KR19990036723U - Over current protection circuit in monitor power supply circuit - Google Patents

Abstract

The present invention relates to an overcurrent protection circuit in a power supply circuit of a monitor that protects each circuit element from overcurrent when the input AC voltage is a low voltage below the rated voltage. The circuit of the present invention includes a PWM controller for outputting a PWM control signal for turning on / off a power transistor, a first split resistor to a second split resistor for dividing a PWM control signal output from the PWM controller, A capacitor connected to the second split resistor in parallel to rectify the sensing voltage applied to the second split resistor, and a zener diode turned on when the sensing voltage applied to the second split resistor rises above a rated voltage; And a transistor which is turned on when the zener diode is turned on and stops driving of the PWM controller by holding the feedback terminal of the PWM controller to ground.

Therefore, in the circuit of the present invention, if the input AC voltage is excessively lowered below the rated voltage, the feedback terminal of the PWM controller is grounded and the PWM control signal is not output. It can protect the circuit element. In particular, it is possible to prevent the rectifying diode connected to the secondary side of the transformer from being destroyed due to overcurrent.

Description

Circuit for protecting devices from over-current in a monitor's SMPS

The present invention relates to a power supply circuit of the monitor, and more particularly to an overcurrent protection circuit in the power supply circuit of the monitor to protect each circuit element from overcurrent when the input AC voltage is a low voltage below the rated voltage.

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 serves to properly supply the voltage required in each part of the monitor, the related technology in recent years switching power supply called SMPS (Switched Mode Power Supply) small size, light weight and high efficiency This is a rapidly developing trend.

FIG. 1 illustrates a general switching power supply circuit (SMPS), which includes a DC power supply 110, a transformer 120, a power transistor 130, and a control IC 140.

Referring to FIG. 1, a circuit operation of a general switching power supply (SMPS) is described. First, when commercial AC power of 100 V or 220 V is applied through a fuse, line filters L1 and L2 of a DC power supply unit 110 and a capacitor ( C1, C2, and C3 remove noise introduced through the AC power by the L · C resonant action, and the high frequency noise generated while the bridge diode D1 and the control IC 140 are operated is carried on the AC input line. Block outwards.

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. After the conversion to the DC voltage (Vi), it is applied to the primary winding of the transformer (120). At the same time, the rectified voltage rectified by the bridge diode D1 is applied to the Vcc terminal of the control IC 140 through the start resistor Rg to operate the control IC 140, and output from the control IC 140. The power transistor 130 is turned on / off by the control signal.

That is, when the DC voltage Vi is applied, the supply power Vcc of the PWM controller 140 reaches the starting voltage, and at this time, the PWM controller 140 is operated to output a PWM control signal. The power transistor 130 is turned on / off by the PWM control signal, so that the power transistor 130 remains in the 'on' state for a predetermined time according to the oscillator cycle in the PWM controller 140 and then transitions to the 'off' state. When induced, induced electromotive force is induced from the primary winding of the transformer 120 to the secondary winding. In this case, the transformer 120 outputs an AC voltage required by the secondary winding by the PWM control signal.

By repeating this operation, the AC voltage output from the secondary winding of the transformer 120 is converted into a DC voltage Vo through the diode D2 and the capacitor C5. On the other hand, if the transformer 120 operates normally, the voltage output from the tertiary winding of the transformer 120 is applied to the Vcc terminal of the PWM controller 140 to enable the PWM controller 140 to operate in the normal state.

However, when the input AC voltage applied to the DC power supply unit 110 in the power supply circuit of the monitor is lowered, the magnitude of the input current is increased to consume a constant power. When the input AC voltage is excessively lower than the rated voltage, the transformer There is a problem in that the overcurrent flows to the rectifying diode D2 connected to the secondary side of 120 so that the diode is destroyed.

That is, in the period where the PWM control signal is at a high level, since a reverse voltage is applied across the rectifying diode D2 connected to the secondary output terminal of the transformer 120, the diode D2 is turned off and the PWM control signal is turned off. In the low level section, a conduction voltage is applied across the rectifying diode D2 so that the diode is turned on so that a current is charged from the secondary side of the transformer 120 to the smoothing capacitor C5. Of course, even when the PWM control signal is at a low level, the diode D2 is turned off when the charging voltage of the smoothing capacitor C5 is higher than the secondary voltage of the transformer 120.

At this time, when the input AC voltage is low, the DC voltage (Vi) is lowered and the voltage induced to the secondary side of the transformer is lowered. When the diode is turned on to generate the required power, the rectifying diode is destroyed when excessive current flows. There is a problem that occurs.

Therefore, the present invention was devised to solve the problems of the prior art as described above. When the input AC voltage supplied into the monitor is lower than the rated voltage, the driving of the power circuit is stopped so that each circuit element, in particular, of the transformer It is an object of the present invention to provide an overcurrent protection circuit in a power supply circuit of a monitor that protects a rectifying diode connected to a secondary side.

The circuit of the present invention for achieving the above object, the monitor to generate the driving power required in each part of the monitor through the transformer by switching the DC voltage output from the DC power supply in accordance with the power transistor on / off A power supply circuit comprising: a PWM controller for outputting a PWM control signal for turning on / off the power transistor; First to second split resistors for dividing the PWM control signal output from the PWM controller; A capacitor connected in parallel with the second split resistor to rectify a sensing voltage applied to the second split resistor; A zener diode which is turned on when the sensing voltage applied to the second split resistor becomes higher than the rated voltage; And a transistor which is turned on when the zener diode is turned on and stops driving of the PWM controller by holding the feedback terminal of the PWM controller to ground.

1 is a circuit diagram showing a power supply circuit of a general monitor;

2 is a circuit diagram illustrating a power supply circuit of a monitor 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: PWM controller

200: overcurrent protection

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

2 shows a power supply circuit of the monitor according to the present invention, which includes a DC power supply unit 110, a transformer 120, a power transistor 130, a PWM controller 140, a voltage feedback unit, , Overcurrent protection unit 200.

The voltage feedback unit rectifies and smoothes the AC voltage output to the tertiary winding of the transformer 120 and the DC voltage rectified and smoothed by the diode D3 and the capacitor C6. Is divided into resistors R1 and R2 provided to the feedback terminal Vfb of the PWM controller 140.

The overcurrent protection unit 200 is connected in parallel with the first split resistor R21 to the second split resistor R22 for dividing the PWM control signal output from the PWM controller 140 and the second split resistor R22. And a capacitor C21 for rectifying the sensing voltage applied to the second split resistor R22 and a zener diode that is turned on when the sensing voltage applied to the second split resistor R22 becomes higher than the rated voltage. ZD21 and a transistor Q21 which is turned on when the zener diode ZD21 is turned on and holds the feedback terminal Vfb of the PWM controller 140 to ground to stop driving of the PWM controller 140. do.

The operation of the present invention configured as described above is as follows.

The DC voltage supply unit 110 receives commercial AC power of 100V or 220V through the fuse and converts the DC voltage into the DC voltage Vi through the resistor Rs and the smoothing capacitor C4. Is applied to the primary side. On the other hand, when the PWM controller 140 is operated by receiving the driving voltage through the starting resistor Rg, a PWM control signal is output from the output terminal (out), and the power transistor 130 is turned on / off by this PWM control signal. Switch to turn off.

While the power transistor 130 is turned on / off, the DC voltage Vi provided to the primary side of the transformer 120 is switched and an AC voltage according to the turns ratio is output to the secondary side of the transformer 120. The AC voltage is rectified by the diode D2 and smoothed by the capacitor C5 and supplied to each circuit portion of the monitor.

At this time, the AC voltage output from the transformer 120 varies according to the turn-on time of the power transistor 130 and the DC voltage Vi provided from the DC voltage supply unit 110, and the commercial AC power supply AC is overloaded. When lowered due to the DC voltage Vi provided from the DC voltage supply unit 110 is also lowered.

Here, when the commercial AC power source AC is lowered to about 80V to 90V, the AC voltage output to the secondary and tertiary windings of the transformer 120 is lowered, which is compensated by the voltage feedback unit. That is, when the AC voltage output to the tertiary winding of the transformer 120 is lowered, the feedback voltage applied to the feedback terminal Vfb of the PWM controller 140 through the resistors R1 and R2 is lowered. When the feedback voltage decreases, the PWM controller 140 outputs a PWM control signal with a long on-time to increase the turn-on time of the power transistor 130. Even though the DC voltage Vi is lowered, the PWM controller 140 As the turn-on time increases, each circuit part of the monitor can operate normally.

However, when the commercial AC power is excessively lowered to 80V or less, the overcurrent protection unit 200 is driven to protect each circuit unit of the monitor from overcurrent by stopping the driving of the PWM controller 140. same.

When the commercial AC power is excessively low, the turn-on time of the PWM control signal output from the PWM controller 140 becomes excessively long, and the PWM control signal is divided into a first split resistor R21 and a second split resistor. It is divided by R22 and smoothed by a capacitor C21. At this time, when the turn-on time of the PWM control signal becomes longer and the sensing voltage applied to the second split resistor R22 becomes higher than the rated voltage of the zener diode ZD21, the zener diode ZD21 is turned on and the transistor Q21 is turned on. Is turned on.

When the transistor Q21 is turned on as described above, the PWM controller 140 burns out while the feedback terminal of the PWM controller 140 connected to the collector terminal of the transistor Q21 is held at the ground level. And the PWM control signal output from the PWM controller 140 is blocked. That is, as the switching operation of the power transistor 130 is stopped, the entire operation of the power supply circuit of the monitor is stopped so that each circuit part of the monitor may be protected from overcurrent.

As described above, when the input AC voltage is excessively lowered below the rated voltage, the feedback terminal of the PWM controller is grounded and the PWM control signal is not output. Each circuit element can be protected from the resulting overcurrent. In particular, it is possible to prevent the rectifying diode connected to the secondary side of the transformer from being destroyed due to overcurrent.

Claims (1)

In the power supply circuit of the monitor to switch the DC voltage output from the DC power supply in accordance with the power transistor on / off to generate the drive power required by each part of the monitor through a transformer, A PWM controller for outputting a PWM control signal for turning on / off the power transistor; First to second split resistors for dividing the PWM control signal output from the PWM controller; A capacitor connected in parallel with the second split resistor to rectify a sensing voltage applied to the second split resistor; A zener diode which is turned on when the sensing voltage applied to the second split resistor becomes higher than the rated voltage; And And a transistor configured to hold the feedback terminal of the PWM controller to ground while the zener diode is turned on to stop the driving of the PWM controller.