accordingly, the cathode of the diode 12 of the discharge driver 22 connected to the collector terminal of the transistor TR2 is also grounded to turn off the diode D12, so that the field effect transistor FET2 is turned on. Since it is impossible to drive, the capacitor C of the sustain power supply 11 and the address power supply 12 cannot be discharged.

On the other hand, when the power malfunction or forced termination, the microcomputer 10 detects a power abnormal state from the sustain power driver 10 and the address power driver 11 to generate a control signal according to the power abnormal state, that is, a low signal. Output to the driving voltage output unit 21 of (20).

Accordingly, the transistor TR2 is turned off by the low signal at the base terminal of the transistor TR2 of the driving voltage output unit 21, and the driving voltage VDD is applied to the collector terminal of the transistor TR2. Since the driving voltage VDD is applied to the cathode terminal of the diode D12 of the discharge driver 22, the potential difference from the sustain voltage VS and the constant voltage diode ZD1 are applied to the gate terminal of the field effect transistor FET2. Is applied to drive the field effect transistor FET2 on.

Therefore, the voltage charged in the capacitor C of the sustain power supply 11 and the address power supply 12 is discharged through discharge resistors R16-R18 and the field effect transistor FET2.

As described above, the present invention does not drive the discharge operation of the discharge circuit provided in the PDP power supply device to the standby power source, but the discharge operation is performed at the driving voltage so that the standby power source is first shut off during the power malfunction or forced termination. Forced discharge operation is performed by the driving power supply, thereby providing an effect of securing reliability of the discharge circuit.

Claims (4)

A sustain power supply unit supplying power to the sustain electrode; An address power driver for supplying power to the address electrode; A microcomputer for detecting a power state from the sustain power driver and the address power driver and outputting a control signal corresponding to the detected power state; And a discharge circuit for discharging the sustain power supply unit and the address power supply unit while driving the control signal from the microcomputer. The driving circuit of claim 1, wherein the discharge circuit comprises: a driving voltage output unit configured to output a driving voltage from a microcomputer; And a discharge driver for discharging the capacitors of the sustain power supply unit and the address power supply unit while driving on / off by receiving the drive voltage from the drive voltage output unit. 3. The discharge circuit of claim 2, wherein the driving voltage output unit includes a transistor, a resistor, a diode, and an opto-coupler for supplying a driving voltage. 3. The discharge circuit according to claim 2, wherein the discharge driver comprises a diode, a resistor, a constant voltage diode, a field effect transistor, and a discharge resistor.

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