KR20020030611A - Power apparatus for plasma display panel - Google Patents

Abstract

PURPOSE: A power supply for a PDP(Plasma Display Panel) is provided, which attenuates a peak voltage generated in a drain of a switching MOS transistor through a closed loop, and blocks an output voltage of a standby power supply part by sensing a rapid increase of a voltage of the switching MOS transistor. CONSTITUTION: An EMI(ElectroMagnetic interference) filter(101) removes an electromagnetic interference noise included in an input AC power, and a rectifier part(102) rectifies the filtered AC power. A standby power supply part(103) supplies a standby power of a microcomputer(104) by processing an output voltage of the rectifier part, and blocks an output of the standby power when an overvoltage detection signal is inputted from an overvoltage sensing part(114). The microcomputer controls a driving of a relay control part(105), which transfers an AC power from the EMI filter to a rectifier part(106). A power factor correction(PFC) part(107) outputs a DC voltage of a constant level without regard to a variation of the AC power. A snubber circuit(108) removes a peak voltage in a drain of a switching MOS transistor of a transformer driving part(112). A panel voltage output part(109) generates a panel voltage(PV) to drive a driver IC device and a controller IC device of a PDP module. A constant voltage sensing part(110) senses whether the panel voltage is constant or not, and a PWM control part(111) generates a pulse width modulation signal to drive a transformer(T2). A peak voltage attenuation part(113) attenuates a peak voltage in the drain when the MOS transistor is turned off. And a transformer(T4) and the overvoltage sensing part senses an overvoltage in the drain of the MOS transistor, and outputs its detection signal to the standby power supply part.

Description

POWER APPARATUS FOR PLASMA DISPLAY PANEL}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique for improving the efficiency of a power supply device applied to a plasma display panel (PDP) and protecting switching elements. The present invention relates to a PDP power supply device which is adapted to prevent heat generation and destruction of a switching element due to an abnormality of a diode.

1 is a block diagram of a PDP power supply device according to the prior art, as shown therein, an EMI filter 101 for removing electromagnetic interference noise included in an input AC power supply; A rectifier 102 for rectifying the filtered AC power; A standby power supply 103 for processing the output voltage of the rectifier 102 and supplying it to the standby power supply of the microcomputer 104; A microcomputer 104 for controlling the driving of the relay control unit 105 as the power switch is turned on and off; A relay controller 105 which is driven by the control of the microcomputer 104 and transmits the AC power branched from the EMI filter 101 to the rectifier 106; A rectifier 106 for rectifying the AC power input through the relay controller 105; A power factor correction unit (107) which always outputs a constant level of DC voltage regardless of a change in AC power inputted through the rectifier 106; A snubber circuit 108 for removing the peak value voltage appearing on the drain side of the switching MOS transistor of the transformer driver 112, which will be described later; A panel voltage output unit 109 for generating a panel voltage PV for driving the drive integrated device and the controller integrated device of the PDP module using the voltage input through the transformer T1; A constant voltage sensing unit (110) for sensing whether the panel voltage (PV) is output at a constant level and transmitting a detection signal accordingly to the microcomputer (104); A PWM controller 111 which receives the output voltage PV of the panel voltage output unit 109 and generates a pulse width modulated signal for driving the transformer T2; By using the voltage induced in the secondary coil (L22) of the transformer (T2), it is composed of a transformer driver 112 for driving the transformer (T1), the operation thereof will be described in detail with reference to FIG. As follows.

The input AC power is input to the EMI filter 101 to remove the electromagnetic interference (EMI) noise, rectified by the rectifier 102, and then supplied to the driving voltage of the standby power supply 103. The standby power supply 103 processes the input DC voltage to generate the 5V power required by the microcomputer 104. The reason for providing the standby power supply 103 separately is to minimize the power consumption in the standby state.

When the user turns on the power by using a remote controller or the like, the microcomputer 104 outputs a high potential control signal to the relay control section 105 to drive it. Accordingly, the AC power branched from the EMI filter 101 is rectified by the rectifier 106 through the relay controller 105 and then supplied to a power factor correction circuit (PFC) 107. The power factor correction circuit 107 always outputs a constant DC voltage regardless of the variation of the input AC power source AC.

The output voltage VA of the power factor correction circuit 107 is supplied to the primary coil L11 of the forward transformer T1, and the transformer T1 is driven by the transformer driver 112. The voltage induced in the secondary coil L12 of the transformer T1 is stored in the inductor L3 through the diode D4 and then passed through the diode D5 in the off period of the MOS transistor Q1 to be described later. (PV) is generated.

The panel voltage PV output from the panel voltage output unit 109 is supplied as a driving voltage for driving the drive integrated device and the controller integrated device of the PDP module on the one hand, and the PWM controller 111 is driven on the other hand. Supplied with voltage.

When the panel voltage PV is output through the path as described above, the constant voltage sensing unit 110 senses whether the panel voltage PV is output at a constant level (for example, 5 V) at a predetermined level and detects it accordingly. The signal is transmitted to the microcomputer 104.

The PWM controller 111 receives the panel voltage PV and outputs a driving pulse as shown in FIG. 2 to the primary coil L21 of the transformer T2, and to the secondary coil L22 of the transformer T2. The induced voltage is supplied to the gate side of the MOS transistor Q1 through the capacitor C3 and the resistor R2. As a result, the MOS transistor Q1 is switched by the waveform as shown in FIG. 2, and the transformer T1 is driven in synchronization with the same.

However, since the panel voltage output method as described above is a secondary side circuit control method, the peak value of the liquid crystal inductor of the primary coil L11 of the transformer T1 at the drain at the off point during one cycle of the MOS transistor Q1. There is a risk of component breakage due to voltage. The snubber circuit 108 is provided to prevent this.

As described above, in the conventional PDPP power supply device, a snubber circuit is used to prevent a component from being damaged or noise caused by a peak value voltage caused by the liquid crystal inductor on the drain of the switching MOS transistor.

Nevertheless, there is a defect that some degree of noise and slight heat of resistor R1 are present and the peak voltage is not completely removed. In addition, when an abnormality occurs in the diode provided on the secondary coil side of the forward transformer, there is a risk that the switching MOS transistor may be destroyed by the overvoltage, thereby degrading the reliability of the PDP module.

Accordingly, an object of the present invention is to attenuate the peak voltage generated in the drain of the switching MOS transistor through a closed loop, and abnormality occurs in the diode provided on the secondary coil side of the forward transformer, so that the voltage of the switching MOS transistor suddenly increases. The present invention provides a PDP power supply device that detects an increase and blocks an output voltage of a standby power supply unit.

1 is a block diagram of a power supply for PDPD according to the prior art

2 is an output waveform diagram of a PWM control unit in FIG. 1.

Figure 3 is an embodiment block diagram of a PDP power supply apparatus according to the present invention.

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

101: EMI filter 102, 106: rectifier

103: standby power supply unit 104: microcomputer

105: relay control unit 107: power factor correction circuit

108: snubber circuit 109: panel voltage output unit

110: constant voltage sensing unit 111: PWM control unit

112: transformer driving unit 113: peak voltage attenuation unit

114: overvoltage sensing unit

3 is an exemplary block diagram of a PDP power supply apparatus according to the present invention, and as illustrated therein, an EMI filter 101 for removing electromagnetic interference noise included in an input AC power supply; A rectifier 102 for rectifying the filtered AC power; The standby power supply unit processes the output voltage of the rectifying unit 102 and supplies it to the standby power supply of the microcomputer 104, and blocks the output of the standby power supply when an overvoltage detection signal is input from the overvoltage sensing unit 114 to be described later. 103); A microcomputer 104 for controlling the driving of the relay control unit 105 as the power switch is turned on and off; A relay controller 105 which is driven by the control of the microcomputer 104 and transmits the AC power branched from the EMI filter 101 to the rectifier 106; A rectifier 106 for rectifying the AC power input through the relay controller 105; A power factor correction unit (107) which always outputs a constant level of DC voltage regardless of a change in AC power inputted through the rectifier 106; A snubber circuit 108 for removing the peak value voltage appearing on the drain side of the switching MOS transistor of the transformer driver 112, which will be described later; The panel voltage PV for driving the drive integrated device and the controller integrated device of the PDP module is generated using the output voltage of the transformer T1 driven by using the output voltage PV of the power factor compensator 107 as an input voltage. A panel voltage output unit 109; A constant voltage sensing unit (110) for sensing whether the panel voltage (PV) is output at a constant level and transmitting a detection signal accordingly to the microcomputer (104); A PWM controller 111 which receives the output voltage PV of the panel voltage output unit 109 and generates a pulse width modulated signal for driving the transformer T2; A transformer driver 112 for driving the transformer T1 by using a voltage induced in the secondary coil L22 of the transformer T2; A peak voltage attenuator 113 configured to form a closed loop with the tertiary coil L13 and the reverse diode D6 of the transformer T1 to attenuate the peak voltage generated at the drain side thereof when the MOS transistor is turned off. )Wow; It is composed of a transformer (T4) and an overvoltage sensing unit 114 for detecting an overvoltage generated on the drain side of the MOS transistor and outputting a detection signal according to the standby power supply 103. When described in detail as follows.

The input alternating current AC is removed from the electromagnetic interference noise through the EMI filter 101, rectified to a DC voltage through the rectifying unit 102, and supplied to the driving voltage of the standby power supply unit 103. The standby power supply 103 processes the input DC voltage to generate the 5V power required by the microcomputer 104.

When the power switch is turned on, the relay controller 105 is driven by the control of the microcomputer 104. Accordingly, AC power branched from the EMI filter 101 is rectified by the rectifier 106 through the relay controller 105 and then supplied to the power factor correction circuit 107, and the power factor correction circuit 107 is provided. It plays a role of always outputting a certain level of DC voltage regardless of variation of input AC power source AC.

The output voltage VA of the power factor correction circuit 107 is supplied to the primary coil L11 of the forward transformer T1, and the transformer T1 is driven by the transformer driver 112. The voltage induced in the secondary coil L12 of the transformer T1 is stored in the inductor L3 through the diode D4 and then passed through the diode D5 in the off period of the MOS transistor Q1 to be described later. (PV) is generated.

The panel voltage PV output from the panel voltage output unit 109 is supplied as a driving voltage for driving the drive integrated device and the controller integrated device of the PDP module on the one hand, and the PWM controller 111 is driven on the other hand. Supplied with voltage.

When the panel voltage PV is output through the path as described above, the constant voltage sensing unit 110 senses whether the panel voltage PV is output at a constant level (for example, 5 V) at a predetermined level and detects it accordingly. The signal is transmitted to the microcomputer 104.

On the other hand, the PWM control unit 111 receives the panel voltage PV and outputs the driving pulse as shown in FIG. 2 to the primary coil L21 of the transformer T2, and the secondary coil L22 of the transformer T2. ) Is supplied to the gate side of the MOS transistor Q1 through the capacitor C3 and the resistor R2. As a result, the MOS transistor Q1 is switched by the waveform as shown in FIG. 2, and the transformer T1 is driven in synchronization with the same.

However, since the panel voltage output method as described above is a secondary circuit control method, the peak value of the liquid crystal inductor of the primary coil L21 of the transformer T2 at the drain at the off point during one period of the MOS transistor Q1. There is a risk of component breakage due to voltage. The snubber circuit 110 is installed to prevent this.

Nevertheless, the peak voltage is not completely removed and noise is generated to some extent, and the resistor R1 generates heat. In addition, when an abnormality occurs in the diodes D4 and D5 provided on the secondary coil L12 side of the forward transformer T1, there is a risk that the switching MOS transistor Q1 may be destroyed. Referring to the operation of the attenuator 113 and the overvoltage sensing unit 114 as follows.

A third coil L13 is additionally installed on the transformer T1, and the output voltage VA terminal of the power factor correction circuit 107 is connected to the transformer through the third coil L13 and a reverse diode D6. It connected to the other side of the secondary coil L22 of (T2).

Therefore, the peak voltage generated at the drain side thereof at the time when the switching MOS transistor Q1 is turned off is induced to the closed loop side made up of the tertiary coil L13 and the reverse diode D6 of the transformer T1, thereby completely. Attenuation is thereby caused, and the amount of heat generated by the resistor R1 in the surge circuit 108 is significantly reduced.

In addition, when an abnormality occurs in the diodes D4 and D5 of the panel voltage output unit 109, the drain-side voltage of the switching MOS transistor Q1 is rapidly increased to prevent the transistor Q1 from being destroyed and the PDP. In order to protect the module, a transformer T4 and an overvoltage sensing unit 114 were provided.

That is, when an abnormality occurs in the diodes D4 and D5 and an overvoltage is generated on the drain side of the MOS transistor Q1, the overvoltage is transmitted through the primary coil L41 of the transformer T4. The overvoltage sensing unit 114 is driven by the induced voltage. In this case, the overvoltage sensing unit 114 transmits an overvoltage sensing signal to the standby power supply 103.

Accordingly, the standby power supply 103 cuts off the standby power supply 5V supplied to the microcomputer 104. As a result, the driving of the microcomputer 104 and the system is stopped, and thus the drive integrated device and the controller integrated device of the PDP module, including the switching MOS transistor Q1, can be prevented from being damaged by overvoltage.

As described in detail above, the present invention attenuates the peak voltage generated in the drain of the switching MOS transistor through the closed loop, and causes an abnormality in the diode installed on the secondary coil side of the forward transformer, thereby causing the voltage of the switching MOS transistor. By detecting the sudden rise and blocking the output voltage of the standby power supply unit, the drive transistor and the controller integrated device of the PDP module, including the MOS transistor, can be prevented from being damaged by overvoltage.

Claims (3)

A standby power supply which processes the input AC power supply and supplies a standby power required by the microcomputer, and cuts the output of the standby power supply when an overvoltage detection signal is input from an overvoltage sensing unit to be described later; A panel voltage output unit configured to generate a panel voltage using an output voltage of a first transformer driven by using the power factor corrected voltage as an input voltage; A transformer driver for driving the first transformer by using a MOS transistor for switching driven by a square wave pulse transmitted through a PWM controller and a second transformer; A peak voltage attenuator for attenuating the peak value voltage generated at the drain side thereof by using a closed loop when the MOS transistor is turned off; And an overvoltage sensing means for detecting that an overvoltage is generated on the drain side of the MOS transistor and outputting a detection signal according to the standby power supply unit. The apparatus of claim 1, wherein the peak voltage attenuating unit comprises a third coil additionally installed in the first transformer and a reverse diode connected in series with the third coil. The overvoltage sensing means of claim 1, further comprising: a fourth transformer having a primary coil connected in series with the primary coil of the first transformer; And an overvoltage sensing unit configured to sense an input voltage through the fourth transformer and output an overvoltage detection signal to the standby power supply unit when it is determined that the overvoltage is detected as an overvoltage.