KR0133431Y1 - A protecting circuit for over-load - Google Patents

Abstract

The present invention relates to an overvoltage protection circuit, comprising: a first switching element switched according to a magnitude of a voltage applied to a main switching element in order to automatically cut off an overvoltage supply into an electric device, and a main operation by a switching operation of the switching element. A second switching element for controlling the switching operation of the switching element is provided. The apparatus may further include a third switching element controlled on-off by the second switching element, and a light emitting element on / off controlled by the third switching element to receive driving power supplied to the main switching element to output an optical signal. This makes it easy for the user to know that the overvoltage is supplied to the system.

Description

Overvoltage Protection Circuit

1 is a conventional power supply circuit diagram.

2 is an overvoltage protection circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

16: Zener diode 17, 18: voltage divider

19: control transistor 20: switching transistor

22: light emitting diode

The present invention relates to an overvoltage protection circuit, and more particularly, to an overvoltage protection circuit that protects a load and an electric device from overvoltage by automatically blocking the supply of the overvoltage to the load when the power supplied to the load is an overvoltage. It is about.

In general, a power supply circuit used in a compact tape recorder or the like, as shown in Figure 1, 110 volt / 220 volt switching switch (1) that can be switched according to the size of the input AC main power (Vin) and the switching switch ( 1) a transformer 2 for converting the main power supply Vin inputted through 1) into a drive voltage having a predetermined size for driving a load, which will be described later, and a drive voltage converted by the transformer 2; It is provided with an adapter (5) consisting of a bridge diode (3) and a smoothing capacitor (4) to convert to.

In addition, when the jack connected to the adapter (5) is connected to the electrical equipment, the switching switch that the driving voltage supplied through the jack switch 6 and the driving voltage supplied through the jack switch 6 is supplied to the load (7) The emitter terminal is connected to the jack switch 6 so that the collector terminal is connected to the load 7 and the switching transistor 8 to control the switching operation of the switching transistor 8. The collector terminal is connected to the base terminal of the emitter terminal, the emitter terminal is grounded, and the base terminal outputs the on-off control signal to the control transistor 10 connected to the microcomputer 9 and the control transistor 10 according to the drive control signal. And a power input unit 11 composed of a microcomputer 9 for controlling the on-off operation of the control transistor 10.

Here, reference numeral 12 denotes a charge / discharge capacitor, and 12 and 14 denote bias resistors.

In the conventional power supply circuit configured as described above, when 110 volts or 220 volts of AC main power Vin is input, the transformer (1) is switched through the changeover switch 1 according to the connection state of the changeover switch 1 selected by the user. Primary winding of 2) is supplied. At this time, when the user sets the switching switch 1 to 220 volts, the terminal ⓐ and terminal ⓑ are connected, and when the user sets to 110 volts, the terminal ⓐ and the terminal ⓒ are connected. The main power supply Vin supplied to the primary winding of the transformer 2 is induced to the secondary winding, where the main power supply is suitable for driving the load 7 according to the primary and secondary winding ratios of the transformer 2. It is converted into a driving voltage of a predetermined size.

The drive voltage of the alternating current type converted by the transformer 2 is rectified and smoothed by the bridge diode 3 and the smoothing capacitor 4, and is DC-driven and then supplied to one end of the jack switch 6.

At this time, when the user plugs the jack of the adapter 5 into the jack input terminal of the electric machine, the jack switch 6 is connected and the DC voltage is supplied to the emitter terminal of the switching transistor 8.

Here, when the user turns on the main power switch (not shown) of the electric device, this signal is input to the microcomputer 9, and the microcomputer 9 is a control signal in a high state in accordance with an operation signal by the user. Outputs

The control signal is supplied to the base terminal of the control transistor 10. At this time, since the control transistor 10 is of the NPN type, the switching transistor 8 is turned on by being supplied with a high state control signal and is connected to the collector terminal. Switch the base terminal to ground level.

Here, since the switching transistor 8 is of the PNP type, when the base terminal reaches the ground level, the switching transistor 8 is turned on to output the driving voltage supplied to the emitter terminal to the collector terminal.

The driving voltage output from the switching transistor 8 is charged in the smoothing capacitor 12, and when the charging of the smoothing capacitor 12 is completed, the driving voltage is supplied to the load 7 to drive the load normally.

On the other hand, when the user turns off the main power switch to turn off the electric equipment, this control signal is supplied to the microcomputer 9, and the microcomputer 9 supplies the control signal in the low state to the base terminal of the control transistor 10. Output

Since the control transistor 10 is of the NPN type as described above, the control transistor 10 is turned off by receiving a control signal in a low state, and thus the base terminal of the switching transistor 8 is no longer at the ground level. 8 is turned off. Therefore, the driving voltage is cut off without being supplied to the load.

By the way, when the user sets the adapter 5 to 110 volts and 220 volts of main power is supplied, the overvoltage is supplied into the adapter 5 and the transformer 2 is destroyed. At this time, since the overvoltage is supplied to the load 7 until the transformer 2 is destroyed, there is a problem that the load 7 is destroyed and a failure occurs in an expensive electric device.

The present invention is to solve the above problems, an object of the present invention is to provide an overvoltage protection circuit to protect the electrical equipment by automatically blocking the supply of the driving voltage to the load when an overvoltage is applied to the load, Is in.

Features of the present invention for achieving the object as described above, the main switching element for switching the drive voltage supplied to the load, the control switching element for controlling the switching operation of the main switching element, and the control operation of the control switching element An electrical apparatus having a microcomputer for outputting a control signal to control the power supply; A first switching device switched according to the magnitude of the voltage applied to the main switching device; And a second switching element that controls the switching operation of the main switching element by the switching operation of the switching element.

In the present invention, it is preferable that the first switching device comprises a zener diode that is turned on when the voltage applied to the main switching device becomes greater than or equal to a predetermined size.

In addition, the second switching element, the base terminal is connected to the output terminal of the first switching element to switch the control signal having a predetermined level is turned on by the predetermined voltage supplied from the first switching element and output from the microcomputer, Either a collector or an emitter is connected to the output of the computer, and the other of the emitter or collector may be configured as a grounded transistor.

In addition, a third switching device that is on-off controlled by the second switching device; And a light emitting device that is on-off controlled by the third switching device and receives a driving power supplied to the main switching device to output an optical signal.

In addition, the third switching device, the base terminal is connected to the second switching device to be turned on when the voltage applied to the main switching device is an overvoltage, either the emitter or the collector is connected to receive the driving voltage, the collector Alternatively, it is preferable that the other of the emitters is composed of a transistor connected to the light emitting element.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the overvoltage protection circuit according to the present invention will be described in detail. In FIG. 2, the same reference numerals in FIG. 1 denote the same parts, so a description thereof will be omitted, and only essential components of the present invention will be described.

2 shows a voltage divider resistor 15 which divides between the base terminal of the switching transistor 8 and the bias resistor 13 to divide the voltage applied to the switching transistor 8, and the voltage divider resistor. Zener diode 16 switched in accordance with the magnitude of the voltage divided by (15), voltage dividing resistors 17 and 18 for dividing the voltage applied through the zener diode 16, and the voltage dividing resistors ( The voltage divided by 17 and 18 is applied to the base terminal to be on-off controlled to switch the control signal supplied from the microcomputer 9 to the control transistor 10 to pass to the ground. The collector terminal is connected to the base terminal and the emitter terminal is grounded to the control terminal 19 and the base terminal to the collector terminal of the control transistor 19 to be controlled on-off according to the on-off state of the control transistor 19. The emitter terminal is connected to the switching transistor 20 connected between the jack switch 6 and the switching transistor 8, the bias resistor 21 connected to the collector terminal of the switching transistor 20, and the switching And a light emitting diode 22 which is supplied through the transistor 20 and driven by a predetermined voltage detected by the bias resistor 21 to output an optical signal.

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

When the switching switch 1 set by the user and the input main power supply Vin are equal to each other, the driving voltage is supplied to the emitter terminal of the switching transistor 8 through the above-described process of FIG. At this time, since the magnitude of the driving voltage applied to the emitter terminal of the switching transistor 8 is in a normal state, the voltage applied to the base terminal of the switching transistor 8 does not exceed the switching point of the zener diode 16 so that the zener diode ( 16) remains off. Therefore, the same result as described in FIG. 1 is obtained.

On the other hand, when the user sets the switching switch 1 to 110 volts and the input main power supply Vin is 220 volts, the main power supply Vin is supplied to the transformer 2 to destroy the transformer 2.

At this time, as described in FIG. 1 before the transformer 2 is destroyed, the overvoltage supplied to the emitter terminal of the switching transistor 8 causes the emitter voltage of the switching transistor 8 to rise rapidly. As a result, the base voltage also increases.

At this time, when the base voltage exceeds the switching point of the zener diode 16, the zener diode 16 is turned on to control the base voltage of the switching transistor 8 through the voltage dividing resistors 17 and 18. It is supplied to the base terminal of (19).

Since the control transistor 19 supplied with the predetermined voltage to the base terminal is an NPN type, the control transistor 19 is turned on to pass the high level control signal output from the microcomputer 9 to the ground. Turn off (8) at the same time. Thus, overvoltage cannot be supplied to the load 7.

On the other hand, as the control transistor 19 is turned on, the base voltage of the switching transistor 20 is switched to the ground level. At this time, the switching transistor 20 is turned on because it is a PNP type, and the jack switch 6 is turned on. The driving voltage supplied through the PDP is supplied to the light emitting diode 22 through the bias resistor 21.

The light emitting diode 22 is driven by a voltage supplied through the switching transistor 20 to output an optical signal. Accordingly, the user can easily recognize that the main power Vin currently input through the light emitting diode 22 is an overvoltage. You will know.

As described above, according to the overvoltage protection circuit of the present invention, when the voltage supplied to the load in the electrical equipment is overvoltage, the main power is automatically cut off from being supplied to the load, thereby preventing the load and other components inside the electrical equipment from being destroyed. There is an advantage that can be prevented.

In addition, there is an advantage in that the user can easily know that the overvoltage is applied through the light emitting diode, thereby preventing damage to the device.

Claims (5)

An electrical apparatus comprising a main switching element for switching a driving voltage supplied to a load, a control switching element for controlling a switching operation of the switching element, and a microcomputer for outputting a control signal to control the control operation of the control switching element. In; A first switching device switched according to the magnitude of the voltage applied to the main switching device; And a second switching element that controls the switching operation of the main switching element by the switching operation of the switching element. The overvoltage protection circuit of claim 1, wherein the first switching device comprises a zener diode that is turned on when a voltage applied to the main switching device is greater than or equal to a predetermined size. The output terminal of claim 1, wherein the second switching device is turned on by a predetermined voltage supplied from the first switching device to switch a control signal having a predetermined level output from the microcomputer. And a collector or emitter connected to the output terminal of the microcomputer, and the other of the emitter or the collector comprises a grounded transistor. The semiconductor device of claim 1, further comprising: a third switching device controlled on-off by the second switching device; And a light emitting device that is on-off controlled by a third switching device and receives a driving power supplied to the main switching device to output an optical signal. The method of claim 4, wherein the third switching device, the base terminal is connected to the second switching device to be turned on when the voltage applied to the main switching device is an overvoltage, any one of the emitter or collector is a driving voltage Is connected to receive the overvoltage protection circuit, characterized in that the other of the collector or emitter is composed of a transistor connected to the light emitting device.