KR0155104B1 - Abnormal voltage protection circuit of power supply - Google Patents

Abstract

The present invention relates to an abnormal voltage protection circuit in a power supply device, the transformer being supplied with a power to convert a constant voltage according to the ratio of the number of primary and secondary windings, and connected to the secondary side auxiliary winding of the transformer A power supply detecting unit for detecting a voltage variation of the power supply unit, a power supply comparing unit for comparing the voltage output from the power detecting unit with a set reference voltage and an output terminal of the power comparing unit, and outputting a drive signal from the drive unit; A power supply having a power driver for supplying power to a load end by an output signal, the power supply device connected to the main winding to the secondary side of the transformer detects the power supply voltage mode of the load and accordingly performs a predetermined control A relay connected to an output terminal of the microcomputer and performing a switching operation according to the output signal of the microcomputer; The load voltage of the power supply device is determined by varying a reference voltage, which is connected to an output terminal of the relay and under the control of the microcomputer, to be compared with a voltage applied through a secondary side auxiliary winding of the transformer according to a load mode. In this way, the short-circuit detection method of the power supply is divided and the abnormal voltage is applied, thereby improving the safety of the power supply device.

Description

Overvoltage Protection Circuit of Power Supply

1 is an abnormal voltage protection circuit diagram of a conventional power supply.

2 is an abnormal voltage protection circuit diagram of a voltage supply device according to the present invention.

* Explanation of symbols for main parts of the drawings

10: trance 20: rectification and smoothing

30: power detection unit 40: power comparison unit

41: comparator 50: drive stage

51: flip-flop 52: drive driver

60: power drive unit 70: microcomputer

80: relay 90: reference voltage variable part

100: load stage (100) D1-D3: diode

C1-C3: Capacitor

The present invention relates to an abnormal voltage protection circuit in a power supply device. In particular, the load mode of the power supply device is determined, and accordingly, a short circuit detection method of the power supply is distinguished and the safety circuit of the power supply device is cut off when an abnormal voltage is applied. The present invention relates to an abnormal voltage protection circuit in an improved power supply.

In general, various electronic devices use power supply devices to receive their operating power from a commercial power source or other voltage source. When each driving device inside the electronic device requires a different power source, the electronic device is powered by a small drive power source. Switching Mode Power Supply (SMPS), which is a power supply device that can easily control a large current applied to an internal drive device, is used.

The above-described abnormal voltage protection circuit of the power supply apparatus is applied with power as shown in FIG. 1 and the ratio of the number of turns of the main winding part TB and the auxiliary winding part TC on the primary side TA and the secondary side is shown. And a diode (D2, D3) and a capacitor (C2, C3) for rectifying and smoothing the power induced through the transformer (10) and the secondary main winding unit (TB) of the transformer (10). A diode D1 and a resistor R1 connected to the rectifying and smoothing unit 20 and the secondary winding unit TC of the transformer 10 to output a signal according to the voltage variation of the transformer 10. R2) and a power comparator comprising a comparator 41 connected to one output terminal of the power detector 30 and comparing the output value with the reference voltage set by the power detector 30. A flip-flop 51 connected to an output terminal of the power comparing unit 40 and controlling output of a signal; A drive stage 50 including a drive driver 52 connected to one output terminal of the flip-flop 51 and outputting a driving signal, and a power source to the load terminal 100 by a signal output from the drive stage 50. It consists of a power drive unit 60 for supplying.

The abnormal voltage protection circuit of the conventional power supply device configured as described above is configured to supply power to the secondary main winding part TB of the transformer 10 while the power driver 60 is operated to supply power to the equipment connected to the load side. When a short circuit occurs, the voltage applied through the secondary main winding unit TB of the transformer 10 is detected to protect the power supply when the power is shorted.

That is, when the power is shorted in the secondary main winding unit TB of the transformer 10, the voltage input to the power detecting unit 30 connected to the secondary auxiliary winding TC of the transformer 10 is increased. The increased voltage is applied to the inverting terminal (-) of the comparator 41 in the power comparator 40 by passing through the diode D1 in the power supply unit 30.

Here, when the voltage output from the power detecting unit 30 is higher than the voltage set by the capacitor C1 connected to the non-inverting terminal (+) of the comparator 41 in the power comparing unit 40, the power comparing unit ( The comparator 41 in 40 outputs a low signal.

Therefore, when the low signal is output from the comparator 41 in the power comparator 40, the potential at the point C is at the low level. Therefore, the flip-flop 51 in the drive driver 50 does not output the signal to the drive driver 52. As a result, the operation of the power drive unit 60 is stopped and thus power is not applied to the main winding unit TB on the secondary side of the transformer 10, thereby preventing damage to components in the power supply and heat generation of the system. Perform an operation to protect the

The conventional power supply device operating as described above detects an abnormal voltage of the secondary main winding unit by detecting a voltage variation induced through the secondary secondary winding of the transformer, and detects an abnormal voltage of the secondary main winding unit, even when a short circuit occurs in the secondary main winding unit. The voltage fluctuation induced by the winding part is not so small that it is not easy to detect the abnormality of the secondary main winding part side, and especially when the light load having a small rate of change of voltage is applied when the power applied to the electronic device is turned off. The voltage fluctuation induced in the auxiliary winding part is smaller than the voltage fluctuation induced in the secondary auxiliary winding part when a heavy load having a large voltage fluctuation rate is applied.

Therefore, when a light load is applied, such as when the power is turned off, even if the power induced to the secondary main winding unit TB of the transformer is shorted, it is not easy to detect the voltage fluctuation applied to the secondary auxiliary winding TC. Reduces the stability of the power supply device due to the long time that the power is not cut off or the relatively short time is cut off, and overcurrent occurs in the short circuit between them, resulting in heat generation and damage of components in front of the short circuit of the secondary main winding part (TB). There is a problem.

Invented to solve this problem of the present invention by applying a method for detecting the abnormal voltage according to the load mode of the electronic device that is powered through the secondary main winding of the transformer power supply in the power supply device It is an object of the present invention to provide an abnormal voltage protection circuit of a power supply device that reliably detects a short circuit of the power supply due to the application of an abnormal voltage even when a light load is applied when the light is off.

In the present invention for performing the above object, a transformer for converting the power flowing through the primary side into a constant voltage according to the winding ratio of the secondary main winding and the auxiliary winding, and the transformer connected to the secondary winding of the secondary side of the transformer A power supply detecting unit for detecting a voltage change of the power supply unit, a power comparing unit comparing the voltage output from the power detecting unit with a set reference voltage, a drive terminal connected to an output terminal of the power comparing unit, and outputting a driving signal; A power supply having a power driver for supplying power to a load end by a signal output from the power supply device, the power supply unit connected to the secondary main winding of the transformer detects the power supply voltage mode of the load and performs a predetermined control accordingly. And is connected to an output terminal of the microcomputer to perform a switching operation according to the output signal of the microcomputer. Is a reference voltage connected to an output terminal of the relay and controlled by the microcomputer and compared with a voltage applied through the secondary auxiliary winding of the transformer according to a load mode, and outputting a reference voltage to the power comparing unit. It is characterized by including a variable portion.

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

2 is an abnormal voltage protection circuit of the voltage supply device according to the present invention for converting the power flowing into the primary side (TA) to a constant voltage in accordance with the turns ratio of the main winding (TB) and the auxiliary winding (TC) of the secondary side Rectification and smoothing part 20 consisting of a transformer (D2, D3) and a capacitor (C2, C3) rectifying and smoothing the power induced through the transformer 10, the secondary main winding unit (TB) of the transformer (10) ) And a power sensing unit comprising a diode (D1) and resistors (R1, R2) connected to the secondary side winding unit (TC) of the transformer (10) and outputting a signal according to the voltage variation of the transformer (10). A power comparison unit 40 connected to one end of the power detection unit 30 and a comparator 41 comparing the output voltage with a reference voltage set by the power detection unit 30, and the power comparison unit; The flip-flop 51 and the flip-flop 51 which are connected to the output terminal of the unit 40 to control the output of the signal. A drive stage 50 including a drive driver 52 connected to one output terminal and outputting a driving signal, and a power driver 60 for supplying power to the load terminal 100 by a signal output from the drive stage 50; The microcomputer 70 is connected to the secondary main winding unit (TB) of the transformer 10 and detects the power voltage mode output to the load and performs predetermined control according to the conventional power supply device, and the transformer 10 A relay 80 which insulates the secondary auxiliary winding part TC and the main winding part TB of the main body, and is connected to the output terminal of the microcomputer 70 and performs a switching operation according to the output signal of the microcomputer 70; It is connected to the output terminal of the relay 80 and compared with the voltage applied through the secondary side winding unit TC of the transformer 10 to determine the abnormality of the power supply device under the control of the microcomputer 70. Outputting reference voltage The quasi-voltage variable part 90 is added.

In addition, the reference voltage variable part 90 is connected to a switch SW1 that receives a signal from the relay 80 and is compared with a DC voltage detected by the secondary side winding part TC of the transformer 10. Secondary auxiliary winding part of the transformer 10 when the microcomputer 70 does not operate in parallel with the zener diode ZD1 for setting the first reference voltage and the switch SW1 and the zener diode ZD1 Another zener diode ZD2 for setting a second reference voltage compared with the DC voltage detected through (TC) is connected to the non-inverting (+) terminal of the comparator 41 of the power comparison unit 40. .

On the other hand, it will be described in detail the effects of the present invention configured as described above.

When the power supply device outputs a drive signal to the power driver 60 and supplies power to the electronic device from the power driver 60, the microcomputer 70 determines the load mode of the electronic device connected to the power supply device to supply the power. When the off-light light load is applied, the driving signal is output to the relay 80.

When the load mode is light load, the relay 80 receiving the signal output from the microcomputer 70 insulates the secondary winding TC of the transformer 10 from the secondary winding TC and the primary winding TB of the secondary. The switch SW1 of the reference voltage variable part 90 is operated. Accordingly, the first reference voltage set by the zener diode ZD1 in the reference voltage variable part 90 is applied to the non-inverting terminal (-) of the power comparator 40.

At this time, when an abnormal state such as a short circuit of power occurs in the secondary main winding unit TB of the transformer 10, the voltage induced to the secondary auxiliary winding unit TC of the transformer 10 is increased and the increased voltage variation is increased. The inverting terminal (-) of the comparator 41 in the power comparing unit 40 is applied while passing through the diode D1 in the power detecting unit 30 and set by the zener diode ZD1 in the reference voltage variable unit 90. It is compared with the first reference voltage.

Here, the voltage fluctuation detected through the secondary side winding unit TC of the transformer 10 applied to the inverting terminal (-) of the comparator 41 in the power comparator 40 is within the power comparator 40. If the voltage is higher than the first reference voltage set by the zener diode ZD1 connected to the non-inverting terminal (+) of the comparator 41, an abnormal state occurs in the secondary main winding part TB of the transformer 10. The comparator 41 in the 40 outputs a low signal, and thus the potential at the point C also becomes a low level so that the flip-flop 51 in the drive driver 50 does not output the signal to the drive stage 52. The stage 52 does not output the drive signal to the power driver 60, so that the power supply to the secondary main winding unit TB of the transformer 10 is cut off.

In addition, when the microcomputer 70 determines that the load mode is a mode in which a load is applied among operations of various driving apparatuses of the electronic device, the microcomputer 70 does not output any signal to the relay 80 and accordingly, the switch SW1 does not operate. The second reference voltage set by the zener diode ZD2 is applied to the non-inverting terminal (+) of the power comparator 40 to compare with the power detected through the secondary auxiliary winding part TC of the transformer 10. At this time, when an abnormal state such as a short circuit of power connected to the secondary main winding unit TB of the transformer 10 occurs, a voltage variation is detected through the secondary auxiliary winding unit TC of the transformer 10, The voltage variation is applied to the inverting terminal (-) of the comparator 41 in the power comparator 40 while passing through the diode D1 in the power sensing unit 30, so that the zener diode ZD2 in the reference voltage variable unit 90 is applied. It is compared with the second reference voltage set at.

At this time, the voltage fluctuation detected by the secondary side winding unit TC of the transformer 10 applied to the inverting terminal (-) of the comparator 41 in the power comparator 40 is within the power comparator 4. An abnormal condition such as a short circuit occurred on the secondary main winding side of the transformer 10 when the voltage was higher than the second reference voltage set by the zener diode ZD2 connected to the non-inverting terminal (+) of the comparator 41. The comparator 41 in the unit 40 outputs a low signal and thus the potential at the point C also becomes low level so that the flip-flop 51 in the drive stage 50 does not output the signal to the drive driver 52. Accordingly, the power driving unit 60 is not operated to cut off the power induced by the load terminal 100 connected to the secondary main winding unit TB of the transformer 10.

Here, the zener diode ZD1 has a lower conduction voltage than the zener diode ZD2, so the first reference voltage set by the zener diode ZD1 is lower than the second reference voltage set by the zener diode ZD2. It has a value.

Therefore, when the light load is applied from the power supply device, the microcomputer 70 outputs a control signal to the reference voltage variable part 70 to determine the abnormal state than when the heavy load is applied to the power supply device. By lowering and applying the electronic device to light off the load, the system detects the voltage fluctuation detected through the secondary winding of the transformer reliably and protects the system.

As described above, in the present invention, the power supply device determines the load mode and, in the light load mode, adds a reference voltage variable part that reliably detects a voltage change detected through the secondary side winding of the transformer. Even when a light load is applied, such as when the power is turned off, the short circuit of the power supply is reliably detected due to the application of an abnormal voltage, and accordingly, the voltage induced by the main winding part of the secondary side is cut off, thereby generating heat in the component in the power supply device in the event of a short circuit. And it is effective to improve the safety of the power supply by preventing damage.

Claims (2)

The transformer 10 converts the power to a constant voltage according to the ratio of the number of turns through the primary side TA, the secondary main winding unit TB, and the auxiliary winding unit TC, and the secondary side of the transformer 10 by receiving power. The power detector 30 and the voltage output from the power detector 30, which are connected to the auxiliary winding unit TC and sense the voltage variation induced through the primary side TA of the transformer 10, are set to the reference value. A power supply comparator 40 for comparing voltage, a drive terminal 50 connected to an output terminal of the power comparator 40 to output a drive signal, and a load terminal by a signal output from the drive terminal 50. In the power supply device having a power driver 60 for supplying power to the (100), connected to the secondary main winding unit (TB) of the transformer 10 detects the power supply voltage mode of the load and accordingly predetermined control The microcomputer 70 performing the operation and the microcomputer 70 connected to the output terminal of the microcomputer 70. A relay 80 that performs a switching operation according to an output signal, and is connected to an output terminal of the relay 80 and is controlled by the microcomputer 70 through a secondary auxiliary winding TC of the transformer 10. And a reference voltage varying part (90) for varying a reference voltage compared to an applied voltage according to a load mode and outputting it to the power comparing part (40). According to claim 1, wherein the reference voltage variable unit 90 is a direct current applied through the secondary side winding unit (TC) of the transformer 10 to the switch (SW1) to operate by receiving a signal from the relay (80) A zener diode ZD1 for setting a first reference voltage compared with the voltage is connected, and a DC voltage applied through the secondary side auxiliary winding TC of the transformer 10 in parallel with the zener diode ZD1; An abnormal voltage protection circuit of a power supply device, characterized by connecting another zener diode (ZD2) for setting a second reference voltage to be compared.