KR19990003558U - Duty Control Circuit for PWM Control Signals in Monitors - Google Patents

Abstract

The present invention relates to a circuit for adjusting the duty of the PWM control signal during low temperature operation of the monitor.

In this circuit of the present invention, the PWM controller 1 outputs a PWM control signal according to a horizontal driving signal to adjust the B + voltage, and the B + voltage is supplied to the flyback transformer and connected to the other side of the flyback transformer. In the monitor supplied to the horizontal deflection circuit, the base terminal is connected to the input terminal of the PWM control unit 1, the first transistor (Q21) is turned on / off according to the horizontal drive signal, the base terminal through the resistor (R22) A second transistor Q22 connected to an emitter terminal of the first transistor Q21 and turned on when the first transistor Q21 is turned on, and a second transistor Q22 connected to a collector terminal of the second transistor Q22 Is turned on when the capacitor C21 is charged, and is discharged when the capacitor C21 is charged, and is turned on when the capacitor C21 is charged, and the collector terminal is connected to the output terminal of the PWM controller 1. The third transistor Q23 is connected, and the horizontal deflection portion can be stabilized by adjusting the duty of the PWM control signal during low temperature operation.

Description

Duty Control Circuit for PWM Control Signals in Monitors

The present invention relates to a PWM control signal for adjusting the B + voltage of the monitor, and more particularly to a duty control circuit of the PWM control signal in the monitor that can stabilize the horizontal deflection by adjusting the duty of the PWM control signal during low temperature operation will be.

In particular, the DC voltage input from the SMPS is switched in the chopper circuit to supply the B + voltage to the flyback transformer (FBT). At this time, the chopper is required to switch the switching element and the PWM control circuit for switching the DC voltage, for example, a dedicated power control chip such as 3842 is used here.

FIG. 1 is a circuit diagram illustrating a part of generating a B + voltage using 3842. Referring to FIG. 1, the switching transistor Q3 applies a DC power supply voltage (usually 200V) from the switching power supply 3 through a drain terminal. The DC power supply voltage B + is supplied to the flyback transformer 5 through the source terminal. The voltage B + applied to the primary side of the flyback transformer 5 by the operation of the switching transistor Q3 is also applied to the horizontal deflection circuit 6 to generate a sawtooth current.

At this time, the switching on / off of the switching transistor Q3 is controlled by a PWM (Pulse Width Modulation) control signal output from the PWM controller 1.

That is, when the switching transistor Q3 maintains the off state for a predetermined time according to the PWM control signal and then transitions to the on state, the power supply current supplied through the drain terminal flows to the flyback transformer 5 through the source terminal.

On the other hand, the horizontal drive signal output from the horizontal deflection circuit 6 is applied to the horizontal drive transistor or the horizontal output transistor of the horizontal deflection circuit 6, and fed back to the PWM control unit 1 and input.

When the feedback voltage is greater than the internal reference voltage, the PWM controller 1 supplies a PWM control signal having a short on time to the gate terminal of the switching transistor Q3 to shortly adjust the on time of the switching transistor Q3. The magnitudes of the input and output voltages of the flyback transformer 5 are varied. On the contrary, when the feedback voltage is smaller than the reference voltage, the PWM control signal having a long on time is supplied to the gate terminal of the switching transistor Q3 to adjust the on time of the switching transistor Q3 long.

That is, the PWM control unit 1 receives the feedback of the horizontal driving signal and compares it with the internal reference voltage, thereby adjusting the duty cycle of the PWM control signal.

In addition, the driving unit 2 is for sufficiently driving the switching transistor Q3, and supplies sufficient base current to the switching transistor Q3 according to the on / off state of the PWM control signal output from the PWM control unit 1 or Block it.

Looking at the operation of the switching transistor Q3 in detail, when the PWM control signal output from the PWM control unit 1 is on time, the second driving transistor Q2 of the driving unit 2 is turned on so that the switching power supply 3 The power supply voltage supplied from the N-B is applied to the collector terminal of the second driving transistor Q2 through the Zener diode ZD (generally, the Zener voltage is 12V) through the capacitor C1 and bypassed to the ground through the emitter terminal. As a result, a positive voltage is applied to one end of the capacitor C1 connected to the base end of the switching transistor Q3, and the switching transistor Q3 is switched on.

On the contrary, since the first driving transistor Q1 is turned on when the PWM control signal is off time, the power supply voltage Vcc is applied to the emitter terminal of the first driving transistor Q1 so that the capacitor C1 is connected through the collector terminal. Is emitted into the snubber circuit 4 via the < RTI ID = 0.0 > Accordingly, a negative voltage is applied to one end of the capacitor C1 connected to the gate terminal of the switching transistor Q3 to switch off the switching transistor Q3.

At this time, the snubber circuit 4 has a source-drain voltage of the switching transistor Q3. ) Is to prevent a sudden rise of the source-drain voltage of the switching transistor Q3. ) Into the stable operating area.

Referring to the operation of the snubber circuit 4, at the moment when the switching transistor Q3 is turned off, current flows through the capacitor C2 and the diode D2 so that the source-drain voltage of the switching transistor Q3 ( ) Make the rise fall. That is, the diode D2 shorts the resistor R5 when the switching transistor Q3 is turned off and raises the voltage absorbing effect of the capacitor C2. In addition, the resistor R5 rapidly discharges the charge of the capacitor C2 at the time the switching transistor Q3 is turned on, and prevents the source current of the switching transistor Q3 from rising excessively.

In addition, the Zener diode ZD fixes the voltage difference between the gate terminal and the drain terminal of the switching transistor Q3 to the Zener voltage 12V to operate the switching transistor Q3.

By the way, the PWM control unit that adjusts the magnitude of the voltage B + according to the PWM control signal outputs a PWM control signal having a 100% duty when operating in a low temperature state lower than room temperature. Accordingly, since the switching transistor is shorted, there is a problem that the horizontal deflection circuit that generates the sawtooth current by the B + voltage does not operate.

The present invention has been made to solve the above problems, the duty of the PWM control signal in the monitor for adjusting the duty of the PWM control signal input to the switching transistor to stabilize the horizontal deflection when operating in a low temperature state The purpose is to provide an adjustment circuit.

The circuit of the present invention for achieving the above object, the PWM control unit outputs a PWM control signal according to the horizontal drive signal to adjust the B + voltage, the B + voltage is supplied to the flyback transformer and at the same time of the flyback transformer In the monitor supplied to the horizontal deflection circuit connected to the other side, the base terminal is connected to the input terminal of the PWM control unit on / off according to the horizontal drive signal, the collector terminal is connected to the power supply voltage, the emitter terminal is connected to the resistor A first transistor, a second terminal connected to an emitter terminal of the first transistor through a resistor, a collector terminal connected to a power supply voltage through a resistor, and an emitter terminal connected to a ground, and a second transistor turned on when the first transistor is turned on; Connected to the collector terminal of two transistors, when the second transistor is turned on, And a third transistor for discharging, and a base terminal connected to a diode and a resistor, a collector terminal connected to an output terminal of a PWM control unit, and an emitter terminal grounded so that the capacitor is turned off when charged and turned on when discharged. It is characterized by.

1 is a circuit diagram showing a portion generating a B + voltage in a conventional monitor,

2 is a circuit diagram showing a duty adjustment circuit of the PWM control signal in the monitor according to the present invention,

FIG. 3 is an operation waveform diagram of each part shown in FIG. 2.

＊ Explanation of symbols for main parts of drawing

1: PWM control unit Q1, Q2, Q3: transistor

C21: Capacitor D21, D22: Diode

R21, R22, R23, R24: resistance

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

2 is a circuit diagram showing a duty adjustment circuit of the PWM control signal in the monitor according to the present invention.

As shown in FIG. 2, the circuit of the present invention includes a PWM control unit 1 and a base terminal connected to an input terminal of the PWM control unit 1, a collector terminal connected to a power supply voltage (eg, 5 V), and an emitter terminal. The first transistor Q21 connected to the resistors R21 and R22 and the base terminal are connected to the emitter terminal of the first transistor Q21 through the resistor R22, and the collector terminal is connected to the 5V power supply through the resistor R23. A second transistor Q22 having an emitter terminal grounded, a capacitor C21 connected to the collector terminal of the second transistor Q22, and a base terminal connected to the diodes D21 and D22 and a resistor R24, It is composed of a third transistor Q23 connected to the output terminal of the PWM control unit 1 and having an emitter terminal grounded.

Next, an operation according to the circuit of the present invention configured as described above will be described with reference to the waveform diagram of FIG. 3.

The PWM controller 1 receives a horizontal drive signal output from a horizontal deflection circuit (shown in FIG. 1, 6) and outputs a PWM control signal. At this time, the horizontal driving signal is simultaneously applied to the base terminal of the first transistor Q21.

The waveform of the horizontal driving signal is shown in FIG. 3A. When the horizontal driving signal is 'high', the first transistor Q21 is turned on and the 5V power source is turned on. As it flows through the emitter stage of, the emitter voltage is applied to the base terminal of the second transistor so that the second transistor Q22 is turned on.

At this time, the 5V power supply voltage is charged to the capacitor C21 through the resistor R23. As a result, the capacitor voltage is increased to increase the voltage at the point A as shown in FIG. The increasing slope depends on the integral time constants of the resistor R23 and the capacitor C21. If the resistance value is large, charging is performed quickly, so that the predetermined voltage (2.1V in this case) is reached quickly, and the resistance value is small. The charge is delayed to reach a predetermined voltage late.

Since the voltage is not applied to the base terminal of the third transistor Q23 while the capacitor C21 is charged and reaches 2.1V, the voltage at the point B becomes 'high' as shown in FIG. '

When comparing the waveforms according to the large and small values of the resistance (R23) with reference to Figure 3, if the resistance value is large to reach 2.1V quickly, the width of the B voltage is 'high' wide and conversely if the resistance value is small late It reaches 2.1V, narrowing the width at which the C voltage becomes 'high'.

When the horizontal driving signal is 'low', the first transistor Q21 is turned off, and accordingly, the second transistor Q22 is turned off, and the capacitor C21 is discharged through the diodes D21 and D22 and the resistor R24. Done. Therefore, since the third transistor Q23 is turned on and grounded through the emitter terminal, the B voltage becomes 'low'.

That is, in the low temperature operation, the duty of the pulse is not 100% by turning on the third transistor Q23 and turning it down to 'low'.

As described above, the circuit of the present invention has the effect of stabilizing the horizontal deflection by adjusting the duty of the PWM control signal so that the duty is not 100% during low temperature operation.

Claims (1)

The PWM controller 1 outputs a PWM control signal according to a horizontal driving signal to adjust the B + voltage, and the B + voltage is supplied to a flyback transformer and simultaneously supplied to a horizontal deflection circuit connected to the other side of the flyback transformer. To A first transistor Q21 connected to an input terminal of the PWM controller 1 on / off according to a horizontal driving signal, a collector terminal connected to a power supply voltage, and an emitter terminal connected to resistors R21 and R22; The base terminal is connected to the emitter terminal of the first transistor Q21 through the resistor R22, the collector terminal is connected to the power supply voltage through the resistor R23, and the emitter terminal is grounded so that the first transistor Q21 is turned on. A second transistor Q22 that is turned on when the transistor is turned on; A capacitor C21 connected to the collector terminal of the second transistor Q22 to charge when the second transistor Q22 is turned on and discharge when turned off; And The base terminal is connected to the diodes D21 and D22 and the resistor R24, the collector terminal is connected to the output terminal of the PWM control unit 1, and the emitter terminal is grounded. When the capacitor C21 is charged, it is turned off and discharged. A duty adjustment circuit for the PWM control signal in a monitor consisting of a third transistor (Q23) being turned on.