KR20010001587A - Supply apparatus of an emergency power - Google Patents

Abstract

PURPOSE: An emergency power supply is provided to reduce power consumption by supplying an emergency power when a normal power is not supplied and interrupting the emergency power when the normal power is supplied again. CONSTITUTION: A normal power supply sensor(10) detects the supply of a normal power. An emergency power supply sensor(20) detects the supply of an emergency power, and rectifies and smoothes the emergency power to generate a DC power. A timer(30) is operated by the DC power from the emergency power supply sensor(20) and generates a switching control signal when the normal power supply sensor(10) detected supply of the normal supply and a predetermined time passed. A power switching unit(40) interrupts the normal power from a load(50) and supplies the emergency power to the load when the normal power supply sensor(10) fails to detect the normal power, and interrupts the emergency power from the load and supplies the normal power to the load according to the switching control signal from the timer(30).

Description

Emergency apparatus of power supply

According to the present invention, when commercial power is not supplied due to an electrostatic discharge, emergency power supplied from a generator or the like is supplied to a load, and when commercial power is again transmitted, the emergency power is cut off to supply commercial power. It relates to an emergency power supply.

In general, when commercial power is not supplied due to a power failure, various loads including a fire hydrant, a water hydrant and an elevator cannot be operated.

Therefore, in general, apartment complexes, etc. are provided with a separate generator capable of generating emergency power, or when the emergency power is supplied through other lines from a utility company, and the commercial power is interrupted, the emergency power is supplied to fire hydrants, water hydrants and elevators. In addition, it is operating by supplying necessary loads such as emergency lights.

In addition, an emergency power supply device is provided to automatically switch between emergency power supply and commercial power supply according to the occurrence of power failure.

The conventional emergency power supply device includes two magnet switches and two timers for switching commercial power and emergency power, respectively, and the two timers selectively operate the two magnet switches depending on whether commercial power is supplied. The power is supplied to the load, that is, emergency power is automatically supplied to the load when a power failure of the commercial power is detected, the emergency power is cut off when the commercial power is transmitted again, and the commercial power is supplied again.

However, the above-mentioned conventional emergency power supply is a large size, expensive magnet switch and a timer using a large size of the product, and is used only in a large industrial building or a large building, which is very expensive as a general household. It is rarely used in apartments or apartments.

In addition, the conventional emergency power supply has a problem in that a large amount of power is consumed without the need to drive the magnet switch even when commercial power is supplied as selectively driving the magnet switch according to the supply of commercial power.

Accordingly, an object of the present invention is to supply an emergency power supply to the load when commercial power is not supplied, to cut off the emergency power when commercial power is supplied again, and to provide an emergency power supply of a simple configuration. It is.

Another object of the present invention is an emergency power supply that can prevent damage due to the phase shift of the power supplied at intervals when the power is not supplied when switching the commercial power and emergency power supply to the load by power failure and power supply To provide.

Still another object of the present invention is to provide an emergency power supply device in which power for supplying commercial power is not consumed when commercial power is supplied.

According to the emergency power supply of the present invention for achieving this object, a commercial power supply detection unit for detecting the supply of commercial power; An operating power supply / emergency power supply detecting unit for detecting a supply of emergency power and rectifying and smoothing the emergency power to generate a DC power; A timer that operates with a DC power supplied by the operation power supply / emergency power supply detection unit and generates a switching control signal when a predetermined time elapses after the commercial power supply detection unit detects supply of commercial power; And when the commercial power supply detecting unit does not detect commercial power, disconnects the commercial power supply line from the load according to the power output from the operation power supply / emergency power supply detecting unit, and supplies emergency power to the load. When the power supply detection unit detects the commercial power source, the emergency power supply is cut off and the commercial power supply unit for supplying the commercial power to the load according to the switching control signal output by the timer.

1 is a circuit diagram showing the overall configuration of the emergency power supply of the present invention.

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

10: commercial power supply detection unit 20: operation power supply / emergency power supply detection unit

30: timer 31: oscillating integrated device

40: power supply switching unit 41: first switching unit

42: second switching unit 50: load

Q4, Q5: transistors RY1 to RY4: first to fourth relays

R10, C8: time constant circuit

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

1 is a circuit diagram showing the overall configuration of the emergency power supply of the present invention.

As shown therein, a commercial power supply detection unit 10 for detecting a supply of commercial power and an operating power supply / emergency power supply detection unit for detecting a supply of emergency power and rectifying and smoothing the emergency power to generate a DC power. 20 and switching when the operating power supply / emergency power supply detecting unit 20 operates with a DC power supplied by the operating power supply / emergency power supply detecting unit 20 and the commercial power supply detecting unit 10 detects supply of commercial power. Supply line for commercial power according to the timer 30 for generating a control signal and the power output from the operation power supply / emergency power supply detection unit 20 when the commercial power supply detection unit 10 does not detect commercial power. After the furnace is cut off from the load 50, the emergency power is supplied to the load, and when the commercial power supply detection unit 10 detects commercial power, the emergency power is cut off and the tie And 30 is provided with a power supply switching unit 40 for supplying commercial power supply in accordance with the switching control signal and outputting to a load (50).

The commercial power supply detection unit 10 is connected to the light emitting element of the capacitor C1 and the photo coupler PC through the bridge diode BD1 and the resistor R1.

The operation power supply / emergency power supply detection unit 20 has a bridge diode BD2 connected to an emergency power supply, a resistor R2 and a capacitor C2 connected in parallel, and a bridge diode.

The output terminal of BD2 is connected to the ground capacitor C3 and is connected to the constant voltage diode ZD and the ground capacitor C4 through the resistor R3.

In the timer 30, the collector of the light receiving transistor of the photocoupler PC of the commercial power supply detection unit 10 is connected to the base of the transistor Q1 through the resistor R4, and the collector of the transistor Q1 is It is connected to the trigger terminal of the ground capacitor C5 and the oscillation integrated element 31. In addition, a connection point of the resistor R3, the constant voltage diode ZD, and the ground capacitor C4 of the operation power supply / emergency power supply detection unit 20 is connected to the oscillation integrated device 31, and the connection point is connected to the resistor R5. ) And a connection terminal of the resistor R6 and the diode D1 via the resistor R7 and the ground capacitor C7 through the resistor R6 and the diode D1. ) And the oscillation integrated element 31. In addition, the output terminal OUT of the oscillating integrated device 31 is connected to the base of the transistor Q2 through a resistor R8, and the operating power supply / emergency power supply detecting unit 20 is connected to the collector of the transistor Q2. The output terminal of the bridge diode BD2 and the connection point of the ground capacitor C3 are connected, and the connection point is connected to the base of the transistor Q3.

The power switching unit 40 operates according to the power output from the operation power supply / emergency power supply detection unit 20 when the commercial power supply detection unit 10 does not detect commercial power to switch emergency power. The first switching unit to supply the load 50 and cut off the emergency power when the commercial power supply detecting unit 10 detects commercial power.

41 and when the timer 30 does not output the switching control signal, the commercial power is cut off so that it is not supplied to the load 50 and the load 50 when the timer 30 outputs the switching control signal. A second switching unit 42 for supplying commercial power.

The first switching unit 41 includes a reverse diode D2 and a resistor in which the output terminal of the bridge diode BD2 and the connection point of the ground capacitor C3 of the operation power supply / emergency power supply detection unit 20 are connected in parallel. (R10), ground capacitor (C8), and resistor (R11) are sequentially connected to the base of transistor (Q4), and the collector of transistor (Q4) is reverse surge diode (D3) and relay (RY1) for surge removal. Is connected, the switch of the relay (RY1)

(RYS1) is connected in series with the relay (RY2) and the emergency power supply so that the switch of the relay (RY2)

RYS21 and RYS22 are connected between the emergency power supply and the load 50.

The second switching unit 42 has an output terminal of the bridge diode BD2 of the operation power supply / emergency power supply detection unit 20 and a connection point of the ground capacitor C3 via the resistor R12 to the timer 30. Is connected to the collector of the transistor Q3, and its connection point is connected to the base of the transistor Q5 through the resistor R13, and the collector of the transistor Q5 is connected to the reverse diode D4 for surge removal and the relay RY3. ) Is connected, and the switch RYS3 of the relay RY3 is connected in series to the relay RY4 and the emergency power supply so that the switch of the relay RY4 is connected.

RYS41 and RYS42 are connected between the emergency power supply and the load 50.

In the above, the switches RYS1 (RYS21, RYS22) and RYS3 are connected when the relays RY1 (RY2) and RY3 are driven, and the switches RYS41 and RYS42 are opened when the relay RY4 is driven. do.

In the emergency power supply device of the present invention configured as described above, the input commercial power is bridged by the bridge diode BD1 of the commercial power supply detection unit 10 and then the light emitting part of the photocoupler PC through the resistor R1. Is approved.

Therefore, when a commercial power source is input, the light emitting unit of the photocoupler PC operates to generate light, and the light receiving transistor of the photocoupler PC receives the generated light and turns it on.

When the commercial power source is not input, the light emitting unit of the photocoupler PC does not operate, and there is no light received by the light receiving transistor of the photocoupler PC, so that it is turned off.

On the other hand, the emergency power input when the emergency power is input is rectified via the bridge diode (BD2) via the resistor (R2) and the capacitor (C2) of the operating power supply / emergency power supply detection unit 20, After being smoothed by the condenser C3 and converted into DC power, it is supplied to the power switching unit 40 as an operating power source, and then converted into a constant voltage by the constant voltage diode ZD and the condenser C4. The oscillating integrated device of the timer 30

31 is supplied as an operating power source.

Here, when the commercial power is normally supplied and the phototransistor of the photocoupler (PC) is turned on, the operating power supply / emergency power supply detection unit 20 is output from the first switching unit 41 of the power switching unit 40. The power passing through the resistor R10 of the photo coupler (PC) flows to the ground through the phototransistor (PC), the low potential is applied to the base of the transistor Q4 of the first switching unit 41, the transistor Q4 is Is off.

Accordingly, since the relay RY1 is not driven and the switch RYS1 of the relay RY1 is opened, the relay RY2 is not driven, and the switches RYS21 and RYS22 of the relay RY2 are opened to the load 50. Emergency power will not be supplied.

As the light receiving transistor of the photocoupler PC is turned on, the transistor Q1 of the timer 30 is turned off, and the constant voltage output from the operation power supply / emergency power supply detection unit 20 is the resistors R6 and R7. And a high potential is continuously applied to the trigger terminal of the oscillating integrated device 31 by charging the capacitors C5 and C7 through the diode D1, so that the oscillating integrated device 31 continues to be reduced to the output terminal OUT. Output the potential.

Since the low potential output from the oscillating integrated device 31 is applied to the base of the transistor Q2, the transistor Q2 is turned off, and the transistor Q3 is turned on, so that the second switching unit of the power switching unit 40 ( The transistor Q5 of 42 is turned off.

Therefore, since the relay RY3 is not driven and the switch RYS3 of the relay RY3 is opened, and the relay RY4 is not driven and the switches RYS41 and RYS42 of the relay RY4 are continuously connected, the commercial power supply is relayed. It is supplied to the load 50 via switches RYS41 and RYS42 of RY4.

If the commercial power is not supplied due to a power failure in such a state, the light emitting unit of the photocoupler PC of the commercial power supply detection unit 10 does not operate in contrast to the above, and the light receiving transistor is turned off.

Then, the power output from the operation power supply / emergency power supply detection unit 20 is charged to the capacitor C8 through the resistor R10 of the first switching unit 41 and again the resistance R4 of the timer 30. Since the transistor Q1 is applied to the base of the transistor Q1, the transistor Q1 is turned on, and a low potential is applied to the trigger terminal of the oscillation integrated device 31 to continuously output a high potential to the output terminal OUT.

The high potential output by the oscillating integrated device 31 is applied to the base of the transistor Q2 and turned on so that the transistor Q3 is turned off.

Accordingly, the power output from the operation power supply / emergency power supply detection unit 20 is applied to the base of the transistor Q5 through the resistors R12 and R13 of the second switching unit 42 and is turned on so that the relay ( Since RY3 is driven and the switch RYS3 is connected, the relay RY4 is driven, and the switches RYS41 and RYS42 are opened to separate the supply line of the commercial power supply from the load 50.

In addition, while the power output from the operation power supply / emergency power supply detection unit 20 is charged to the capacitor C8 through the resistor R10 of the first switching unit 41, the transistor Q4 is again passed through the resistor R11. Transistor Q4 is turned on, relay RY1 is driven and switch RYS1 is connected, and relay RY2 is driven in accordance with connection of switch RYS1 to switch RYS21 and RYS22. The emergency power is supplied to the load 50 through the switches RYS21 and RYS22.

Here, when the emergency power is supplied immediately after the commercial power is shut off, if the phases of the commercial power and the emergency power coincide with each other, the power may be supplied without causing any damage to the load 50.

However, if the phases of the commercial power supply and the emergency power supply do not coincide, the overvoltage is supplied to the load at the moment of switching the power supply, and the overvoltage supplied is the highest when the phase difference between the commercial power supply and the emergency power supply is 180 °. The contacts 50 of the switches RYS21 and RYS22 and RYS41 and RYS42 of the relays RY2 and RY4 for switching the power supply are damaged as well as the load 50 is damaged due to overvoltage.

Therefore, in the present invention, the second switching unit 42 has a time constant circuit composed of a resistor R10 and a capacitor C8. When the commercial power is not supplied, the second switching unit 42 operates immediately. The power supply line is cut off, and the first switching unit 41 supplies the emergency power after the time constant time of the time constant circuit consisting of the resistor R10 and the capacitor C8 has elapsed, thereby allowing commercial power and emergency power. Even if the phases do not coincide with each other, the overvoltage is not supplied to the load 50.

When the commercial power is again transmitted while the emergency power is supplied to the load 50 by the power failure, the photocoupler PC of the commercial power supply detection unit 10 operates as described above, so that the light receiving transistor is turned on. The power charged in the capacitor C8 of the switching section 41 is discharged directly through the light receiving transistor of the photo coupler PC.

Then, a low potential is applied to the base of the transistor Q4 and it is turned off, and the relay RY1 is not driven so that the switch RYS1 is opened, so that the relay RY2 is not driven and the switches RYS21 and RYS22 are driven. It is opened so that the emergency power is not supplied to the load 50.

As the power of the capacitor C8 is discharged, the low potential is applied to the base of the transistor Q1 of the timer 30 so that it is turned off so that the power is charged to the capacitor C5 again. The oscillating integrated device 31 is triggered by being applied to the trigger terminal of the oscillator, and when the predetermined time elapses, the oscillating integrated device 31 outputs a low potential to the output terminal OUT.

Then, since the transistor Q2 is turned off and the transistor Q3 is turned on, the transistor Q5 of the second switching section 42 is turned off so that the relay RY3 is not driven and the switch RYS3 is opened. In response to the opening of RYS3, the relay RY4 is not driven so that the switches RYS41 and RYS42 are connected, and a commercial power source is supplied to the load 50.

As described above, the present invention supplies emergency power to a load when commercial power is not supplied, cuts off the emergency power when commercial power is supplied again, and supplies commercial power. When switching to the emergency power supply to the load, it is possible to prevent damage due to the phase shift of the supplied power at intervals when the power is not supplied, and when the commercial power is supplied, power for supplying the commercial power is consumed. Of course, since the circuit configuration is simple, it can be manufactured and sold at low cost.

Claims (4)

A commercial power supply detecting unit detecting a supply of commercial power; An operation power supply / emergency power supply detection unit for rectifying and smoothing the emergency power to generate a DC power; A timer that operates with a DC power supplied by the operation power supply / emergency power supply detection unit and generates a switching control signal when a predetermined time elapses after the commercial power supply detection unit detects supply of commercial power; And When the commercial power supply detection unit does not detect commercial power, the commercial power supply / emergency power supply detection unit disconnects the commercial power supply line from the load according to the power output from the load, supplies emergency power to the load, and supplies the commercial power. Emergency power supply characterized in that the supply detection unit is configured to shut off the emergency power when detecting the commercial power, and to supply the commercial power to the load in accordance with the switching control signal output by the timer. The apparatus of claim 1, wherein the power switching unit; When the commercial power supply detection unit does not detect the commercial power supply, the operation power supply / emergency power supply detection unit operates according to the power output by switching the emergency power supply to the load and the commercial power supply detection unit detects the commercial power supply. A first switching unit to cut off emergency power when And The second switching unit is configured as a second switching unit for blocking the commercial power when the timer does not output the switching control signal so that the commercial power is supplied to the load when the timer outputs the switching control signal. Emergency power supply characterized in that. The method of claim 2, wherein the first switching unit; A time constant circuit for delaying the output power of the operation power supply / emergency power supply detection unit and releasing the delay time when the commercial power supply detection unit detects supply of commercial power; A transistor turned on / off when a delay time set in the time constant circuit elapses; A first relay driven / stopped according to on / off of the transistor; And Emergency power supply, characterized in that configured as a second relay for supplying / blocking the emergency power to the load while driving / stopping together in accordance with the driving / stop of the first relay. The method of claim 2, wherein the second switching unit; A transistor turned on / off according to the output signal of the timer; A third relay driven / stopped according to on / off of the transistor; And Emergency power supply, characterized in that consisting of a fourth relay for supplying the commercial power to the load and the load while being driven / stopped together in accordance with the driving / stop of the third relay.