KR930001675Y1 - Power circuit - Google Patents

Abstract

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Description

Battery backup circuit when the system voltage drops

1 is a battery backup circuit when the specified voltage falls of the present invention system.

2 is a control waveform diagram of a battery backup circuit of the present invention.

* Explanation of symbols for main parts of the drawings

10: latch voltage detection unit 20: output attenuation detection unit

30: latch control unit 40: latch voltage release unit

50: relay drive 1: AC / DC converter

2: negative phase voltage detection unit R1-R20: resistance

D1-D4: Diode ZD1-ZD4: Zener Diode

BE: Battery RL1: Relay

RS1: Relay switch Q1-Q5: Transistor

CP1: comparator

The present invention relates to a battery back-up circuit of a negative (-) system. In particular, a battery backup circuit of a system that supplies a power above a specified value to the system at all times even when the DC power of the system is lowered. It is about.

In the related art, when a backup of a battery power supply occurs, instantaneous power drop occurs and relay contact failure occurs, thereby degrading safety of the system.

The present invention, in view of such a conventional combination, detects the DC power state of the system and drives a relay to create a battery backup circuit when the specified voltage drop of the system to perform a safe battery backup function, When described in detail by the accompanying drawings as follows.

1 is a battery backup circuit diagram of a specified voltage drop of the present invention system, as shown here, a system circuit composed of a negative phase voltage detection unit (2) for detecting a negative phase voltage of the AC power input (AC) The output of the AC / DC converter 1 drives the transistor Q4 through the bias resistors R11, R15, R16, and Zener diode ZD3, so that The output attenuation detection unit 20 and the output of the AC / DC converter 1, which senses the voltage, are sensed through the transistors Q6 through the bias resistors R17-R20, the zener diode ZD4, and the power drop prevention diode D4. The latch voltage sensing unit 10 for driving and sensing the latch voltage and the output of the AC / DC / converter 1 are input side of the comparator CP1 through the distribution resistors R8-R10, R12 and R13. Set the voltage level to (-) (+), apply the voltage level to the output side and the non-inverting (+) side of the comparator CP1 through the distribution resistors R4, R5 and diode D1, A latch control unit 30 which has an output of the time limiting attenuation detection unit 20 applied to the inverting (-) side of the comparator CP1 and is compared with a reference power supply on the non-inverting (+) side to perform latch control; The output of the latch control unit 30 is connected to each of the bias resistors R1-R3 to control the relay RL1 through the transistors Q1 and Q2 which are driven back to each other and then control the relay switch RS1. The output of the AC / DC converter 1, which has passed through the relay drive 50 and the distribution resistors R8, R14, and the control diode AD2, controls the backup of the battery BE power supply. After detecting the state of the latch voltage sensing unit 10 and the negative phase voltage sensing unit 2 through D3, the transistor Q3 is connected through the resistors R7 and R6 and the control diode ZD1. And a latch voltage release section 40 for releasing the latch state of the latch control section 30. The resistors R16, R17 and R15 are the same.It is set to the capacitance, and the capacitance of the zener diode ZD4 is set larger than the zener diode ZD3.

FIG. 2 is a control waveform diagram of the battery backup circuit of the present invention. As shown in the drawing, the backup timing of the battery BE is shown according to the AC / DC output, the latch voltage of the negative polarity voltage, and the attenuation detection voltage.

Referring to the effect of the present invention configured as described above are as follows.

After the input AC power is turned off, when the output of the AC / DC converter 1 rises to the ground GND level with ripple as shown in FIG. When the normal AC / DC output is attenuated to point a, a high potential is applied to the base side of transistor Q5 through resistors R17 and R18 to turn off transistor Q5 and to distribute resistor R8 and R14. Since the output of the AC / DC converter 1 passing through) is distributed to the diode D2 and the resistor R20, a low potential is applied to the base side of the transistor Q3 to turn off the transistor Q2.

At this time, the output of the AC / DC converter 1 sets the level at the input side (-) (+) of the comparator CP1 through each of the distribution resistors R8, R9, 10, R12, and R13. In response to the zener diode ZD3 passing through the distribution resistors R15 and R16, a low potential is applied to the base side of the transistor Q4 to turn on the transistor Q4, and then through the distribution resistor R11, a comparator CP1. Since a power supply higher than the non-inverting (+) side is applied to the inverting (−) input side of the low side, a low potential is applied to the output side of the comparator CP1 and applied to the base side of the transistor Q2 through the bias resistor R3.

At the same time, after the transistor Q2 is turned on, a high potential is applied to the base side of the transistor Q1 through the distribution resistors R1 and R2 so that the transistor RL1 is driven as the transistor Q1 is turned off. Since the relay switch RS1 is still off, the power of the battery RE is not backed up.

As shown in FIG. 2, when the AC / DC voltage continues to drop to reach the attenuation detection voltage b, the output of the AC / DC converter 1 passes through the transistors Q4 through the bias resistors R15 and R16. The non-inverting (+) side voltage of the comparator CP1 is higher than the half-side power supply of the comparator CP1 as the high potential is applied to the base side of the transistor Q4 to turn off the transistor Q4. A high potential in the ground state is generated to turn off the transistor Q2.

At this time, a low potential is applied to the base side of the transistor Q1 through the bias resistors R1 and R2 to turn the transistor Q1 on and then turn on the relay RL1 to turn on the relay switch RS1. This backs up the battery (BE) power to the system load.

Here, the output of the comparator CP1 at the ground (GND) level is applied to the non-inverting (+) side of the comparator CP1 through the distribution resistor R5 and the diode D1 to stabilize the reference power supply, and the transistor Q3 ) Is turned off, so even when transistor Q4 is turned on, comparator CP1 continues to output the high potential of ground (GND) due to the increased reference power on the non-inverting (+) side, thereby backing up the battery (BE) power supply. The function continues to run.

On the other hand, when the input alternating current (AC) power is turned on and descends from point c and reaches point e as shown in FIG. 2, the transistor Q4 is turned on so that the comparative power supply of the inverting (-) side of the comparator CP1 Is raised but the backup status of the battery is still maintained.

When the point d is reached, the output of the AC / DC converter 1 is applied to the base side of the transistor Q5 as the normal negative voltage is applied to the load of the system through the resistor R17 and the zener diode ZD4. The potential is applied to turn on the transistor Q5 and then applied through the distribution resistors R19 and R20.

At this time, the zener voltage of the zener diode ZD2 turns on the transistor Q3 by applying a high potential to the base side of the transistor Q3 through the distribution resistors R14, R7 and R6 and the zener diode ZD1. As the output of the comparator CP1 flows through the transistor Q3, the inverting (-) side comparison power supply of the comparator CP1 is higher than the non-inverting (+) side reference power source, so that the transistor Q2 is turned on and thus the transistor Q1 Turn off).

At the same time, the driving of the relay RL1 is cut off and the relay switch RS1 is turned off to cut off the backup function of the battery BE. At this time, the output of the AC / DC converter 1 is supplied to the load of the load.

In addition, the power of the load is not cut off by the diode D4 connected to the relay switch RS1.

As described in detail above, the present invention eliminates instantaneous powder drop and relay contact defects generated during battery backup, thereby providing a high reliability and stable battery backup function.

Claims (1)

In the system circuit composed of the negative phase voltage sensing unit 2, the output of the AC / DC converter 1 is connected to the transistor Q5 through the resistors R17-R20, the zener diode ZD1, and the diode D4. An output reduction that senses an output attenuation voltage by driving the transistor Q4 through a latch voltage sensing unit 10 that drives the drive to sense a latch voltage, and resistors R15, R16, R11, and Zener diode ZD3. The input unit (-) (+) voltage level of the comparator CP1 is set through the sensing unit 20 and the resistors R8-R10, R12, and R13, and the resistors R4, R5, and diode D1. Set the input (-) (+) voltage level of the comparator CP1 through, and the output side and the non-inverting (+) side voltage of the comparator CP1 through the resistors R4, R5 and diode D1. After setting the level, the output of the output attenuation detecting unit 20 is applied to the inverting (-) side of the comparator CP1 through the resistor R11 and then compared with the non-inverting (+) side reference power supply to control the latch. A latch control unit 30 for performing a function, The output of the tooth control unit 30 is connected to the resistors R1-R3 to control the relay RL1 through the transistors Q1 and Q1 which are driven backwards, and then the relay switch RS1 to control the system load. The output of the AC / DC converter 1 through the relay drive 50 and the zener diode ZD2 and the resistor R14 that controls the backup function of the battery BE is controlled through the diode D2 and D3. After sensing the state of the latch voltage sensing unit 10 and the negative phase voltage sensing unit 2, the transistor Q3 is driven through the resistors R6 and R7 and the zener diode ZD3, and the The battery backup circuit when the specified voltage falls in the system, characterized in that the latch voltage release unit 40, which releases the latch state of the latch control unit 30.