KR0146324B1 - Interruption of electric power switching circuit for portable type uninterrupted power supply - Google Patents

Abstract

1. Fields to which the invention described in the claims belong

The present invention relates to an electrostatic transfer circuit of an uninterruptible power supply (hereinafter referred to as a UPS), and in particular, a simple uninterruptible power supply capable of switching and restoring a power supply from a battery during an AC interruption or a recovery in a simple UPS having a long turn-on delay time. It relates to an electrostatic transfer circuit of a device.

2. The technical problem to be solved by the invention

In the uninterruptible power supply, it provides stable power even at the moment of battery change during AC interruption, and also protects against short-circuits at the output stage while supplying stable power even when the battery is restored from AC to AC voltage. To provide an uninterruptible power supply.

3. Summary of Solution to Invention

The DC power output unit 2, the battery charging unit 3, and the AC power monitoring unit 6 are connected from the AC input terminal 1, and the battery 4 and the battery over-discharge monitoring unit 5 are connected from the battery charging unit 3. In the electrostatic transfer circuit in which the switch unit 7 is connected between the DC power output unit 3 and the battery charging unit 3 when the power supply unit 3 is connected, the DC power supply unit according to the electrostatic signal of the AC power monitoring unit 4. The switch unit 7 is connected to the DC output voltage monitoring unit 201 for monitoring the DC output voltage of the output unit 2 and the battery charging unit 3 and the power failure or recovery signal of the DC output voltage monitoring unit 201. Electrostatic transfer circuit of the simple uninterruptible power supply, characterized in that the switch control unit 202 for controlling the DC charging or supply of the battery by operating

4. Important uses of the invention

Electrostatic Transfer of Simple Uninterruptible Power Supply

Description

Blackout Switching Circuit of Simple Uninterruptible Power Supply

1 is a diagram of an electrostatic transfer circuit of a conventional uninterruptible power supply.

2 is a diagram of an electrostatic transfer circuit of a simple uninterruptible power supply according to an embodiment of the present invention.

3 is a circuit diagram in which the parts of FIG. 2 are embodied.

The present invention relates to an electrostatic transfer circuit of an uninterruptible power supply (hereinafter, referred to as a UPS), and in particular, a simple UPS having a long turn-on delay time can be switched and restored so that power is supplied from a battery during AC interruption and recovery. The present invention relates to an electrostatic transfer circuit of a simple uninterruptible power supply.

In general, the uninterruptible power supply is intended to remove the obstacles to the normal operation of the system by supplying the charged power of the battery when the supply of AC power is suddenly cut off due to a power failure.

A conventional circuit diagram for this is shown in FIG.

In the normal state, when power is input to the AC input terminal 1, the DC power is output through the DC power output unit 2, and the battery 4 is charged by the battery charger 3.

When the power supply is cut off from the AC input terminal 1 while the battery 4 is fully charged, the AC power monitoring unit 6 detects this and operates the switch unit 7 to operate the DC of the battery 4. Allow power to be supplied.

When the AC power is input to the AC input terminal 1 while the DC power is being supplied to the battery 4, the AC power monitoring unit 6 detects this and detects the switch unit 7. By operation, the supply of DC power to the DC power output unit 2 by the battery 4 is cut off, and the battery 4 enters a charged state. However, when the battery 4 is continuously supplied with the DC output, the battery over-discharge monitoring unit 5 operates the switch unit 7 when the battery 4 reaches the over-discharge stop voltage. Shut off the DC supply. In the state where the DC output is supplied by the battery 4 and the turn-on delay time of the DC power output unit 2 is long, the AC power monitoring unit 6 of the switch unit 7 When the DC power supply by the battery 4 is interrupted by the operation, the DC output power is supplied to the power receiving end in an unstable state.

However, in order to solve this problem, it is inconvenient to add the functions of the following items.

end. The DC power output unit 3 shortens the turn-on delay time or

I. A predetermined delay should be given when voltage is applied according to the AC restoration of the AC power monitoring unit 6.

Accordingly, an object of the present invention is to provide a stable power supply even when the battery is switched during AC interruption in a simple uninterruptible power supply, and also to supply a stable power even when the AC voltage is restored and recovers from the battery to AC. An uninterruptible power supply that is protected against

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

2 is a block diagram according to the present invention, which includes a DC power output unit 2 for outputting DC-powered DC power from the AC input terminal 1 and a battery charging unit 3 for charging power to the battery 4. And an AC power monitoring unit 6 for monitoring input of AC power.

The battery 4 is connected from the battery charging unit 3, and the battery 4 is supplied with power of the battery 4 when the AC power supply is turned off, thereby discharging the battery 4. Battery over discharge monitoring unit (5) is connected to the battery (4) to monitor the over-discharge state of the power supply.

A switch unit 7 for selectively selecting a DC output of the DC power output unit 2 or a DC output of the battery 4 is connected, and the switch unit 7 is controlled by the switch controller 202. The switch control unit 202 operates according to the output of the DC output voltage monitoring unit 201. The DC output voltage monitoring unit 201 receives the DC of the DC power output unit 2 and the output of the battery 4, and from the outputs of the AC power monitoring unit 6 and the battery over-discharge prevention unit 5. The output state of the DC is monitored and provided to the switch controller 202 according to the monitoring result.

That is, the DC output voltage monitoring unit 201 monitors the DC output voltage of the DC power output unit 2 and the battery charging unit 3 according to the power failure signal of the AC power monitoring unit 6, and controls the switch. The unit 202 is configured to control the power supply charged in the battery 4 by operating the switch unit 7 in response to a power failure or voltage restoration of the DC output voltage monitoring unit 201.

Therefore, according to the operation of the present invention according to FIG. 2, when power is applied to the AC input terminal 1, the DC power is output through the DC power output unit 2, and at the same time, the battery is charged by the battery charging unit 3. 4) charging is performed. When the input of the AC input terminal 1 is cut off while only the battery 4 is charged, the DC output voltage monitoring unit 201 monitors the DC output voltage when the power failure signal is applied to the DC output voltage monitoring unit 201. The unit 201 supplies an electrostatic signal to the switch control unit 202, and the switch control unit 202 operates the switch unit 7 according to the input of the electrostatic signal to select a DC output from the battery 4 and supply it. To control.

When the AC power is restored to the AC input terminal (1) while the DC output is supplied from the battery (4), the AC power monitoring unit (6) returns the restored state voltage to the DC output voltage monitoring unit. To 201. At this time, after the node 9 reaches the normal voltage by the DC power output unit 2, the DC output voltage monitoring unit 201 gives a restoration voltage signal to the switch control 202 to operate the switch unit 7. The supply of the DC output power which was being supplied by the battery 4 is interrupted | blocked, and the output of the said DC power output part 2 is supplied normally.

FIG. 3 is a detailed circuit diagram of FIG. 2 according to the present invention. As shown in FIG. 2, parts except for the DC output voltage monitoring unit 201 and the switch control unit 202 are similar to those of the conventional components of FIG. However, it can be seen that the mutual configuration of these embodiments is separate.

In addition, in FIG. 3, the battery (BATT) 4 next to the battery charging unit 3 and the battery (BATT) 4 of the battery over-discharge monitoring unit 5 are the same and are shown separately for convenience of drawing in the drawing. will be.

Therefore, the DC output voltage detection unit 201 and the switch control unit 202 directly related to the present invention will be described in detail with respect to its configuration and operation example. The DC output voltage detection unit 201 is an AC power monitoring unit 6. Photocoupler IC3 driven from the AC power monitoring result output value of the operational amplifier IC2 and photocoupler driven according to the level of the DC output node 9 of the DC power output unit 2; IC5), an SCR (IC4) connected to an emitter of a photo transistor of the photocoupler (IC3) and an emitter of a port transistor of the photocoupler (IC5) connected to a gate to perform a self-holding operation; Zener diode (IC6) connected to the cathode of the light emitting diode of the photocoupler (IC5) and the level value appearing at the DC output node (9) is output at a constant voltage through the resistors (R16, R17), and the battery over-discharge monitoring The over-discharge detection signal of the section 5 or the output voltage of the DC output voltage monitoring unit 201 It consists of a resistor (R18, R19), which to facilitate the delivery of the signal.

The switch controller 202 is configured to receive and drive the outputs of the battery over-discharge monitoring unit 5 and the DC output voltage monitoring unit 201 through resistors R18 and R19, and the transistor Q1. Transistors Q2 for controlling the DC power supply of the DC power output unit 2 to pass through the output of the power supply; and the directionality of the current except for the transistor Q2 by the output signal of the transistor Q1. Diodes D2-D4 for controlling and transistors Q4 for controlling relay driving for switching of the switch unit 7 by the output of the diode D3.

Looking at the operation relationship of the present invention in detail with reference to FIG.

[AC power is normal input state]

When the AC input to the AC input terminal 1 is normal, the DC power output unit 2 operates the battery charging unit 3 normally. The output terminal of the operational amplifier IC2 when the voltage divided by the resistors R10 and R11 to the inverting terminal (-) of the operational amplifier IC2 of the AC power supply monitoring unit 6 is higher than the voltage of the reference voltage non-inverting terminal (+). Becomes low and the transistor Q1 of the switch control unit 202 is turned on to operate the photocoupler IC3 so that the collector becomes low. Therefore, the transistors Q2 and Q4 are turned off to turn off the transistor Q3. The switch is turned off by turning off the relay RL1, and the DC output of the DC power output unit 2 is continuously supplied, the DC output power supply by the battery 4 is cut off, and the battery charging unit 3 (4) will only charge.

[Power Off (Power Outage)]

When AC power is cut off under normal AC power input, if the voltage at the inverting terminal (-) of the associating amplifier (IC2) of the AC power monitoring unit 4 is lower than the reference voltage of the non-inverting terminal (+), the operational amplifier (IC2) The output becomes high. At this time, the photocoupler IC3 is turned off to cut off the source power supplied to the base terminal of the transistor Q1. At this time, the transistor Q1 is turned off and at the same time, the transistor Q2 is turned on to turn the base of the transistor Q3 low so that the DC voltage charged to the battery 4 is first supplied through the transistor Q3. . When the transistor Q1 is off, the current for operating the transistor Q4 to drive the relay RL1 is charged to the capacitor C6 through the resistor R20 and then operates the transistor Q4 to operate the relay RL1. Is driven secondly so that the DC output voltage is directly supplied by the battery (4). By operating the transistor Q3 first, the voltage difference between the contacts of the relay RL1 is reduced to prevent sparking between the contacts, thereby protecting the contacts and compensating the Vcc drop voltage of the transistor Q3 to the contacts of the relay RL1. can do.

[Recovering Power Failure (Restore AC Power)]

When AC power is input in the power-off state, the output terminal of the operational amplifier IC2 of the AC power monitoring unit 6 goes low to operate the photocoupler IC3, but if the voltage of the node 9 does not reach the normal voltage. The photocoupler IC5 is turned off and the SCR IC4 is turned off to have no effect on the relay RL1 and the transistor Q3. However, when time passes, the DC power output unit 2 outputs the normal voltage, and when the voltage of the node 9 becomes the normal voltage, the photocoupler IC5 is turned on and the SCR IC4 is turned on to turn on the transistor Q1. While supplying the source voltage to the base to turn on the transistor Q1, the transistor Q4 is turned off, the relay RL1 is first turned off, and then the power charged in the capacitor C6 is discharged through the resistor R25. The transistor Q2 is kept on for a while, and when discharge is completed, the transistor Q2 is turned off and the transistor Q3 is turned off to cut off the DC output voltage supply by the battery 4.

[When DC output stage short-circuited]

If the DC output stage is shorted in the normal state, the voltage of the node 9 is lowered and the photo coupler IC5 is turned off, but the photo coupler IC3 remains on and the SCR (IC4) is turned on. Even if the gate power supply of the SCR (IC4) is removed due to the off of the IC5, the SCR (IC4) remains on (use of the characteristics of the SCR), so it is not switched to the battery 4 and no overcurrent flows.

As described above, even a simple uninterruptible power supply with a long turn-on delay time can be switched and restored to supply power to the battery, and the relay can have a difference in operating time to extend the life of the relay. .

Claims (1)

The DC power output unit 2, the battery charging unit 3, and the AC power monitoring unit 6 are connected from the AC input terminal 1, and the battery 4 and the battery over-discharge monitoring unit are connected from the battery charging unit 3. In the electrostatic transfer circuit (5) is connected, the switch unit 7 having a transistor (Q3) is connected between the DC power output unit (2) and the battery charging unit (3), the AC power monitoring unit ( The photocoupler IC3 driven by the AC power monitoring result output value of the operational amplifier IC2 of 6) and the photocoupler driven according to the level of the DC output node 9 of the DC power output unit 2. (IC5), an SCR (IC4) connected to an emitter of a photo transistor of the photocoupler (IC3) and an emitter of a photo transistor of the photo coupler (IC5) to a gate to perform a self-holding operation; The level value, which is connected to the cathode of the light emitting diode of the photocoupler IC5 and appears on the DC output node 9, is provided through the resistors R16 and R17. Zener diode IC6 outputs a constant voltage, a resistor for facilitating the transfer of the DC discharge voltage detection signal of the DC discharge voltage monitoring unit 201 and the over discharge state of the battery over-discharge monitoring unit 5 ( Transistor Q1 driven through R18 and R19 and controlled by transistor Q3 of the switch unit 7 by the output of the transistor Q1 to control the supply of power to the battery 4. The transistor Q2, the diodes D2-D4 for controlling the transistor Q2 and the direction of current flow by the output signal of the transistor Q1, and the outputs from the diode D3. Electrostatic switching circuit of the simple type uninterruptible power supply, characterized in that it comprises a transistor (Q4) for controlling the drive of the relay (RL1) for switching of the switch unit 7 so that the power of the battery 4 is directly applied