KR20010011125A - Power switching circuit - Google Patents

Abstract

PURPOSE: A power switching circuit is provided to control a main power switching element having a high capacity when a user operates a power switch having a low capacity, to switch a main power without using a standby power, so as to remove a dangerous factor such as an electric shock in a power on or off state and to prevent power consumption in the power-off state. CONSTITUTION: A main power switching element(14) switches a main power. The first power switch(SW11) is connected when a user turns on the power, and outputs the main power. A differentiator(10) generates a power-on signal for a preset time, when the first power switch(SW11) is turned on. A micro computer(16) is operated when the main power switching element(14) outputs the main power, and continuously outputs the power-on signal. A drive circuit(12) operates the main power switching element(14) for the power-on signal outputted from the differentiator(10) and the micro computer(16), and makes the main power supplied. The second power switch(SW12) is connected when the power is turned off, and intercepts the power-on signal not to be inputted to the drive circuit(12).

Description

Power switching circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power switching circuit for switching main power, which is embedded in various devices such as a television receiver, an optical disk player, and the like, to be supplied as an operating power source to a load according to a user's operation.

In general, in various devices such as a television receiver and an optical disk player, there is a risk of an electric shock accident when the user directly switches the main power supplied to the load as operating power.

Therefore, the apparatus includes a small capacity power switch operated by a user and a large capacity power switching element for switching the main power, and the user switches the main power while the power switching element is turned on and off as the user operates the power switch. .

1 is a conventional power supply switching circuit diagram.

As shown therein, a standby power supply SB + is connected to be applied to the microcomputer 1 and its connection point is connected to the on / off input terminal of the microcomputer 1 through the power switch SW1. ON / OFF).

The on / off output terminal OUT of the microcomputer 1 is connected to the control terminal of the power switching element 3 for switching the main power supply through the drive circuit 2.

In the conventional power switching circuit configured as described above, when the user presses the power switch SW1 while the standby power supply SB + is applied, the standby power supply SB + is connected to the microcomputer 1 through the power switch SW1. ) Is input to the ON / OFF input terminal (ON / OFF).

Then, the microcomputer 1 determines the power on, outputs a high potential power on signal to the on / off output terminal OUT, and the output high power power on signal is input to the drive circuit 2. .

The drive circuit 2 amplifies and outputs an input signal and amplifies and outputs a high potential power-on signal to be applied to the control terminal of the power switching element 3, so that the power switching element 3 is connected. The main power is supplied to the load through the power switching element 3 so that the load operates normally.

When the user presses the power switch SW1 again while the power is turned on and the main power is supplied to the load, the standby power supply SB + turns on / off the microcomputer 1 through the power switch SW1. Input terminal (ON / OFF) is input.

Then, the microcomputer 1 determines the power off and outputs a low potential power off signal to the on / off output terminal OUT, and outputs the low potential power off signal through the drive circuit 2. The power supply switching element 3 is opened by being applied to the control terminal of the switching element 3, and main power cannot be supplied to the load.

However, the above-described conventional power switching circuit must generate standby power separately from the main power supplied to the load and supply the power to the microcomputer 1 as the operating power. There was a problem that a lot of power is consumed without the need to supply the power.

Accordingly, an object of the present invention is to provide a power switching circuit for supplying a load by switching the main power while the power switching element is turned on and off as a user operates a power switch having a small capacity without using a separate standby power source.

According to the power switching circuit of the present invention for achieving the above object, when the user turns on the power, the first power switch is connected to output the main power and the main power output from the first power switch is a differentiator which is a power-on signal generating means. Differentiate to generate a power-on signal for a preset time, and according to the power-on signal generated by the differentiator, the drive circuit operates the main power switching element to supply the main power to the equipment load.

The microcomputer operates according to the main power supplied by the main power switching element to continuously output the power-on signal, and the drive circuit operates the main power switching element to supply the main power to the load of the device.

On the other hand, when the user turns off the power, the second power switch is connected to cut off the power-on signal input to the drive circuit, thereby causing the drive circuit to open the power switching element to cut off the main power.

1 is a conventional power switching circuit diagram,

2 is a power supply switching circuit diagram of the present invention.

* Description of the symbols for the main parts of the drawings *

10: differentiator 12: drive circuit

14: power switching element 16: microcomputer

SW11, SW12: first and second power switch

Hereinafter, a power switching circuit of the present invention will be described in detail with reference to the accompanying drawings.

2 is a power supply switching circuit diagram of the present invention.

As shown therein, the main power supply is connected to the ground resistor R11 through the first power switch SW11 and again via the condenser C11 to constitute the differentiator 1 which is a power-on signal generating means.

The output terminal of the differentiator 10 and the output terminal OUT of the microcomputer 16 respectively pass through diodes D11 and D12, and through the resistor R12, a second power switch having one terminal grounded. (SW12) and an input terminal of the drive circuit 12, the output terminal of the drive circuit 12 controls the main power switching element 14 for switching the main power supply and supplying the load of the device and the microcomputer 16. Connected to the terminal.

The first power switch SW11 and the second power switch SW12 are interlocked with each other. When the user turns on the power, the first power switch SW11 is connected and the second power switch SW12 is opened. When the power is turned off, the first power switch SW11 is opened and the second power switch SW12 is connected.

In the power switching circuit of the present invention configured as described above, when the user turns on the power in the state where the main power is applied, the first power switch SW11 is connected, and the second power switch SW12 is opened, the main power is the first power switch. Through SW11, the derivative signal is differentiated by the capacitor C11 and the resistor R11 of the differentiator 10 and outputs a differential signal.

The differential signal output from the differentiator 10 is input to the drive circuit 12 through the diode D11 and the resistor R12 sequentially.

Then, the drive circuit 12 amplifies the input differential signal, outputs it, and is applied to the control terminal of the main power switching element 14, so that the main power switching element 14 is connected, and the main power supply is connected to the main power switching element 14. Through this, the load is supplied to the load and the load is operated, and the microcomputer 16 is normally operated by being applied to the power supply terminal of the microcomputer 16.

When the microcomputer 16 operates normally as described above, the microcomputer 16 continuously outputs a high potential power on signal to the output terminal OUT, and the output high potential power on signal is a diode D12 and Since the resistor R12 is sequentially input to the drive circuit 12, the drive circuit 12 continuously connects the main power switching element 14 while outputting a high potential, thereby continuously supplying the main power to the load and operating normally.

Here, the diodes D11 and D12 are for preventing the output signals of the differentiator 10 and the microcomputer 16 from being reversed.

In this state, when the user turns off the power to open the first power switch SW11 and connects the second power switch SW12, the high-potential power-on signal output by the microcomputer 16 is output. The dummy diode D12, the resistor R12, and the second power switch SW12 sequentially flow to ground, and a low potential is applied to the input terminal of the drive circuit 12.

Here, the resistor R12 is for preventing over current from being damaged by the output terminal OUT of the microcomputer 16 when the second power switch SW12 is connected.

Then, the drive circuit 12 outputs the low potential, the main power supply switching element 14 is opened, and the main power is cut off.

As described above, according to the present invention, the main power is switched on and off by controlling a main power switching element having a large capacity as a user operates a power switch having a small capacity without using a separate standby power supply. The risk of electric shock is eliminated, and power consumption is prevented without the need of turning off the power supply.

Claims (3)

A main power switching element for switching main power; A first power switch connected when the user turns on the power and outputting a main power; Power-on signal generating means for generating a power-on signal for a preset time when the first power switch is turned on; A microcomputer that is operated when the main power switching element outputs main power and continuously outputs a power on signal; A drive circuit for operating the power switching element to supply the main power to the power on signal generated by the power on signal generating means and the microcomputer; And a second power switch which is connected when the user turns off the power and cuts off the power-on signal generated by the power-on signal generating means and the microcomputer from the drive circuit. The method of claim 1, A power switching circuit, characterized in that it is a differentiator. 2. The power supply of claim 1, wherein the first and second power switches comprise: a; A power switching circuit, characterized in that interlocked with each other.