KR101031496B1 - Guidance lamp lighting device - Google Patents

Abstract

The present invention relates to an induction lamp that is turned on in an emergency situation and its driving device, and avoids the use of integrated circuits and photocouplers, which were the main components of the conventional device, and enables mechanical driving around a small DC relay interlocking with a remote switch. By designing the device, not only the overall size, weight, and slimness are possible, but also the heat generation inside the device can be suppressed to achieve a reflection configuration of the operation accuracy and lifespan.

Induction lamp, relay, heat

Description

Induction light driving device {Guidance lamp lighting device}

The present invention relates to an induction light drive device.

In particular, the present invention relates to an induction lamp driving device installed at a radiation-related material emission site such as a nuclear power plant.

Normally, induction lamps are installed in emergency exits or emergency passages, which are quickly turned on in the event of an emergency, so that people in danger can see the lights and evacuate to a safe place. Such induction lamps must be installed, especially in high-rise buildings with high population density. Even though it is not a high-rise building, it is true that modern life is highly likely to cause various safety accidents. Therefore, common sense should be installed in all buildings and facilities to prevent the loss of valuable lives.

However, when looking at the conventional induction lamps for fire-fighting, SMPS IC (Switched-Mode Power Supply Integrated Circuit) for small size, light weight and slimness and photo coupler for insulation connection operation are mainly used to reduce the volume of transformer for transformer. Able to know.

However, the SMPS IC and the port coupler have problems such as unstable operation or shortened life time of the induction lamp installed in the nuclear power plant due to severe heat generation, which adversely affects the durability of the device or is very vulnerable to radiation-related materials. Caused.

The present invention has been made to improve the problems associated with the conventional induction lamp as described above, an object of the present invention is to enable the induction light to be turned on and off by the operation of a small DC relay interlocked with a remote switch induction lamp to enable mechanical operation To provide a drive.

Induction light driving device of the present invention for achieving the above object, the induction light is turned on when an emergency occurs; Remote switch for operating the induction light in case of emergency such as fire; Induction lamp driving circuit unit by the AC power supply to operate the relay in conjunction with a remote switch which is supplied to the external AC power supply AC 220V, transformed to a constant voltage and operates in an emergency situation to operate the relay; An induction lamp driving circuit unit by a DC power source operating to turn on an induction lamp under the control of a remote switch operating when an emergency occurs when the external AC power is cut off; And a battery monitoring circuit for monitoring a state of a battery supplying DC power for lighting the induction lamp.

The remote switch unit of the present invention is characterized in that the relay is interlocked for the induction light to the magnet switch that operates when an emergency occurs.

Induction lamp driving circuit unit by the AC power supply of the present invention is characterized in that it comprises a small DC relay interlocked with the remote switch, and the light emitting diode for driving the induction light.

Induction lamp driving circuit unit by the DC power supply of the present invention is characterized in that it comprises a battery for supplying power for driving the induction lamp when the AC power supplied from the outside.

The battery monitoring circuit of the present invention is characterized in that it comprises a light emitting diode for battery charging and status monitoring.

According to the induction light driving device of the present invention, the induction light is turned on and off by the operation of the small DC relay interlocked with the remote switch, the mechanical operation is possible to suppress the self heat generation, thereby improving the durability of the device.

In addition, according to the induction light driving device of the present invention can improve the configuration of the device as a whole can be compact, light weight, slim.

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

1 is a control configuration diagram of an induction lamp driving apparatus of the present invention, FIG. 2 is a detailed circuit diagram of FIG. 1, FIG. 3 is an induction lamp driving circuit diagram by an AC power source among the circuits of FIG. 2, and FIG. 4 is a battery DC power source of the circuit of FIG. FIG. 5 is a battery monitoring circuit diagram of the circuit of FIG. 2, and FIG. 6 is an operation waveform diagram of the battery monitoring circuit of FIG. 5.

As shown in FIG. 1, the induction lamp driving device according to the present invention receives an induction lamp 10, a remote switch 20 that operates to turn on the induction lamp 10 in case of an emergency such as a fire, and an external AC power supply AC 220V. The induction lamp driving circuit part 30 by an AC power source which operates so that the induction lamp 10 is turned on by operating the relay 35 in conjunction with a remote switch operating at an emergency situation such as a fire and the like, and the external AC power source Induction lamp driving circuit unit 40 by the DC power source to operate so that the induction lamp 10 is turned on under the control of the remote switch 20 operating in the event of an emergency such as a fire when blocked, and the DC power source for the induction lamp 10 lights It consists of a battery monitoring circuit 50 for monitoring the state of the battery supplying the.

In Fig. 1, the relay 35 is the same component.

As shown in FIG. 2, the induction lamp 10 of the present invention includes a white LED 11 to enable driving (lighting and turning off) by an AC and DC power supply.

2 and 3, the remote switch 20 of the present invention is a part operated for lighting the induction lamp 10 when an emergency situation such as a fire is called a black line BL and a red line by the operation of a magnet switch. (R) Control the contact of the line.

As shown in FIGS. 2 and 3, the induction lamp driving circuit part 30 by the AC power supply of the present invention receives an external alternating current power, converts a constant voltage, and relays to a remote switch 20 that operates when an emergency occurs. 35, the white line (WH) and the black line (BL) line as the AC power input terminal, the fuse 31 for the external rated AC power input and the check switch 32 so that the induction lamp 10 is turned on according to the operation of 35). In order to transform the input AC power into a constant voltage, the transformer 33 having a primary and secondary windings having a constant ratio and the AC power supplied from the secondary side of the transformer 33 are driven by induction lamp driving and battery charging DC. Rectifiers R1 to R4, R13, and R14 connected in series to generate a constant current by the rectifying bridge diode 34, the diode D1 rectifying the external AC power, and the DC power rectified by the diode D1. And, for driving the relay 35 A capacitor C1 for charging the power through the resistors R1 to R4, R13, and R14, a capacitor C2 for charging the power by the bridge diode 34 to drive the relay 35, and the transformer A diode D3 for rectifying the AC power supplied from the secondary side of 33, a capacitor C3 charged with the DC power rectified by the diode D3, and a power charged in the capacitor C3. It consists of a resistor R9 for flowing and an induction lamp lighting confirmation LED 36 that receives power through the resistor R9 and emits light. Here, the power source is referred to collectively without distinguishing voltage and current.

As shown in FIGS. 2 and 4, the induction lamp driving circuit unit 40 by the DC power supply of the present invention is supplied through the battery 41 and the fuse 42, and the white line WH and the black line BL lines. When the AC power is cut off, as the voltage charged in the capacitor C3 is momentarily discharged, the voltage of the battery 41 connected to the emitter flows current to the base resistor R10 so that the base bias is forward. The emitter current is composed of a transistor TR2 that turns on the white LED 11 through the resistor R12 so that the induction lamp 10 is turned on.

As shown in FIG. 2 and FIG. 5, the battery monitoring circuit 50 of the present invention has a resistance (R6) (R7) for dividing the power when the power supplied from the transformer 13 is rectified, and the battery 41 is fully charged. Transistor TR1 that is driven and controlled according to power, uncharged, emergency power failure and fuse 42 is disconnected, and is turned on or off according to driving of the transistor TR1 to check the state of the battery 41. It consists of an LED 51 for checking battery status.

 The operation of the induction lamp driving device of the present invention configured as described above will be described in detail with reference to the entire drawings.

The operation of the present invention is largely divided into induction lamp lighting according to the external AC power, indicating whether the induction lamp lighting or not, charging the battery for induction lamp lighting by the DC power, and monitoring the battery status.

First, when the induction lamp 10 is turned on according to the external AC power, when AC 220V is supplied through the fuse 31 and the check switch 32, the power is applied to the primary side of the transformer 33 and the voltage induced to the secondary side is After rectifying by the bridge diode 34, the capacitor C1 is charged to open and close the contact SRY of the relay 35 interlocking with the remote switch 20 so that the induction lamp 10 can be turned on and off.

In addition, the indication whether the induction lamp 10 is turned on is that the DC power supplied from the secondary side of the transformer 33 and rectified by the diode D3 is charged in the capacitor C3 to turn on the LED 36 through the resistor R9. Since it is lit, it is possible to confirm that the induction lamp 10 is lit.

In addition, the charging of the battery 41 for turning on the induction lamp 10 by the DC power is performed by applying the reverse bias of + to the base of the transistor TR2 through the diode D4 by the DC power charged in the capacitor C3. Operation by the battery 41 is impossible at the time of power input, and half-wave rectification through the diode D2 is charged to the battery 41 in an uncharged manner through the resistor R5.

In the battery 41 state monitoring, the divided voltage by the resistors R6 and R7 becomes VB and this voltage becomes the base bias voltage of the battery monitoring transistor TR1. Is V BA and the split voltage by the split resistor is VB, but when fully charged, V BA is higher than VB, so that the collector current of the transistor 41 for monitoring the battery 41 flows, so that the LED 51 is turned off and the battery 41 is turned off. Indicates full charge.

In addition, when the battery 41 voltage V BA is less than or equal to the divided voltage VB when the battery is not charged, the emergency power supply is defective, and the fuse 42 is disconnected, the base of the transistor 41 for monitoring the battery 41 has no bias or a bridge rectification frequency. The battery monitoring LED 51 flashes at 120 Hz due to the pulse current at 120 Hz, indicating that the battery 41 is in an abnormal state.

   The driving of the induction lamp 10 of the present invention, which is basically operated as described above, is divided into driving by AC power and DC power, respectively.

First, the lighting of the induction lamp 10 by the AC power will be described.

When the black line BL and the red line R are connected at the time of input of the external AC power, that is, when the emergency situation such as a fire occurs, the black line BL and the red line R line by the remote switch 20 such as an external magnet switch. When this connection is made, the pulse wave rectified by the diode D1 is charged to the capacitor C1 through the resistors R1 to R4, R13 and R14, and the relay 35 is operated to turn on the contact SRY P. Therefore, the DC power charged in the capacitor C2 turns on the white LED 11 through the series resistors R11 and R12 to maintain the lighting state of the induction lamp 10. Therefore, those who are in an emergency will have to evacuate to a safe zone by looking at the induction lamp 10 that is lit.

On the other hand, when the connection between the black line BL and the red line R is interrupted, that is, when the emergency situation is released, the contact of the relay 35 is opened, so that the resistances R11 and R12 of the DC power charged in the capacitor C2 are opened. Induction lamp 10 is turned off because the supply to the white LED 11 through the impossible.

At this time, the battery 41 is connected to the emitter of the DC lighting transistor TR2 and the voltage rectified by the capacitor C3 is greater than the voltage of the battery 41 while the voltage rectified by the capacitor C3 is applied to the base. Since the emitter and base of the DC lighting transistor TR2, which is a PNP transistor, are reverse biased, the operation of the transistor TR2 becomes impossible, and as a result, the emitter current does not flow. 10) No lighting occurs.

Next, the induction lamp 10 lighting by the DC power supply of the battery 41 is demonstrated.

When the AC power supplied through the white line WH and the black line BL is cut off, the voltage charged in the capacitor C3 is momentarily discharged and the battery 41 connected to the emitter of the DC lighting transistor TR2 is connected. ), The current flows to the base resistor R10 of the DC lighting transistor TR2, and the base bias of the transistor TR2 is forward, so that the emitter current turns on the white LED 11 through the resistor R12. The induction lamp 10 is turned on.

As described above, according to the present invention, by illuminating the white LED 11 for illumination by the AC power and the battery DC power, the display surface of the induction light 10 is illuminated so that the emergency exit or the emergency passage can be guided to the light.

1 is a control configuration of the induction light driving device of the present invention.

2 is a detailed circuit diagram of FIG.

3 is an induction lamp driving circuit diagram of the circuit of FIG.

4 is an induction lamp driving circuit diagram of the battery of FIG.

5 is a battery monitoring circuit diagram of the circuit of FIG.

6 is a waveform diagram illustrating an operation of the battery monitoring circuit of FIG. 5.

Explanation of symbols on the main parts of the drawings

10: induction light

20: remote switch

30: induction lamp driving circuit by AC power

40: induction lamp driving circuit by DC power

50: battery monitoring circuit

Claims (4)

In the induction light driving device installed in the radiation emitting material place, Induction lamp 10; A remote switch 20 that operates to turn on the induction lamp 10 when an emergency occurs; A relay 35 interlocked with the remote switch 20; The white line (WH), which is an AC power input terminal, is switched on so that the induction lamp 10 is turned on according to the operation of the relay 35 interlocked with the remote switch 20 which operates when an emergency situation occurs by receiving an external AC power. And black line BL lines; An external rated AC power input fuse 31 and a check switch 32; A transformer 33 having primary and secondary windings having a predetermined ratio so as to transform the input AC power into a constant voltage; A bridge diode (34) for rectifying the AC power supplied from the secondary side of the transformer (33) to a direct current for induction lamp driving and battery charging; A diode D1 rectifying an external AC power source; Resistors R1 to R4, R13, and R14 connected in series to generate a constant current by the DC power rectified by the diode D1; A capacitor C1 for charging the power through the resistors R1 to R4, R13, and R14 to drive the relay 35; A capacitor (C2) for charging the power by the bridge diode (34) for driving the relay (35); A diode (D3) for rectifying the AC power supplied from the secondary side of the transformer (33); A capacitor C3 charged with the DC power rectified by the diode D3; A resistor (R9) for flowing the power stored in the capacitor (C3); And an induction lamp driving circuit unit 30 formed by an AC power source including an induction lamp lighting confirmation LED 36 that receives power through the resistor R9 and emits light; A battery (41) so that the induction lamp (10) is turned on under the control of a remote switch (20) operating when an emergency occurs when the external AC power is cut off; Fuse 42; When the AC power supplied through the white line (WH) and the black line (BL) is cut off, the voltage of the battery 41 connected to the emitter is changed to the base resistance as the voltage charged in the capacitor C3 is momentarily discharged. Induction lamp driving by DC power source composed of transistor R12 which keeps induction lamp lighting state by flowing current through R10 so that the base bias is forward and emitter current lights white LED 11 through resistor R12. Circuit section 40; And Induction lamp driving device, characterized in that consisting of a battery monitoring circuit (50) for monitoring the state of charge of the battery (41) for supplying DC power for the lighting of the induction lamp (10). delete delete delete

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