KR0171093B1 - System power supply protection circuit at abnormal state - Google Patents

Abstract

The present invention relates to a system power cut-off circuit for an abnormal power supply that detects an AC / DC line and cuts off the power for system protection when the AC / DC power line is shorted by the abnormal power supply. The smoothing capacitor (C2) is shorted and an overcurrent is applied to the fuse resistor (FR1) to protect the system by opening the fuse resistor (FR1) .However, when the surge current flows into the AC input terminal, the fuse resistor (FR1) remains normal. If the AC input terminal and the fuse resistor (FR1) is shorted, there is a problem that the standard or the system can not be securely protected due to abnormal oscillation of the transformer or flyback transformer.

In order to solve the conventional problem, the present invention detects when the AC / DC power line is open or shorted and applies it to the microcomputer, so that the microcomputer determines that the abnormal voltage is applied through the sensed voltage to protect the power supply. It is applied to each electronic product to make it easy to cope with the safety standard which is getting more regulated by cutting off the supply.

Description

System power cut-off circuit for abnormal power

1 is a conventional abnormal power cut-off circuit diagram.

2 is a system power cut-off circuit diagram for the abnormal power supply of the present invention.

3 is a flowchart showing a system power-off method for the abnormal power supply of the present invention.

* Explanation of symbols for main parts of the drawings

1: first sensing means 2: second sensing means

3: power supply control means

The present invention relates to a system power cut-off circuit for an abnormal power supply that detects an AC / DC line and cuts off the power for system protection when the AC / DC power line is shorted by the abnormal power supply.

In the conventional abnormal power cut-off circuit, as shown in FIG. 1, when a fuse resistor FR1 is connected to a transformer and flyback transformer AC input terminal and an AC smooth capacitor C2 connected to the fuse resistor FR1 is shorted. The fuse resistor FR1 is configured to be open. C1 is a capacitor and D1 is a diode.

The conventional abnormal power cut-off circuit configured as described above has a capacitor C1 (C2) connected to the fuse resistor FR1 when power is applied to the fuse resistor FR1 through the transformer and flyback transformer AC input terminal as shown in FIG. The power supply (B ⁺ : DC 12V, 30V, 9V) is supplied to the system through and diode (D1).

At this time, when power is supplied to each part of the system, if the smoothing capacitor C2 is shorted, overcurrent is applied to the fuse resistor FR1 connected in series with the diode D1 to open and protect the system by cutting off the power supplied to the system.

However, in the related art, the smoothing capacitor C2 is shorted and an overcurrent is applied to the fuse resistor FR1, thereby protecting the system by opening the fuse resistor FR1. However, when the surge current flows into the AC input terminal, There is a possibility that FR1) may be opened, and when the AC input terminal and the fuse resistor FR1 are shorted, an abnormal oscillation of the transformer or flyback transformer may cause a problem in that it cannot comply with the standard and protect the system safely.

In order to solve the conventional problem, the present invention detects when the AC / DC power line is open or shorted and applies it to the microcomputer, so that the microcomputer determines that the abnormal voltage is applied through the sensed voltage to protect the power supply. The configuration and operation effects of the present invention will be described with reference to the accompanying drawings, in order to be able to easily cope with safety standards that are increasingly regulated by blocking supply.

First, the system power cut-off circuit for the abnormal power supply of the present invention is connected to the flyback transformer and the AC input terminal of the transformer as shown in FIG. 2 to detect the presence or absence of an abnormal state of each terminal voltage. And second sensing means (2) connected to an AC input terminal (CPT RK / GK / BK or a transformer and flyback transformer) to sense whether there is an abnormality in the input voltage, and the 1.2 sensing means (1) (2). It consists of a power supply control means (3) for controlling the power supply on / off for the protection of the system by receiving the voltage output from the sensed), the first sensing means (1) is each terminal output from the flyback transformer or transformer A diode D11 and a capacitor C12 for integrating the voltage, and a diode D11 for supplying and blocking the voltage outputted from the diode D12 and the capacitor C12 to the power supply control means 3, C11. Is a capacitor.

The second sensing means (2) is a resistor (R13-R15) and a capacitor (C13) for dividing and outputting the voltage input from all AC input terminals, and the integral output from the resistor (R13-R15) and a capacitor (C13). A transistor Q12 that operates on / off in accordance with the set voltage and a transistor Q11 that operates on / off so that an abnormal voltage is supplied to the power supply control means 3 according to the on / off operation of the transistor Q12. R12 is a resistor.

The power supply control means 3 includes a coil L11 which transfers the voltage output from the first and second sensing means 1 and 2 to the microcomputer 3A, and a microcomputer when an overvoltage is applied to the microcomputer 3A. Zener diode ZD11 to protect 3A, and microcomputer 3A to turn on / off the power supply for system protection according to the voltage transmitted through the coil L11. R11 is a resistor.

3 is a flowchart for controlling on / off power supply to the system according to the voltage state supplied to the microcomputer 3A of the present invention.

As shown in FIG. 2 and FIG. 3, the operation and effect of the present invention configured as described above are output at the AC input terminal of the flyback transformer or transformer when the power is turned on by the microcomputer 3A in the power supply control means 3. The terminal power supply to be integrated is outputted by the diode D12 and the capacitor C12 in the first sensing means 1.

At this time, when the terminal voltage is integrally output from the diode C12 and the capacitor C12 in a normal state, the DC voltage is supplied to the various element power sources B + and transfers the integrated output voltage to the power supply control means 3. The diode D11 is opened due to the high voltage of the A portion, and thus the voltage output from the first sensing means 1 is not applied to the coil L11 in the voltage supply control means 3, and thus the microcomputer A high voltage is applied to the input terminal I of 3A so that the microcomputer 3A remains on so that power is continuously supplied to the system.

At this time, when the terminal voltage is output from the AC input terminal of the flyback transformer or transformer, when various devices or capacitors C11, C12, and diode D12 are shorted and become abnormal, the A part is grounded and the diode D11 is conducted. Therefore, the first sensing means 1 is connected to the input terminal I of the microcomputer 3A by the coil L11 in the power supply control means 3, thereby providing a low voltage to the input terminal I of the microcomputer 3A. While being applied, the microcomputer 3A turns off the power supply for system protection and cuts off the power supply.

On the other hand, if the voltages input from all AC input terminals (CPT RK / GK / BK, flyback transformer or transformer) are output to the second sensing means 2, the resistance in the second sensing means 2 in the normal state ( When the AC voltage is integrated and output by the R13-R15 and the capacitor C13, the DC voltage is applied to the base of the switching transistor Q12 and the collector is grounded so that a low voltage is applied to the base of the switching transistor Q11. Is approved.

Accordingly, when the low voltage of the switching transistor Q11 is applied, the collector is opened so that the voltage output from the second sensing means 2 is not transferred to the coil L11 in the voltage supply control means 3, thereby the microcomputer 3A. Since the high voltage is applied to the input terminal I of the resistor R11, the system is continuously turned on.

At this time, when the AC input terminal is grounded and is in an abnormal voltage state, no voltage is applied to the base of the switching transistor Q12 in the second sensing means 2, so that the collector is open and the power supply (B ⁺ ) is applied to the base of the switching transistor Q11. The collector is grounded by a resistor (R12), which is up at: SV.

Therefore, the ground DC voltage outputted by the collector of the switching transistor Q11 being grounded is supplied to the input terminal I of the microcomputer 3A through the coil L11 in the power supply control means 3, and thus the microcomputer 3A. ) Cuts off the power supply to protect the system from abnormal voltage.

As described above, when the AC / DC power line is open or shorted, it detects this and applies it to the microcomputer. Therefore, the microcomputer determines that the abnormal voltage is applied through the sensed voltage and cuts off the power supply for system protection. It can easily cope with the increasing safety standard, thereby improving the reliability of the product.

Claims (4)

First sensing means 1, which receives AC voltage output from flyback transformer or transformer and uses it as power of various elements in normal state and transmits it from power supply control means 3 in abnormal state, and AC input stage (flyback transformer) Or second sensing means (2) for transmitting the AC voltage input from the transformer, CPT RK / GK / BK) to the power supply control means (3) in an abnormal state, and the first and second sensing means (1) (2). System power cut-off circuit for the abnormal power consisting of a power supply control means (3) for receiving the abnormal power output from the) to turn off the power for system protection. The first sensing means (1) according to claim 1, characterized in that the diode (D12) and capacitor (C12) for integrating the respective terminal voltages output from the flyback transformer or transformer, and the integral output from the diode (D12) and capacitor (C12). A system power cut-off circuit for an abnormal power supply, characterized in that it comprises a diode (D11) for supplying and interrupting the supplied voltage to the power supply control means (3). 2. The second sensing means (2) includes a resistor (R13-R15) and a capacitor (C13) for dividing and integrating the voltage input from the AC input terminal, and the resistors (R13-R15) and a capacitor ( The transistor Q112 operating on / off in accordance with the integral output voltage in C13) and the on / off operation such that an abnormal voltage is supplied to the power supply control means 3 according to the on / off operation of the transistor Q12. A system power cut-off circuit for an abnormal power supply, characterized in that it comprises a transistor (Q11). 2. The power supply control means (3) according to claim 1, wherein the power supply control means (3) comprises a coil (L11) for transmitting the voltage output from the first and second sensing means (1) (2) to the microcomputer (3A), and the microcomputer (3A). Zener diode ZD11 to protect the microcomputer 3A when an overvoltage is applied to the microcomputer 3A, and a microcomputer 3A to control the power supply on / off for system protection according to the voltage transmitted through the coil L11. A system power interruption circuit for an abnormal power supply.