KR920007739Y1 - Circuit charging and discharging battery with low electric power - Google Patents

Abstract

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Description

Low power consumption battery charge and discharge circuit

1 is a conventional circuit diagram.

2 is a circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

10: rectifier 20: regulator

30: constant voltage output unit 40: charging battery

50: end voltage detection unit 60: floor discharge path control unit

T1: transformer D1-D4: diode

D6: Zener Diode R1-R3: Resistance

C1: capacitor

The present invention relates to a battery charging and discharging circuit, and more particularly to a low power consumption battery charging and discharging circuit that can reduce the power consumption and extend the life of the battery using a low power device.

In the conventional battery total discharge circuit, as shown in FIG. 1, the AC voltage is inputted and the primary voltage is induced to the secondary side by the transformer Tl. The rectifier 1 for inputting the induced power to the secondary side of the transformer Tl rectifies and outputs a stable current voltage. The regulator 2 which inputs the voltage output from the rectifier 1 outputs a desired constant voltage.

The power output from the regulator 2 is applied to the supply power Vcc of the load (microcomputer, electronic product, etc.) through the diode D1.

In addition, the power output from the regulator 2 is input to the battery charging current unit 3 to output a constant current. At this time, the battery charging current unit 3 controls and outputs a constant current even when an overcurrent is input. .

The battery voltage detector 4, which inputs the power output from the battery charging current unit 3, outputs a high signal through the line b and is applied to the base of the transistor Q1. As a result, the transistor Q1 is turned on to drive the relay RY1. When the relay RY1 is driven, the power output from the battery charging current unit 3 is applied to the charging battery BA1 to perform charging. At this time, the charging battery BA1 is discharged at the same time as charging, but the voltage output from the battery charging current unit 3 is always high, so that the voltage of the charging battery BA1 is hardly consumed. As described above, when the battery is charged with a constant voltage current by the output of the battery charging current unit 3 and the power is cut off due to power failure or disconnection of the line, the power charged in the charging battery BA1 is applied to the power detector 4 so as to supply the line. Through (a) is applied to the supply power supply (Vcc) of the load (microcomputer, electronics, etc.). At this time, when the discharge voltage of the battery BA1 falls below a predetermined voltage, it is determined as a termination voltage, and the voltage detector 4 outputs a low signal through the line b.

The low signal output from the voltage detector 4 is applied to the base of the transistor Q1 to turn off the transistor Q1. When the transistor Q1 is turned off, the relay RY1 is turned off to block the discharge of the charging battery BA1. Diodes D1-D3 not described here are for backflow prevention.

The conventional circuit as shown in FIG. 1 has a problem in that the power consumption is increased and the life of the charging battery is shortened because the supply power is supplied by driving the relay using the voltage of the charging battery at the time of disconnection or power failure of the line.

Therefore, an object of the present invention is to provide a low-power battery charge and discharge circuit that can reduce the power consumption of the battery by supplying a power supply using a low power FET and diode.

Another object of the present invention is to provide a low-power battery charge and discharge circuit that can extend the life of the battery by stopping the discharge of the charge battery by detecting the end voltage using a low power.

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

2 is a circuit diagram according to the present invention, a transformer (T1) for inputting an AC power supply to lower the voltage to be induced to the secondary side, and a rectifying unit (10) for rectifying the voltage induced to the secondary side of the transformer (T1) and A regulator 20 for outputting a predetermined constant voltage by inputting the voltage rectified by the rectifier 10 and a voltage output from the regulator 20 to input a constant voltage to prevent charging of an overvoltage or an overcurrent. A constant voltage output unit 30 to be dropped, a charging battery 40 for charging and discharging the output voltage of the constant voltage output unit 30, and a charging voltage of the charging battery 40 are input to detect and terminate a termination voltage. Charge and discharge path control unit for controlling the charge and discharge path of the battery 40 by inputting the end voltage detection unit 50 for outputting a cutoff control signal, the output voltage of the regulator 20 and the end voltage detection unit 50 ( 60).

In the configuration, the constant voltage output unit 30 includes a diode D3-D4 and a resistor R2 connected in series between the output terminal of the regulator 20 and the charging battery 40, and the termination voltage detection unit 50. The output power of the regulator 20 prevents the reverse flow and forms a discharge path of the charging voltage of the charging battery 40 to output the power supply (Vcc) during power failure, the diode (D5) and the diode (D5) The cathode of the diode (D6) is connected to the anode of the () is connected to the zener diode (D6) for detecting the termination voltage when the charged voltage of the charging battery 40 is discharged, and the anode of the zener diode (D6) When charging the charging battery 40 is composed of a resistor (R3) for controlling the charging current flowing through the zener diode (D6), and a diode (D2) connected to the resistor (R3) to prevent backflow , Charge / discharge path control unit 60 of the regulator (2) An anode is connected to an output terminal to prevent a backflow, and a diode (D1) connected between the cathode of the diode (D1) and ground and a gate of the FET (Q1) for switching and controlling the charge / discharge passage ( A capacitor C1 connected between a gate and a ground to suppress noise of the FET Q1, and a capacitor C1 connected between a gate of the FET Q1 and a ground to prevent the malfunction of the FET Q1. It consists of a resistor (R1) for controlling the current input to the gate of.

One embodiment of the present invention based on the above configuration will be described with reference to FIG.

When the AC source is input to the rectifier 10 through the transformer T1, the rectifier 110 is full-wave rectified and output. The regulator 20 for inputting the full-wave rectified voltage in the rectifier 10 outputs a predetermined voltage to be used. The constant voltage output from the regulator 20 is applied to the supply power supply (Vcc) of the load and is also output as a constant voltage through the diode (D3-D4) resistor (R2). In addition, the voltage output from the regulator 20 is applied to the gate of the FET Q1 through the diode D1.

As a result, since the FET Q1 is turned on to form a charge path, the voltage output through the diodes D3-D4 and the resistor R2 starts to be charged in the charging battery 40. In this case, the diodes D3-D4 are for preventing the charging battery 40 from being charged with overvoltage and overcurrent, and the resistor R2 is for limiting the current for controlling the charging current of the battery 40. In addition, since the FET Q1 is turned on at a low current, a resistor R1 is used to limit the bias current, and the capacitance C1 for noise blocking is performed to prevent the FET Q1 from malfunctioning due to noise. ) Was used. When the charging battery 40 starts to be charged, the total voltage is charged and discharged through the diode D5 at the same time, but when the constant voltage is output from the regulator 20, the constant voltage power is charged to the charging battery 40. Since the voltage is always higher than the voltage, the voltage of the charging battery 40 is not consumed.

As described above, when AC power is cut off due to a power failure or disconnection of the line while charging the regulator 20, the voltage charged in the charging battery 40 is discharged through the diode D5 to supply the load to the load (Vcc). Will be supplied. At this time, when the charging voltage of the charging battery 40 is discharged and falls below the final voltage, the zener diode D6 detects the same. Is small. When the discharge voltage of the charging battery 40 is greater than the value of the zener diode D6, the zener diode D6 is turned on and applied to the gate of the FET Q1 through the resistor R3 and the diode D2. The FET Q1 is turned on to form a discharge passage of the charging battery 40. However, when the discharge voltage of the layer battery 40 is lower than the value of the zener diode D6, the zener diode D6 is turned off to turn off the FET Q1, thereby blocking the discharge path of the charging battery 40. do.

Therefore, as the current value for turning on the zener diode D6 decreases, power consumption may be reduced, thereby extending the life of the battery. Here, the diode D2 is a protection diode for preventing the constant voltage power output from the regulator 20 from flowing in the reverse direction, and the diode D1 is the charging battery output through the zener diode D6 and the resistor R3. It is a protection diode for preventing the voltage at 40 from flowing back. In addition, diode D5 is a low drop diode that is different from the normal switching diodes. When the diode is turned on, a voltage drop of 0.6-0.7V occurs. However, the low drop diode D5 generates a voltage drop of 0.2V when turned on. The resistor R3 is used as a load resistor for preventing the current flowing through the zener diode D6 when the charging battery 40 is charged.

As described above, power is supplied using FETs and diodes driven at low power, the terminal voltage is detected, and the battery power is reduced by reducing power consumption of the battery, thereby extending the battery life.

Claims (4)

In a low power consumption type battery charge / discharge circuit having a transformer Tl, a rectifier 10, and a regulator 20, a voltage output from the regulator 20 is input to prevent charging of an overvoltage or an overcurrent. A final voltage is detected by inputting a constant voltage output unit 30 for dropping the constant voltage, a charging battery 40 for charging and discharging the output voltage of the constant voltage output unit 30, and a charging voltage of the charging battery 40. Charge / discharge to control the charge / discharge path of the battery 40 by inputting an end voltage detector 50 for outputting a discharge interruption control signal, and output voltages of the regulator 20 and the end voltage detector 50. Low power consumption battery charge and discharge circuit, characterized in that consisting of a pass control unit (60). The terminal voltage detecting unit 50 prevents the reverse flow of the output voltage of the regulator 20 and forms a discharge passage of the charging voltage of the charging battery 40 to supply the power supply Vcc at the time of power failure. A diode D5 for supplying, a zener diode D6 for detecting a termination voltage when the charged voltage of the charging battery 40 is discharged, and the zener diode when charging the charging battery 40 ( A low power consumption battery charging circuit comprising a resistor (R3) for suppressing the charging current flowing through the D6), and a diode (D2) for preventing the reverse flow of the constant voltage power supply of the regulator (20). The low-power type battery charge / discharge circuit according to claim 1, wherein the constant voltage output unit (30) is connected between the output terminal of the regulator (20) and the + terminal of the charging battery (40). According to claim 1, Charge and discharge path control unit 60 is a diode (D1) for preventing the charging power of the charging battery 40 is reversed, and the power or end voltage detection unit 50 output through the diode (D1) FET (Q1) for switching the charge and discharge path by inputting the output power of the power supply) and the output power of the output power of the terminal voltage detection unit 50 or the power output through the diode (D1) to input the To limit the bias voltage to the FET Q1 by inputting the capacitor (C1) for removing noise and the output power of the terminal voltage detection unit 50 or the power output through the diode (D1) to prevent the noise ( Low power consumption battery charging and discharging circuit, characterized in that consisting of R1).