KR20000004300A - Micom stabilization circuit for a monitor - Google Patents

Abstract

PURPOSE: A micom stabilization circuit for a monitor is provided to supply a stable driving voltage to a micom by supplying the micom with an auxiliary power supply voltage when a power supply voltage inputted to the micom is lower than a regular voltage. CONSTITUTION: The micom stabilization circuit for a monitor comprises: a switching portion(10) switched on when a switching control signal is inputted, for supplying a regulator(7) with a sub power supply voltage(Vo) higher than the main power supply voltage(Von); and a switching controller(20) for outputting the switching control signal to the switching portion(10) when the inputted main power supply voltage(Von) is below a constant voltage, wherein the switching controller(20) lowers the sub power supply voltage(Vo) inputted to the regulator(7) when the switching portion(10) is switched on.

Description

A circuit for protecting a micro-computer of a monitor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply system of a monitor, and more particularly, to a driving voltage supplied to a microcomputer 8 from a switching power supply circuit. V _on ) Is smaller than the rating, the auxiliary drive voltage ( V _o It is related to the microcomputer stabilization circuit of the monitor to supply.

In general, a monitor is a device that receives information from a computer video card and a synchronization signal and displays information on a CRT screen. The monitor includes a video system for processing a video signal, a deflection system for vertical and horizontal deflection, and a power supply. It consists of a system.

Here, the power supply system of the monitor plays a role of properly supplying the voltage required in each part of the monitor, and the related technology is SMPS (smaller, lighter and more efficient than the linear power supply). Switching mode power supply (Switched Mode Power Supply) is developing rapidly.

1 shows a conventional switching power supply (SMPS), which includes a DC power supply 1, a transformer 2, a power transistor 3, a control IC 4, and an output 5. And the overvoltage detector 6.

Referring to the operation of the switching power supply (SMPS) configured as described above, if the commercial AC power of 100V or 220V is first applied through the fuse, the line filter (L1, L2) and capacitors (C1, C2, C3) is L · C The resonance action removes the noise flowing through the AC power, and at the same time, the high frequency noise generated while the bridge diode D1 and the control IC 4 are operated is blocked from going out through the AC input line.

Meanwhile, the AC voltage passing through the line filters L1 and L2 and the capacitors C1, C2 and C3 is rectified by the bridge diode D1 and smoothed in the smoothing capacitor C4 through the inrush current preventing resistor Rs. DC voltage ( V _i And then to the primary winding of the transformer (2).

At the same time, the rectified voltage rectified by the bridge diode D1 is applied to the control IC 4. V _cc Resistance at R _g ) Is applied to operate the control IC 4, and the power transistor 3 is turned on / off by a control signal output from the control IC 4.

That is, the DC voltage ( V _i Is applied, the DC voltage ( V _i Power supply of control IC 4 as V _cc ) Reaches the starting voltage, the control IC 4 is operated to generate a PWM control signal, and the power transistor 3 is turned on / off by this PWM control signal.

When the power transistor 3 remains in the on state for a predetermined time according to the oscillator cycle in the control IC 4 and changes to the off state, induced electromotive force is induced from the primary winding of the transformer 2 to the secondary winding. Done.

Therefore, the transformer 2 is the AC voltage required by the secondary winding by the PWM control signal ( V _s, V _sm, V _sn ) Will be printed.

By repeating this operation, the AC voltage output from the secondary winding of the transformer 2 ( V _s, V _sm, V _sn ) Again through the output (5) DC voltage ( V _o, V _om, V _on Is converted to).

That is, the AC voltage input to the output unit 5 ( V _s, V _sm, V _sn ) Is the direct current voltage (V) by rectifying diodes (D2, D3, D4) and smoothing capacitors (C6, C7, C8). V _o, V _om, V _on ) Is supplied to each circuit of the monitor to operate the circuit.

However, the above DC voltage ( V _o, V _om, V _on ) Rises above the reference voltage, resulting in damage to the circuit elements due to overvoltage, which can shorten the life of the power supply device. Therefore, in order to maintain the output voltage of the output unit 5 at a constant voltage, the switching power supply circuit In general, the overvoltage detector 6 is provided.

In more detail, the power supply voltage to each circuit of the monitor ( V _o ) Is sensed by the voltage detector 6 comprising the error amplifier EA and the photo couplers PC1 and PC2, and the detection signal is input to the feedback stage of the control IC 4.

That is, the power supply voltage (outputted from the transformer 2) V _o Is larger than during normal operation, the error amplifier EA senses the overvoltage and lowers the voltage at the output side of the error amplifier EA. At this time, the output side of the error amplifier EA is connected to the light emitting unit PC1 of the photo coupler, and the other end of the light emitting unit PC1 is the SMPS output terminal ( V _om ), More current flows momentarily through the light emitting unit PC1 than during normal operation, thereby emitting as much light.

Accordingly, the light receiving unit PC2 of the photocoupler receives the light, converts the optical signal into an electrical signal, and outputs the light signal to the feedback terminal of the control IC 4. The input current rapidly increases, and the control IC 4 generates a PWM control signal, which shortens the on time of the power transistor 3.

As the on time of the power transistor 3 is shortened, induced electromotive force induced from the primary winding of the transformer 2 to the secondary winding ( V _s, V _sm, V _sn ) Is lowered, the power supply voltage (outputted from the SMPS) V _o, V _om, V _on ) Is maintained at a constant voltage and supplied to each circuit of the monitor.

The switching power supply circuit SMPS as described above typically uses the regulator RE2 to always supply the correct 5V power supply voltage to the MICOM.

That is, the power supply voltage (outputted from the rectifying means D4, C8) V _on : Normally, 18V) is maintained at 12V through the first regulator RE1 and supplied to the deflection circuit, while a power supply voltage of 12V output through the first regulator RE1 is reduced to 5V through the second regulator RE2. Maintain and feed it to the microcomputer.

At this time, the first regulator (RE1) is designed to maintain the output voltage is always 12V even if the input voltage is unstable (usually 15V-21V), and always supply the correct 12V power supply voltage to the deflection circuit, the second regulator (RE2) Even though the input voltage is unstable (typically 8V-15V), the output voltage is designed to maintain 5V all the time, so it always supplies the correct 5V supply voltage to the microcomputer.

However, the conventional switching power supply circuit configured as described above rises to a normal state as shown in (a) of FIG. 3 when a large amount of current is consumed in the deflection circuit when the switching power supply circuit is not stabilized when the monitor is initially powered on. DC voltage ( V _on ) Is drastically lowered, the driving voltage applied to the microcomputer is lowered to 4.3V or less, and thus, the microcomputer is reset to prevent the smooth start of the monitor.

Accordingly, the present invention has been made to solve the above problems, by supplying the auxiliary power supply voltage to the microcomputer if the power supply voltage input to the microcomputer becomes smaller than the rating, the microcomputer stabilization of the monitor to supply a stable driving voltage to the microcomputer at all times The purpose is to provide a circuit.

Micom stabilization circuit of the monitor according to the present invention for achieving the above object is a regulator for stabilizing the input main power supply voltage to output a constant drive voltage; A monitor equipped with a microcomputer operating by receiving a driving voltage from the regulator, the monitor comprising: a switching unit which is switched on when a switching control signal is input and supplies a negative power voltage having a value greater than the main power voltage to the regulator; And a switching control unit for outputting a switching control signal to the switching unit when the value of the main power supply voltage input to the regulator is equal to or lower than a predetermined voltage, and appropriately lowering the sub-power supply voltage input to the regulator when the switching unit is switched on. It is characterized by.

1 is a circuit diagram showing a general switching power supply circuit,

2 is a circuit diagram showing a microcomputer stabilization circuit of the monitor according to the present invention;

3 is a waveform diagram of an initial power supply voltage at initial power-on.

* Names of symbols according to the main parts of the drawings

1: DC power supply 2: transformer

3: power transistor 4: control IC

5 output unit 6 voltage feedback unit

7: regulator 8: micom

10: switching unit 20: switching control unit

RE 1,2: 1,2nd regulator ZD 1,2: 1,1 / 2 Zener diode

Q: transistor R1: feedback resistor

R4, C11: Speed Up Resistors and Capacitors

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

2 is a circuit diagram showing a microcomputer stabilization circuit of the monitor according to the present invention.

The device according to the invention has a voltage, as shown in FIG. V _on A regulator 7 for stabilizing) and outputting a constant driving voltage; In the monitor equipped with a microcomputer (8) which operates by receiving a driving voltage from the regulator (7), when a switching control signal is input is switched on, the main power supply voltage ( V _on Negative supply voltage greater than) V _o A switching unit (10) for supplying the regulator to the regulator (7); Main power voltage input to the regulator 7 V _on ) Outputs a switching control signal to the switching unit 10 when the value is equal to or less than a predetermined voltage, and when the switching unit 10 is switched on, the sub-power voltage input to the regulator 7 ( V _o ) Is configured to include a switching control unit 20 to properly drop the voltage.

Here, the switching unit 10, the base terminal through the switching control unit 20 the main power supply voltage ( V _on ) Is connected in parallel between the regulator (7) and the emitter stage V _o Is a transistor Q and whose collector end is grounded; A feedback resistor (R1) for turning on / off the transistor (Q); It consists of a speed-up resistor R4 and a capacitor R11 for turning on / off the transistor Q at high speed.

The switching control unit 20 further includes: a first zener diode ZD1 having a cathode terminal connected to the base terminal of the transistor Q; A cathode terminal is connected to the anode terminal of the first zener diode ZD1 and an anode terminal is connected to the main power supply voltage ( V _on ) And a second zener diode ZD2 connected in parallel between the regulator 7 and the regulator 7.

Subsequently, the operation and effects of the present invention configured as described above will be divided into normal operation and abnormal operation.

First, in the normal operation, the main power voltage ( V _on ) To 18V and the negative power supply voltage ( V _o ) Is set to 45V, and the sum of the first zener voltage and the second zener voltage is set to 30V.

1.In normal operation (mains voltage V _on ) Is more than 15V)

Main power supply voltage of a DC component output from the switching power supply circuit ( V _on ) 18V, the main power supply voltage ( V _on ) Is inputted to the first regulator RE1 and stabilized at 12V and then supplied to the deflection circuit, while a 12V power supply voltage outputted through the first regulator RE1 is inputted to the second regulator RE2 to 5V. After it is stabilized, it is supplied to the microcomputer 8.

At this time, the main power voltage ( V _on ) Is more than 15V, the switching unit 10 is turned off, accordingly the negative power supply voltage ( V _o ) Is not supplied to the regulator 7.

That is, since the sum of the main power supply voltage 18V and the zener voltage 30V is 48V, the 48V voltage is applied to the base end of the transistor Q. At this time, the voltage 48V applied to the base end of the transistor Q is applied. The transistor Q is turned off by being larger than the voltage 45V applied to the emitter stage, and thus the negative power supply voltage ( V _o ) Is not supplied to the regulator 7.

2. In case of abnormal operation (Main power voltage ( V _on ) Is 15 V or less)

The main power supply voltage ( V _on ) Is less than or equal to 15V, the switching unit 10 is turned on, thereby the negative power supply voltage ( V _o ) Is supplied to the regulator 7.

That is, since the sum of the main power supply voltage (15V or less) and the zener voltage (30V) is 45V or less, the voltage of 45V or less is applied to the base end of the transistor Q. At this time, the base end of the transistor Q is The voltage (45 V or less) becomes smaller than the voltage (45 V) applied to the emitter stage, so that the transistor Q is turned on, and thus the sub power supply voltage ( V _o ) Is supplied to the regulator 7.

At this time, the negative power supply voltage supplied through the switching unit 10 ( V _o Is passed through the zener diodes ZD1 and ZD2 only 15V (negative power supply voltage-zener voltage = 45V-30V = 15V) and is supplied to the regulator 7.

That is, the sub power supply voltage of 15V as shown in FIG. V _o ) Is inputted to the first regulator RE1 and stabilized at 12V and then supplied to the deflection circuit, while a 12V power supply voltage outputted through the first regulator RE1 is input to the second regulator RE2 and is 5V. It is stabilized by and then supplied to the microcomputer (8).

At this time, the main power voltage ( V _on When again rises above 15V, the switching unit 10 is turned off, and accordingly the negative power supply voltage ( V _o ) Is not supplied to the regulator (7), but the main power supply voltage output from the switching power supply circuit ( V _on ) Is supplied to the regulator 7

As described above, the present invention provides a driving voltage supplied to the microcomputer 8 from the switching power supply circuit. V _on ) Is smaller than the rating, the auxiliary drive voltage ( V _o By supplying a), it is possible to always supply a correct driving voltage of 5V to the microcomputer 8, which is effective in stabilizing the microcomputer.

Claims (3)

Input main power voltage V _on A regulator 7 for stabilizing) and outputting a constant driving voltage; In the monitor equipped with a microcomputer (8) operating by receiving a driving voltage from the regulator (7), When the switching control signal is input, the switching is turned on, so that the main power voltage ( V _on Negative supply voltage greater than) V _o A switching unit (10) for supplying the regulator to the regulator (7); Main power voltage input to the regulator 7 V _on ) Outputs a switching control signal to the switching unit 10 when the value is equal to or less than a predetermined voltage, and when the switching unit 10 is switched on, the sub-power voltage input to the regulator 7 ( V _o The microcomputer stabilization circuit of a monitor comprising the switching control part 20 which voltage falls appropriately). The method of claim 1, wherein the switching unit 10, The base terminal is connected to the main power voltage through the switching control unit 20 ( V _on ) Is connected in parallel between the regulator (7) and the emitter stage V _o Is a transistor Q and whose collector end is grounded; A feedback resistor (R1) for turning on / off the transistor (Q); And a speed-up resistor (R4) and a capacitor (R11) for turning on and off the transistor (Q) at high speed. The method of claim 2 wherein the switching control unit 20 A first zener diode ZD1 having a cathode end connected to the base end of the transistor Q; A cathode terminal is connected to the anode terminal of the first zener diode ZD1 and an anode terminal is connected to the main power supply voltage ( V _on And a second zener diode (ZD2) connected in parallel between the regulator and the regulator (7).