KR19990034335A - Soft-start circuit in switching power supply circuit of monitor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soft start circuit in a switching power supply circuit of a monitor. Conventional switching power supply circuits receive a DC voltage output from a DC power supply and generate an induced electromotive force, and PWM control the operation of the power transistor. It consists of a control IC and a voltage feedback unit for sensing the power supply voltage output from the secondary winding of the transformer and supplying a feedback voltage to the control IC, since the power supply voltage output to the secondary winding of the transformer is very low when the initial power-on On-time of the PWM control signal output from the control IC is very long, which causes a problem that the voltage induced by the secondary winding of the transformer is rapidly increased to cause damage to the secondary circuit elements of the transformer.

Therefore, the circuit of the present invention includes a KA431 integrated circuit for outputting a cathode voltage that varies according to the magnitude of a power supply voltage, a photo coupler for supplying a feedback voltage according to the cathode voltage of the KA431 integrated circuit to the control IC, and an initial stage of a monitor. The voltage is induced to the secondary winding of the transformer when the initial power-on of the monitor is further provided by providing an initial voltage supply unit for applying a voltage of a predetermined magnitude or more to the reference terminal of the KA431 at power-on to increase the feedback voltage supplied to the control IC. There is an effect to prevent this from rising rapidly.

Description

A soft start circuit of a SMPS in a monitor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching power supply circuit of a monitor, and more particularly, to a soft start circuit in a switching power supply circuit of a monitor which is supplied to respective circuits of a monitor after stabilizing an initial power supply voltage by adjusting a pulse width of a PWM signal at initial power-on. It is about.

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.

FIG. 1 illustrates a general conventional switching power supply circuit (SMPS), which includes a DC power supply 110, a transformer 120, a power transistor 130, a control IC 140, and an output unit ( 150, the voltage feedback unit 160, and the overcurrent detection unit 170.

Referring to FIG. 1, a circuit operation of a general switching power supply (SMPS) is described. First, when 100 V or 220 V commercial AC power is applied through a fuse, the line filters L1 and L2 and the capacitors C1, C2, and C3 are By removing the noise introduced through the AC power by the L-C resonant action, the high frequency noise generated while the bridge diode D1 and the control IC 140 are operated is blocked from traveling outside 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 applied to the primary winding of transformer 120. At the same time, the rectified voltage rectified by the bridge diode D1 is applied to the control IC 140. V _cc Resistance at R _g ) Is applied to operate the control IC 140, and the power transistor 130 is turned on / off by the control signal output from the control IC 140.

That is, the DC voltage ( V _i ) Is applied, the direct current voltage ( V _i Power supply of the control IC 140 as V _cc ) Reaches the starting voltage, the control IC 140 is operated to generate a PWM control signal, and the power transistor 130 is turned on / off by this PWM control signal. When the power transistor 130 maintains the 'on' state for a predetermined time according to the oscillator cycle in the control IC 140 and transitions to the 'off' state, the power transistor 130 is induced from the primary winding of the transformer 120 to the secondary winding. Induced electromotive force is generated.

At this time, the transformer 120 is the AC voltage required in the secondary winding by the PWM control signal ( V _s, V _sm ) Will be printed. By repeating this operation, the AC voltage output from the secondary winding of the transformer 120 ( V _s, V _sm ) Through the output unit 150 again the DC voltage ( V _o, V _om Is converted to). That is, the AC voltage input to the output unit 150 ( V _s, V _sm ) Is the direct current voltage (V) by rectifying diodes (D2, D3) and smoothing capacitors (C6, V _o, V _om ) Is supplied to each circuit of the monitor to operate the circuit.

However, the power supply voltage output through the output unit 150 ( V _o, V _om ) Rises above the reference voltage, the circuit element may be damaged due to overvoltage, which may shorten the lifespan of the power supply circuit. Therefore, in order to maintain the output voltage of the output unit 150 at a constant voltage, the switching power supply circuit The SMPS generally includes a voltage feedback unit 160.

In more detail, the power supply voltage to each circuit of the monitor ( V _o ) Is detected by the voltage feedback unit 160 including the photo couplers PC1 and PC2 and the KA431 integrated circuit 161, and the detection signal is input to the feedback terminal of the control IC 140. That is, the voltage applied to the reference terminal R of the KA431 integrated circuit 161 is variable according to the voltage applied to the secondary winding of the transformer 120, and thus the cathode terminal voltage of the KA431 integrated circuit 161 is increased. While being variable, the amount of current flowing through the light emitting portion PC1 of the photo coupler is controlled.

For example, the power supply voltage output from the output unit 150 ( V _o ) Is greater than normal operation, the voltage applied to the reference terminal R of the KA431 integrated circuit 161 is increased to short-circuit the cathode terminal K and the anode terminal A of the KA431 integrated circuit 161. Since the cathode terminal K voltage of the KA431 integrated circuit 161 is lowered, more current flows momentarily through the light emitting unit PC1 of the photocoupler than during normal operation to emit as much light.

In this case, the light receiving unit PC2 of the photocoupler receives a lot of light, converts the optical signal into an electrical signal, and outputs the light signal to the feedback terminal of the control IC 140. The applied feedback voltage is increased so that the control IC 140 outputs a PWM control signal with a short on time. That is, the on time of the power transistor 130 is shortened.

As the on time of the power transistor 130 is shortened, the induced electromotive force induced from the primary winding of the transformer 120 to the secondary winding ( V _s, V _sm ) Is lowered, the power supply voltage (outputted from the SMPS) V _o, V _om ) Is maintained at a constant voltage and supplied to each circuit of the monitor.

At this time, the control IC 140 detects the current flowing through the power transistor 130 through the overcurrent detector 170, controls the duty ratio of the PWM control signal according to the detected current amount, and at the same time, overcurrent When detected, the power transistor 130 is forcibly turned off. That is, the current flowing through the power transistor 130 is sensed through an overcurrent sensing resistor R11, and the detected voltage is again filtered through a low pass filter R12 and C11, and then the control IC 140, overcurrent detection stage ( I _sen Supplies). Accordingly, the control IC 140 controls the duty ratio of the PWM control signal according to the overcurrent detection signal.

However, since the power supply voltage output to the secondary winding of the transformer 120 is very low in the conventional switching power supply circuit SMPS, the current flowing through the light emitting portion PC1 and the light receiving portion PC2 of the photocoupler is very low. Due to the low and very low feedback voltage of the control IC 140, the on time of the PWM control signal output from the control IC becomes very long. That is, there is a problem that the voltage induced from the primary side of the transformer to the secondary winding is sharply increased to cause damage to the secondary circuit elements of the transformer.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, by adjusting the pulse width of the PWM signal at the initial power-on of the monitor to stabilize the initial power supply voltage of the monitor to be supplied to each circuit of the monitor It is an object of the present invention to provide a soft start circuit in a switching power supply circuit.

In the switching power supply circuit of the monitor according to the present invention for achieving the above object, the soft start circuit is a transformer for generating an induced electromotive force by receiving a DC voltage output from a DC power supply unit, and a power transistor according to the feedback voltage. In the switching power supply circuit of the monitor comprising: a control IC for PWM control operation and a voltage feedback unit for sensing a power supply voltage output from the secondary winding of the transformer and supplying a feedback voltage to the control IC. A switching element configured to apply a power supply voltage output from the secondary winding to a reference terminal to output a cathode voltage which varies according to the magnitude of the power supply voltage; A photo coupler for supplying a feedback voltage according to the cathode voltage of the switching element to the control IC; And an initial voltage supply unit supplying a voltage greater than or equal to a predetermined magnitude to a reference terminal of the switching element to increase a feedback voltage supplied to the control IC when the monitor is initially powered on.

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

2 is a circuit diagram showing a switching power supply circuit of a monitor including a soft start circuit according to the present invention;

3 is an internal circuit diagram of a KA431 integrated circuit according to the present invention.

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

110: DC power supply 120: transformer

130: power transistor 140: control IC

150: output section 200: voltage feedback section & soft start section

210: KA431 integrated circuit 220: initial voltage supply

C21: capacitor D21: forward connection diode

D22: reverse connection diode

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

2 is a circuit diagram illustrating a switching power supply circuit of a monitor including a soft start circuit according to the present invention.

As shown in FIG. 2, the switching power supply circuit of the monitor according to the present invention includes a transformer 120 generating an induced electromotive force by receiving a DC voltage output from the DC power supply 110 and a power transistor according to a feedback voltage. The control IC 140 PWM-controls the operation of the operation 130 and the power supply voltage output from the secondary winding of the transformer 120 to sense the feedback voltage to the control IC 140 ( V _fb ), And a voltage feedback part & soft start part 200 for supplying ().

Here, the voltage feedback unit & soft start unit 200 according to the present invention, the power supply voltage output from the secondary winding of the transformer 120 is applied to the reference terminal (R) is variable according to the magnitude of the power supply voltage A switching element implemented with a KA431 integrated circuit 210 for outputting a cathode voltage, a photo coupler PC1 and PC2 for supplying a feedback voltage according to the cathode voltage of the KA431 integrated circuit 210 to the control IC 140; The initial voltage supply unit 220 is configured to supply a voltage greater than or equal to a predetermined magnitude to the reference terminal R of the KA431 integrated circuit 210 to increase the feedback voltage supplied to the control IC 140 when the monitor is initially powered on. .

Here, the initial voltage supply unit 220 is a capacitor (C21) for charging a predetermined voltage when the monitor is in normal operation, and the charging voltage of the capacitor (C21) when the initial power-on of the monitor is the reference terminal of the KA431 integrated circuit 210 A forward connection diode (D21) providing a path to be applied to (R), a reverse connection diode (D22) biased to prevent the charging voltage of the capacitor (C21) from being discharged when the monitor is powered off, and the initial stage of the monitor It is composed of a reverse discharge blocking diode (D23), a resistor (R21), a resistor (R22) for supplying power so that a predetermined voltage of the capacitor (C21) can be charged when the power is on. The reverse discharge blocking diode D23 may block a path so that the charging voltage of the capacitor C21 is not discharged through the resistor R22 when the monitor is powered off.

Operation and effects of the present invention configured as described above are as follows.

Before describing the present invention, the operation state of the KA431 integrated circuit, which is a major component of the present invention, will be described with reference to FIG. 3. The KA431 integrated circuit 210 includes a comparator 211 and a transistor 212. . Here, the non-inverting input terminal of the comparator 210 is a reference terminal (R), the output signal of the comparator 210 is input to the base terminal of the transistor 212, the collector of the transistor 212 The terminal and the emitter terminal become the cathode terminal K and the anode terminal A, respectively.

A reference voltage of about 2.5V is applied to the inverting input terminal of the comparator 211. When the voltage applied to the reference terminal R becomes 2.5V or more, the reference voltage of the comparator 211, The output is at a high level so that the transistor 212 is turned on and the cathode end K and the anode end A are shorted. At this time, the voltage output to the cathode terminal (K) is variable according to the magnitude of the voltage applied to the reference terminal (R).

Referring to the operation of the present invention, the DC voltage supply unit 110 receives a commercial AC power of 100V or 220V through the fuse and the DC voltage ( V _i ) And the primary winding of the transformer 120 and the resistance ( R _g Of control IC 140 V _cc In this case, the control IC 140 is operated and the power transistor 130 is turned on / off by the PWM control signal output from the control IC 140.

That is, DC voltage ( V _i ) Is applied, the direct current voltage ( V _i Power supply of the control IC 140 as V _cc ) Reaches a starting voltage and the control IC 140 is operated to generate a PWM control signal, and the power transistor 130 is turned on / off by the PWM control signal. Since the electromotive force is induced to the secondary winding of the transformer 120 as the power transistor 130 is turned on / off, the voltage output from the secondary winding is very low when the monitor is initially turned on. A very low voltage is applied to the reference terminal R to open between the cathode terminal K and the anode terminal A of the KA431 integrated circuit 210 so that no current flows to the KA431 integrated circuit 210.

At this time, when the KA431 integrated circuit 210 cuts off the current and the current does not flow to the light emitting unit PC1 of the photocoupler, a very low feedback voltage is applied to the control IC 140. The PWM control signal having a very long on-time is output, which causes the power supply voltage induced to the secondary winding of the transformer 120 to rise sharply. This is solved using the initial voltage supply unit 220.

That is, while the monitor is normally driven, the power voltage induced in the secondary winding of the transformer 120 is charged to the capacitor C21 through the resistor R21, the resistor R22, and the reverse discharge blocking diode D23. Since the current flow is interrupted by the reverse connection diode D22 and the reverse discharge blocking diode D23 even when the power of the monitor is turned off, the charging voltage of the capacitor C21 may not be discharged, and thus the charging state may be maintained.

As described above, when the power of the monitor is initially turned on while the capacitor C21 is charged with a predetermined magnitude, the charging voltage of the capacitor C21 is referenced to the KA431 integrated circuit 210 through the forward connection diode D21. The cathode voltage of the KA431 integrated circuit 210 is low because the charging voltage is applied to the reference terminal R even when the power supply voltage induced by the secondary winding of the transformer 120 is low. The current flowing from the power supply voltage output from the secondary winding of the transformer 120 to the light emitting part PC1 of the photo coupler flows through the cathode end K and the anode end A of the KA431 integrated circuit 210. will be.

That is, as described above, the initial voltage supply unit 220 increases the voltage applied to the reference terminal R of the KA431 integrated circuit 210 to a predetermined level or more, and the cathode voltage of the KA431 integrated circuit 210 is increased. Since the current is lowered so that a current of a predetermined level or more flows to the light emitting unit PC1 of the photocoupler, the feedback voltage applied to the control IC 140 is increased to a predetermined level or more, thereby causing the control IC 140 to turn on. By outputting this short PWM control signal, it is possible to prevent the power supply voltage induced to the secondary winding of the transformer 120 from being sharply increased.

Meanwhile, when the power supply voltage rises above a predetermined level while the power supply voltage induced by the secondary winding of the transformer 120 is stabilized, the reference terminal R of the KA431 integrated circuit 210 through the reverse connection diode D22. ) And the cathode voltage of the KA431 integrated circuit 210 is further lowered to increase the amount of current flowing through the light emitting unit PC1 of the photo coupler, which is applied to the control IC 140. The voltage is increased, which causes the control IC 140 to output a PWM control signal with a short on time, thereby reducing the electromotive force induced by the secondary winding of the transformer 120.

As described above, in the apparatus of the present invention, even when the power supply voltage induced by the secondary winding of the transformer is low when the monitor is initially powered on, the feedback voltage of a certain level or more is applied to the control IC, thereby rapidly increasing the power supply voltage of the transformer. Since it is not possible to protect the circuit elements of the switching power supply circuit.

Claims (3)

A transformer for generating an induced electromotive force by receiving a DC voltage output from a DC power supply unit, a control IC for PWM controlling the operation of a power transistor according to a feedback voltage, and sensing a power voltage output from a secondary winding of the transformer; In the switching power supply circuit of the monitor comprising a voltage feedback unit for supplying a feedback voltage to the control IC, A switching element configured to apply a power supply voltage output from the secondary winding of the transformer to a reference terminal to output a cathode voltage which varies according to the magnitude of the power supply voltage; A photo coupler for supplying a feedback voltage according to the cathode voltage of the switching element to the control IC; And A soft start circuit of a switching power supply circuit of a monitor, comprising: an initial voltage supply unit configured to increase a feedback voltage supplied to a control IC by supplying a voltage of a predetermined magnitude or more to a reference terminal of the switching element when the monitor is initially powered on. The display device of claim 1, wherein the initial voltage supply unit provides a capacitor for charging a constant voltage when the monitor is in normal operation, and a path for applying the charging voltage of the capacitor to a reference terminal of the switching element when the monitor is initially powered on. A forward connection diode, a reverse connection diode biased to prevent the charging voltage of the capacitor from being discharged when the monitor is turned off, a charging voltage is applied to the capacitor when the monitor is turned on, and the charging voltage of the capacitor is turned off when the monitor is turned off A soft start circuit in a switching power supply circuit for a monitor, characterized by comprising a reverse discharge blocking diode that blocks a path from being discharged. The soft start circuit of claim 1, wherein the switching device is implemented as a KA431 integrated circuit.