KR200199085Y1 - Automatic power control device - Google Patents

Abstract

The automatic power supply control device has a rechargeable battery, a voltage level circuit, a power supply circuit, and first and second optical control circuits.

The voltage level circuit includes a display lamp, a switch connected in parallel to the display lamp, two resistors respectively connected to the terminal of the switch, and one or two neon lamps by generating light by switching the switch ON or OFF. It has two neon lamps connected to two resistors to turn it on.

First and second light control circuits are provided for detecting light from a neon lamp that activates a power supply circuit for selectively supplying power to a load and a rechargeable battery.

Each light control circuit has an optical resistor for detecting light.

The first optical control circuit has a first relay for controlling the power supply of the power supply circuit.

The second optical control circuit has a second relay for determining whether the power supply circuit or the rechargeable battery will supply power.

Description

Automatic power control unit {AUTOMATIC POWER CONTROL DEVICE}

The present invention relates to a power supply control device, and more particularly to an automatic power supply control device for providing an uninterruptible power supply.

In recent years, people have paid much attention to how to escape from an emergency building.

As a result, well-known emergency light devices are usually installed around the doors or stairs of buildings to provide lighting for people to escape in case of danger or when the building is out of power.

These devices were installed only around doors or stairs to illuminate only a small portion of the area, making them unsatisfactory for large venues such as buildings.

Therefore, it is proposed to use a general lamp device for providing emergency lighting.

However, the use of a general lamp device as an emergency light device requires a complicated wiring connection process and causes a cost increase.

In addition, in the use of an emergency lamp or a general lamp device for emergency lighting, an uninterruptible power supply (UPS) for supplying power to the emergency light device or the general lamp device when power is turned off should be employed.

However, UPS typically do not start at the correct time, for example, no power is applied for five seconds and the building is completely dark.

This dark period of time results in people delaying their escape, leading to serious injury or death.

Thus, there is a need for the design of new emergency lighting devices that reduce and / or eliminate the problems described above.

An object of the present invention is to provide an automatic power supply control device that is safe to use, quick to operate, and easy to install.

1 is a circuit diagram showing an automatic power supply control apparatus according to the present invention.

(Explanation of symbols for the main parts of the drawing)

10: voltage level circuit 11: display lamp

12: switch 15, 16: neon lamp

20: first optical control circuit 21: comparator

22: photo resistor 23: relay

30 second optical control circuit 31 comparator

32: photoresistor 33: relay

40: power supply circuit 42, 43: power supply circuit

50, 51: rechargeable battery 60: power supply detection circuit

61: comparator

In order to achieve the above object, the automatic power supply control apparatus according to the present invention includes a charge battery, a voltage level circuit, a power supply circuit, the first and second light control circuit.

The voltage level circuit includes a display lamp, a switch connected in parallel to the display lamp, two resistors respectively connected to the terminal of the switch, and two neon lamps. Make sure the two neon lamps light up.

The power supply circuit is used for power supply.

The first and second light control circuits are provided for detecting light from a neon lamp that is active in a power supply circuit for selectively supplying power to a load or a rechargeable battery.

Each light control circuit has a photo resistor for detecting light from one neon lamp.

The first light control circuit has a first relay for controlling the power supply of the power supply circuit.

The second light control circuit has a second relay for determining whether the power supply circuit or the rechargeable battery supplies power.

Other objects and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

(Example)

1 shows an automatic power supply control device according to the present invention.

As shown in the figure, the device includes a voltage level circuit 10, a first light control circuit 20, a second light control circuit 30, a power supply circuit 40, a charge battery 50, and a power detection circuit 60. ) Is included.

The voltage level circuit 10 includes a display lamp 11, a switch 12 connected in parallel with the display lamp 11, two resistors R1 and R2 connected to terminals of the switch 12, respectively; It includes two resistors R1 and R2 and two neon lamps 15 and 16 connected to the input power source.

The display lamp 11 and the switch 12 are well known devices, and the display lamp 11 is turned off when the switch 12 is turned on, and the display lamp 11 is turned on when the switch 12 is turned off. Activate in this way.

The two neon lamps 15 and 16 are both turned on when the switch 12 is turned on, and the indicator lamp 11 is turned on due to the voltage distribution effect provided by the resistors R1 and R2 when the switch 12 is turned off. Only the neon lamp 16 is turned on by supplying a small current via).

The first light control circuit 20 includes a comparator 21 having an optical resistor 22 and an input pin connected to the resistor R3.

The reference voltage pin of the comparator 21 is connected to two resistors R4 and R5.

The output pin of the comparator 21 is connected to the relay 23.

The photo resistor 22 opposes the neon lamp 15 of the voltage level circuit 10.

As a result, when the neon lamp 15 is turned on, the resistance of the photoresistor 22 is lowered.

Therefore, the voltage to the input pin of the comparator 21 is higher than the reference voltage so that a high voltage level is output.

The relay 23 has an excitation coil connected to the output pin of the comparator 21.

The common terminal of the relay switch excited by the exciting coil is connected to the input power supply, and the terminal of the normally open relay switch is connected to the power supply circuit 40.

When the comparator 21 outputs a high voltage level, the relay 23 is excited so that the common terminal is switched to the always open terminal so that the power supply circuit 40 is started by the power supply.

The second light control circuit 30 includes a comparator 31 having an optical resistor 32 and an input pin connected to the resistor R6.

The reference voltage pin of the comparator 31 is connected to two resistors R7 and R8.

The output pin of the comparator 31 is connected to the relay 33.

The photo resistor 32 opposes the neon lamp 16 of the voltage level circuit 10.

Thus, when the neon lamp 16 is turned on, the resistance of the photo resistor 32 is lowered.

As a result, the voltage of the input pin of the comparator 31 becomes lower than the reference voltage, and the low voltage level is output.

The relay 33 has an excitation coil connected to the output pin of the comparator.

The common terminal of the relay switch excited by the exciting coil is connected to the load (lamp device).

The normally closed terminal of the relay switch is connected to the power supply circuit 40.

The normally open terminal of the relay switch is connected to the load charging battery 50.

When the comparator 31 outputs the low voltage level, the relay 33 is not excited and the power supply circuit 40 supplies power to the load.

On the contrary, when the comparator 31 outputs a high voltage level, the common terminal of the relay switch is switched to the always open terminal so that the load receives power from the load charging battery 50 instead of the power supply circuit 40.

The power supply circuit 40 includes a transformer 41 and two power supply circuits 42 and 43.

The primary winding of the transformer 41 is connected to the input power supply via the relay 23 of the first optical control circuit 20.

The secondary winding of the transformer 41 is connected to two power supply circuits 42 and 43.

Each power supply circuit 42, 43 includes a bridge rectifier, a capacitor and a voltage-stabilizing IC.

The output of the power supply circuit 42 is connected to the normally closed terminal of the relay switch of the second optical control circuit 30.

The output of the power supply circuit 43 is connected to the normally open terminal of the relay switch of the charging battery 50 and the second optical control circuit 30.

In addition to being connected to the output terminal of the power supply circuit 40, the rechargeable battery 50 has a positive terminal connected to the input terminal of the power supply detection circuit 60 and the first optical control circuit 20.

The power supply detection circuit 60 has a first input connected to the charging battery 51 via a resistor R10 and a second connected to a fixed reference voltage circuit formed by the resistor R9 and the zener diode ZD. It consists of a comparator 61 having an input.

The output of the comparator 61 is connected to the input of the second optical control circuit 30.

Therefore, if the output voltage of the rechargeable battery 50 is higher than the reference voltage of the comparator 61, the comparator 61 outputs a high voltage level to activate the second optical control circuit 30.

On the contrary, when the charging battery 50 outputs a voltage lower than the reference voltage, the comparator 61 outputs a low voltage level, and the second optical control circuit 30 is not activated so that the charging battery 50 supplies power to the load. Do not supply

Therefore, the power supply detection circuit 60 can protect the charging battery from over discharge and can ensure that the light control circuits 20 and 30 are efficiently activated.

In addition, the user can know whether the rechargeable battery 50 is activated correctly.

Since power is supplied to the light control circuits 20 and 30 by the charge battery 50, the power supply from the charge battery 50 to the load is supplied by the charge battery 50 to the light control circuits 20 and 30. It is limited to ensuring that there is enough electric power which can supply to.

If the rechargeable battery 50 fails and cannot normally be supplied with power, the lamp device (load) cannot be turned on by the user because the light control circuits 20 and 30 cannot be activated by the rechargeable battery 50. do.

As a result, the user knows that the rechargeable battery 50 has failed and needs to be repaired.

As described above, the structure of the automatic power control device according to the present invention can be seen.

In addition, the operation method is as follows.

If the power supply is normal and the switch 12 is turned on, the neon lamps 15 and 16 of the voltage level circuit 10 are turned on, and the light of the neon lamp 15 is the photoresistor 22. Lowers the resistance.

As a result, the output of the first light control circuit 20 activates the relay 23 high for driving the power circuit 40 for power supply.

At the same time, the light of neon lamp 16 also lowers the resistance of photoresist 32.

As a result, the output of the second light control circuit 30 is low, and the relay 33 is not activated so that the power supply circuit 40 supplies power to the load via the relay 33.

If the power supply is normal and the switch 12 is OFF, the neon lamp 15 of the voltage level circuit 10 is turned OFF and the other neon lamp 16 receives a small current to be turned on from the display lamp 11. .

As a result, the second light control circuit 30 outputs the low voltage level and the relay 33 is not activated.

The load is still connected to the output of the power supply circuit 40 via the relay 33.

Since the neon lamp 15 is turned off, the first light control circuit 20 outputs a low voltage at a level at which power cannot be supplied from the power supply circuit 40.

As a result, in that state, power is not supplied to the load and the load is turned off.

If the power supply fails and both the neon lamps 15 and 16 are turned off, the first light control circuit 20 outputs a low voltage level so that the input of the power supply circuit 40 is separated from the input power supply.

Since the resistance of the photoresistor 32 increases, the output of the second light control circuit 30 becomes high.

The relay 33 is excited to switch the common terminal of the relay switch to the normally open terminal.

As a result, the load is connected to the charging battery 50 via the relay 33, and the charging battery 50 supplies power to the load.

From the above description, it will be understood that the circuit structure and the operation method of the automatic power supply control apparatus according to the present invention.

According to the device of the present invention, there are the following advantages.

1. The device can be easily installed and modularized without complicated wiring connections.

2. The optical control circuit can be manufactured as an IC chip, and operates accurately at superspeed so that the rechargeable battery can be switched to the power supply when its main power fails.

3. Apparatus may be applied to various types of lamps or to alarm systems for providing emergency lighting.

Although the present invention has been described with respect to the appropriate embodiments, it will be appreciated that various other modifications are possible without departing from the spirit and scope of the present invention, and the scope of the present invention will be understood to be limited to the following claims.

Claims (7)

Rechargeable battery 50; A display lamp 11, a switch 12 connected in parallel to the display lamp 11, two resistors R1 and R2 connected to terminals of the switch 12, and two resistors R1, respectively. And a voltage level circuit having two neon lamps 15 and 16 connected to R2 and turning on one or two neon lamps 15 and 16 to generate light by switching off or on of a switch ( 10); A power supply circuit 40 for supplying power; First and second light control circuits for detecting light from the neon lamps 15 and 16 to energize the power supply circuit 40 to selectively power a load and the rechargeable battery 50. 20, 30, and Each of the light control circuits 20 and 30 has photo resistors 22 and 32 for detecting light, and the first light control circuit 20 is provided to control the power supply of the power supply circuit 40. Has a first relay 23, and the second optical control circuit 30 has a second relay 33 for determining whether the power supply circuit 40 or the rechargeable battery 50 supplies power. Automatic power control device characterized in that. The method of claim 1, The second optical control circuit 30 is further provided with a power detection circuit 60 connected to the charging battery 50 for detecting the charging battery 50 to protect the charging battery 50 from over discharge. Automatic power control device characterized in that for controlling. The method of claim 1, The first light control circuit 20 includes an input pin connected to the photoresistor 22 and a resistor, a reference voltage pin connected to two resistors, a common terminal connected to the input pin, and the power supply circuit 40. And a comparator (21) having an output pin connected to said first relay (23) having a normally open terminal connected to the control unit. The method of claim 1, The second optical control circuit 30 includes a comparator 31 having an optical resistor 32 and an input pin connected to the resistor, a reference voltage pin connected to two resistors, and a load connected to the load. And an output pin connected to said second relay (33) having a common terminal, and a normally closed terminal connected to said power supply circuit (40). The method of claim 3, The power supply circuit 40; A transformer (41) having a primary winding connected to the input power via the first relay (23) and a secondary winding connected to first and second power supply circuits (42, 43); The first and second power supply circuits 42 and 43, each having a bridge rectifier, a capacitor, a voltage-stabilizing IC, and the first having an output connected to the load via the second relay 33; And a second power supply circuit (43) connected to said rechargeable battery (50). The method of claim 4, wherein The power supply circuit 40; A transformer (41) having a primary winding connected to the input power supply via the first relay (23) and a secondary winding connected to first and second power supply circuits (42, 43); The first having the first second power supply circuits 42 and 43 each having a bridge rectifier, a capacitor and a voltage-stabilizing IC, and an output connected to the load via the second relay 33; And a second power supply circuit (43) connected to said charging battery (50). The method of claim 2, The power supply detection circuit 60, A first input connected to the rechargeable battery 50 via a resistor, a second input connected to a fixed reference voltage circuit formed by a resistor and a zener diode, and an input of the second light control circuit 30. And a comparator (61) having a connected output.