KR200189903Y1 - The lighting electric circuit for a pilot lamp of emergency exit - Google Patents

Abstract

The present invention relates to an emergency exit indicator lighting circuit used for indicating the location of the emergency exit for escape even in the event of a power failure during a fire lamp disaster.

The present invention is to ensure that the emergency exit indicator by the battery when the power failure by one inverter is turned on at the same time as the emergency exit indicator by the same one inverter during testing, and to minimize the occurrence of blackening phenomenon will be.

To this end, the present invention provides a power supply to a battery for supplying power to an inverter during a power failure, a power supply for driving an inverter during a test, and a power supply for a relay that switches a contact by detecting a power failure. The power supply is to be made, but this power supply is made by three independent power supply means, and the emergency exit indicator light circuit is proposed so that the constant power supply is made by the transformer in the filament of the emergency exit indicator lamp.

Accordingly, the present invention uses only one inverter, thereby reducing manufacturing costs, making it lighter and smaller, and reducing the blackening phenomenon, thereby extending the life of the indicator.

Description

The lighting electric circuit for a pilot lamp of emergency exit}

The present invention relates to an emergency exit indicator lighting circuit, and more particularly to an emergency exit indicator lighting circuit used for indicating the location of the emergency exit for escape even in the event of a power failure during a fire lamp disaster.

As is well known, the emergency exit indicator is used to allow a person in the room to escape to the outside through an emergency exit in the event of a fire or other disaster.

A representative circuit of such an emergency exit indicator is shown in FIG. As can be seen from the prior art, the battery 100 is normally charged by the power supply circuit in the usual state, and when the power failure is detected, the emergency exit indicator 101 is turned on by the charged power of the battery 100. When the power is applied to the test terminal 102 provided separately to check the abnormality of the indicator 101, the indicator 101 is to be turned on.

Therefore, it is essential that the inverter 103 to obtain the high voltage required for the lighting required by the indicator 101 by the storage battery 100 is required, and the choke 104 and the glow starter to be turned on by commercial AC power directly for the test. (glow starter) 105 was needed.

Accordingly, the conventional emergency exit indicator lamp had to be provided with two lighting means for turning on the battery and a commercial AC power supply, and thus, there is a problem in that the manufacturing cost is increased, the volume is increased, and the failure rate is also increased.

In addition, the conventional emergency exit indicator light is started by the high voltage applied to both ends of the discharge lamp in a cold region, there is a problem that the blackening of the discharge lamp is generated early, the life of the discharge lamp is shortened.

The purpose of the present invention is to solve the problem, the lighting of the emergency exit light by the battery at the time of power outage by one inverter and at the same time the lighting of the emergency exit light by the same one inverter during testing,

In addition, an emergency exit indicator lighting circuit is provided so that a smooth discharge can be started by always supplying current to the filament of the emergency exit indicator.

1 is a conventional emergency exit indicator lighting circuit diagram.

2, 3 is an emergency exit indicator lighting circuit diagram according to the present invention.

* Explanation of symbols for the main parts of the drawings

1: trans

2: rectifier circuit

3: battery

4: transistor for excitation

5: switching transistor

6: winding for excitation

7: Winding winding

8: Output side winding

9: inverter

10: Test terminal

11, 12, 13: Output terminals 1, 2, 3

14: Compensation Control Circuit

It is a photocoupler

22: heater winding

The purpose of the present invention is to provide power to the battery for supplying power to the inverter during power failure, to supply power to drive the inverter during the test, and to detect the power failure for the relay to switch contacts The power supply is to be made, but this power supply is made by three independent power supply means, and the emergency exit indicator lighting circuit is made to ensure that the power supply is always made by the transformer in the filament of the emergency exit indicator.

As a result, the present invention enables a single inverter to be turned on during a power failure and to turn on a test, thereby greatly reducing manufacturing costs, reducing weight, and suppressing blackening of an indicator light, thereby obtaining a life extension effect. It works.

This invention is described in more detail with reference to the accompanying drawings as follows.

As shown in FIG. 2, the present invention provides a transformer 1 for lowering the voltage of an input power source, a storage battery 3 charged by a rectifier circuit 2 connected to the transformer 1, and a storage battery 3. Inverter (9) consisting of excitation transistor (4) and switching transistor (5) and excitation winding (6), oscillation winding (7), and output side winding (8) for oscillating with power to supply lighting power to an indicator light And a known emergency exit indicator light circuit comprising a test terminal 10, the output terminals 1, 2, 3 (11, 12, 13) connected to the secondary side of the transformer 1 to generate three independent outputs. To charge the storage battery 3 by the output terminal 1 (11), to supply power to the relay 23 by the output terminal 2 (12), the test signal by the output terminal 3 (13) To supply power to the transistor 4 and the inverter 9 that are switched according to The auxiliary rectifier circuit 14 and the photo coupler 15 to the rectifier circuit 2, the test terminal 10 and the power supply line, and the photo coupler 15 and the base of the transistor 4 Reference numeral 16 is a light emitting diode of the photocoupler 15, 17 is a phototransistor of the photocoupler 15, 18 is a constant voltage circuit 18, 19 is a transistor of the constant voltage circuit 18, 20 is a light emitting diode of the constant voltage circuit, and 21 is a filament of the indicator 4.

In the present invention as described above, the power is normally supplied to the rectifier circuit 2 when the power is supplied to the primary side of the transformer 1 and is induced to the secondary side. Therefore, '+' voltage is output from the output terminals 1, 2, 3 (11, 12, 13) of the rectifier circuit 2.

Therefore, since the output voltage of the output terminal 1 (11) flows through the constant voltage circuit to the storage battery 3, the storage battery 3 can be smoothly charged.

In this charging step, since the voltage across the storage battery 3 is low, the base voltage of the transistor 19 of the constant voltage circuit 18 is low, so that the transistor 19 remains turned off. Thus, a current is generated in the light emitting diode 20. The user can recognize that the storage battery 3 is currently being charged because it can be turned on to be turned on. In this process, when the battery 3 is charged, the voltage between the both ends of the battery 3 is sufficiently high, and the base voltage of the transistor 19 of the constant voltage circuit 18 is high. Therefore, the transistor 19 is turned on so that the constant voltage circuit ( No current flows to the light emitting diode 20 of 18, and the light emitting diode 20 is turned off.

On the other hand, at present, since the power supply is normally performed, current flows to the coil of the relay 23 by the power supplied from the output terminal 2 (12) so that the contacts (A, B) are switched. Therefore, the state in which the power of the battery 3 is supplied to the inverter 9 through the contact A is cut off by switching to the contact state as shown in FIG. 3, so that the power supply to the inverter 9 is cut off.

In addition, the power supplied from the output terminal 3 (13) is supplied to the inverter 9 through the contact A, and the excitation winding 6 of the transistor 4 and the inverter 9 through the contact B. ), The phototransistor 17 of the photocoupler 15 is turned off and waits for operation.

In the case of power failure in this state, the secondary output of the transformer 1 disappears, resulting in the loss of the voltages of all the output terminals 1, 2, 3 (11, 12, 13) of the rectifier circuit 2.

Therefore, the voltage of the output terminal 2 (12) is lost and the operation of the relay 23 is stopped, thereby inverting the state of the contacts A and B, as shown in FIG. Therefore, as shown by the arrow in FIG. 2, the voltage of the battery 3 is supplied to the excitation winding 6 of the inverter 9 via the contact B, and also through the contact A to the oscillation winding of the transformer. Also supplied to (7) is the oscillation by the switching transistor (5) is made. Accordingly, the oscillation output is induced in the output side winding 8 so that the oscillation voltage is applied to the filament 21 at both ends of the indicator 4, so that discharge can be started and maintained.

In addition, the person who is indoors will be able to escape through the emergency exit confirmed by the indicator light 4 in the event of an emergency such as a fire.

In this state, when the power supply is normally resumed, the power of the output terminals 1, 2, 3 (11, 12, 13) of the rectifier circuit 2 connected to the transformer 1 is normally supplied. Therefore, the relay 23 is actuated so that the contacts A and B are switched again, as shown in FIG. 3, whereby the inverter 9 is operated by the photocoupler 15 as described above.

In this state, when the operator applies power to the test terminal 10 for the test, the power is rectified in the auxiliary rectifier circuit 14 and the current flows in the light emitting diode 16 of the photocoupler 15. As the phototransistor 17 is turned on, current flows. As a result, a high-level voltage is applied to the base of the transistor 4, and as a result, current flows through the excitation winding 6 of the inverter 9 as shown by the dotted line in FIG. (8), the oscillation current flows by the switching operation of the switching transistor 5, and the oscillation voltage is applied to the indicator light 4, so that the lighting start and maintenance states are secured.

When the test result indicator 4 is turned on, when the voltage applied to the test terminal 10 is cut off, only the dotted line shown in FIG. 3 is applied to the voltage, so that the phototransistor 17 and the transistor 4 are closed. When turned off, the indicator light 4 turns off and returns to the standby state.

In addition, in the present invention, the heater winding 22 is installed on the transformer 1 and the filament 21 of the indicator light 4 is connected thereto. As a result, power is always supplied to the filament 21 of the indicator light 4. It becomes the state that becomes. As a result, when the oscillation output is supplied to the indicator 4, the indicator 4 is smoothly started to discharge, thereby suppressing the occurrence of blackening and extending the life of the indicator 4.

In this way, the present invention is to use a single inverter (9) to turn on the indicator light (4) can greatly reduce the manufacturing cost, reduce the weight, it is possible to obtain the effect such as compact size In addition, there is a useful effect that it is possible to restrain the blackening of the indicator 4 to achieve the effect of extending the life.

Claims (2)

Oscillation is generated by the power of the storage battery 3 and the storage battery 3 charged by the transformer 1 for reducing the voltage of the input power supply, the rectifier circuit 2 connected to the transformer 1, and the lighting power supply to the indicator lamp. The inverter 9 and the test terminal 10 composed of an excitation transistor 4 and a switching transistor 5 and an excitation winding 6 and an oscillation winding 7 and an output winding 8 In the emergency exit indicator lighting circuit, an output terminal 1, 2, 3 (11, 12, 13) connected to the secondary side of the transformer 1 to generate three independent outputs is provided by the output terminal 1 (11). The battery 3 is charged, the power is supplied to the relay 23 by the output terminal 2 (12), and the transistor 4 and the inverter switched by the output terminal 3 (13) according to the test signal. Rectification circuit (2) and test to supply power to (9) Member 10 and the auxiliary rectifier to the power supply line circuit 14 and connects the photo coupler 15, the photo-coupler 15 and the emergency exit indicator lamp lighting circuit as claimed hayeoseo connecting the base of said transistor (4). 2. The emergency exit indicator lighting circuit according to claim 1, wherein the filament (21) of the indicator (4) and the heater winding (22) additionally installed in the transformer (1) are connected.