KR930011479B1 - Back-up circuit - Google Patents

Abstract

The circuit supplies backup power to a microcomputer and a remote control module when a power is OFF. The circuit includes a power switching unit (20) for supplying and breaking power supply by a transformer (T3), a transformer (T3) for inducing low-current high- voltage to a sub-winding (B), a 1st voltage regulating unit (40) for supplying output voltage to the microcomputer (1) and the remote control module (2), a 2nd voltage regulating unit (50) for supplying backup power to the micom (1) and the remocon module (2), and a voltage protection unit (60) for bypassing the rectifying voltage of the 2nd voltage unit (50).

Description

Backup power supply circuit when power off

1 is a conventional backup power supply circuit diagram.

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

* Explanation of symbols for main parts of the drawings

20: power switching unit 50: second constant voltage unit

60: voltage rise prevention unit T1 to T3: transformer

RY1: Relay REG1 ~ REG3: Regulator

The present invention relates to a backup power supply circuit when power is turned off to supply back-up power to the microcomputer and the remote control module when the power of the system of the present invention is turned off.

In the conventional backup power supply circuit, as shown in FIG. 1, the main transformer T1, the bridge diode BD1, and the capacitor C1 (C2) supplying the main power to the system by dropping and rectifying the input AC power. The main power supply unit 10 and the voice recognition using a binary voice feature that is suitable for reducing the size of the memory (RAM, ROM required for the microcom) and the time required to compare the voice feature pattern Resistor R1, transistor TR1, diode D1, and relay RY1 that are switched under the control of the control panel) to transfer and cut off the AC power input through the power cord PC to the main power supply 10. , The power switching unit 20 of the spark-proof capacitor C3 and the AC power inputted through the power cord PC are dropped and rectified to supply the sub-power, and the microcomputer 1 and the remote control module 2 when the power is turned off. To supply backup power to The western power supply unit 30 includes the transformer T2, the diodes D2 to D4, the capacitor C4, the regulator REG1, and the resistor R2.

The conventional circuit configured as described above has a subtransformer T2 in front of the relay RY1 separately from the main transformer T1 to supply power to the microcomputer 1 and the remote controller module 2 even when the relay RY1 switch is turned off. Connected.

Therefore, even though the relay RY1 is turned off and the main power is not supplied, the AC power is applied to the sub relay T2. n2 / n1V _AC) is caught, the voltage (V _b) is applied to the regulator (REG1) via the smoothing capacitor (C4) after the half-wave rectified by a diode (D2) is outputted at a predetermined constant voltage. The constant voltage output from the regulator REG1 is applied to the microcomputer 1 and the remote controller module 2 through the diodes D3 and D4, and the microcomputer 1 and the remote controller module 2 even when the power is turned off by this backup power supply. ) Will work.

In this state, when the user turns on the power switch, a high potential signal is output through the terminal OUT of the microcomputer 1 and the transistor TR1 is turned on so that the sub power is applied through the relay RY1 and the transistor TR1. The relay RY1 is driven, the relay RY1 switch is connected, and AC power is applied to the main transformer T1.

Therefore, the AC power dropped by the main transformer T1 is full-wave rectified while passing through the bridge diode BD1, and the rectified power is smoothed by the capacitors C1 and C2 and supplied to the system as the main power source.

However, since the conventional method must always supply power to the microcomputer and the remote control module, a sub transformer must be separately provided to supply backup power to the system when the power is turned off, resulting in high production cost and design problems.

The present invention has been devised to solve the above problems, in that a small current is introduced through the spark prevention capacitor even when the power is off, and the sub transformer is deleted and backed up using the induced voltage in the main transformer. By supplying power and bypassing the increased voltage at power-on, it is possible to always supply power to the microcomputer and the remote control module. The embodiments of the present invention will be described in detail with reference to FIG.

FIG. 2 is a backup power supply circuit diagram of the present invention, as shown therein, which is switched under the control of the microcomputer 1 to transfer and cut off the AC power input through the power cord PC to the transformer T3. The power supply switching section 20 consisting of R1, transistor TR1, diode D1, relay RY1, and spark preventing capacitor C3, and the secondary winding are connected to the main winding A and the sub winding B. When the power supply is separated, the transformer (T3) which induces the low current and high voltage in the sub-winding wire (B2) by using a small current through the capacitor (C3), and rectifies the voltage output from the main winding (A) of the transformer (T3) Bridge diode (BD1), capacitor (C5) (C6), resistor (R3), regulator (REG2), diode that supplies the main power and supplies a predetermined constant voltage to the microcomputer (1) and the remote control module (2) when the power is turned on. A predetermined constant voltage is rectified by rectifying the voltage output from the first winding unit 40 (D5) and the sub winding B of the transformer T3. A diode (D3) (D4) (D6), a capacitor (C7) (C8), a resistor (R2) (R4), and a regulator (REG3) for supplying the microcomputer (1) and the remote control module (2) as backup power. By switching the second constant voltage unit 50 and the rectified voltage of the first constant voltage unit 40 while bypassing the rectified voltage of the second constant voltage unit 50 to increase the voltage of the second constant voltage unit 50 when the power is turned on. The control diode ZD1, the resistors R5, R6, and the transistor TR2 are configured to prevent the voltage rise prevention unit 60 from being prevented.

The present invention configured as described above focuses on the fact that when the relay RY1 is switched off, the alternating voltage V _AC can apply a minute voltage Vi to the primary side of the power transformer T3 through the spark preventing capacitor C3. It was.

That is, since the equivalent circuit of the capacitor (c3) is the impedance of the capacitor (c3) is Z _C3 + R + k (WL-1 / WC), and if the impedance of the primary side of the transformer (T3) is Z _P , Vi is Z _P / (Z _C3 + ZP) x V _AC . Therefore, if the number of windings of the secondary winding B on the secondary side is large (n3>), the output voltage becomes proportional to n3 / n1 × Vi, and the current is inversely proportional to n3 / n1. Low current can be induced. When the relay RY1 is switched off, the AC power supply V _AC conducts the voltage of Vi to the primary winding of the transformer T3 through the capacitor C3, and the high voltage low current to the secondary winding B. Since the winding is used, a voltage proportional to n 3 / n 1 × Vi is applied to the sub winding B.

This voltage is half-wave rectified through the diode D6 and then applied to the regulator REG3 through the smoothing capacitor C7, and the output terminal is subjected to a voltage of 5V.

This voltage is applied to the microcomputer 1 and the remote control module 2 through the diodes D3 and D4 so that the microcomputer 1 and the remote control module 2 can operate even when the power is turned off.

When the power supply ON signal is applied to the microcomputer 1, the terminal OUT of the microcomputer 1 becomes high potential, and the signal conducts the transistor TR1 through the resistor R1 to supply the second constant voltage unit 50. Since the rectified voltage passes through the relay RY1, the regulator RY1 is turned on, and AC power V _AC is applied to the transformer T3 so that a high voltage is applied to the primary winding A and the secondary winding B on the secondary side. Induced. The voltage of the main winding (A) is full-wave rectified through the bridge diode (BD1) and the capacitor (C5) (C6), the regulator REG2 is applied to the output terminal of a voltage of 5.6V, the microcomputer 1 and the remote control module ( Voltage is applied to 2). At this time, the high voltage and current of the negative winding B2 are applied to the input terminal of the regulator REG3, resulting in high heat generation and instability in the regulator REG3, and high voltage is applied to the relay RY1. To prevent this, if the voltage of the input terminal of the regulator REG2 is detected and the zener voltage is equal to or greater than the zener voltage, the transistor TR2 is conducted through the zener diode ZD1 and the resistor R5, and the high voltage and current of the second constant voltage unit 50 are applied. It is possible to stabilize the voltage risen at power-on to the same state as when power-off.

Accordingly, the output voltage of the regulator REG3 when the relay RY1 is turned off and the output voltage of the regulator REG2 when the relay RY1 is turned off is applied to the microcomputer 1 and the remote controller module 2 so that the microcomputer 1 regardless of the power supply on / off. ) And the remote control module 2 can be operated.

As described above, the present invention can reduce the production cost by supplying backup power to the microcomputer and the remote control module without using the sub transformer separately, and thus the weight of the set can be reduced, which is advantageous for the transport and drop test. .

Claims (1)

According to the control of the microcomputer 1, the power switching unit 20 for transmitting and cutting off the AC power through the power cord PC to the transformer T3 and the secondary side are separated into the main winding A and the sub winding B. To supply the main power by rectifying the output voltage of the main winding A and the transformer T3 for maintaining a low current and high voltage in the sub winding B by using a small current from the power switching unit 20 when the power is turned off. And a first constant voltage unit 40 for supplying the output voltage of the regulator REG2 to the microcomputer 1 and the remote controller module 2 when the power is turned on, and the output voltage of the negative winding B to rectify the voltage of the regulator REG3. The control diode ZD1 and the transistor TR2 according to the rectified voltage of the second constant voltage unit 50 and the first constant voltage unit 40, which supplies the output voltage to the microcomputer 1 and the remote controller module 2 as backup power. Rise prevention unit for bypassing the rectified voltage of the second constant voltage unit 50 that is switched on when the power is turned on ( 60. A backup power supply circuit when the power is turned off.