Low cost / Automatic Emergency Light

LOW-COST AUTOMATIC EMERGENCY LIGHT

Description

Here is a white-LED-based emergency light that offers the following advantages:

  • It is highly bright due to the use of white LEDs.
  • The light turns on automatically when mains supply fails, and turns off when mains power resumes.
  • It has its own battery charger. When the battery is fully charged, charging stops automatically.

The circuit comprises two sections: charger power supply and LED driver.The charger power supply section is built around 3-terminal adjustable regulator (IC1) LM317, while the LED driver section is built around transistor BD140(T2). In the charger power supply section, input AC mains is stepped down by transformer to deliver 9V, 500mA to the bridge rectifier, which comprises diodes (IN4007x4). Filter capacitor (25v/1000uf)eliminates ripples. Unregulated DC voltage is fed to input pin 3 of IC1 and provides charging current through diode IN4007(D5) and limiting resistor (16ohm)R16. By adjusting preset 2.2K(VR1), the output voltage can be adjusted to deliver the required charging current. When the battery gets charged to 6.8V, zener diode conducts and charging current from regulator (IC1) finds a path through transistor BC547(T1) to ground and it stops charging of the battery. The LED driver section uses a total of twelve 10mm white LEDs.

All the LEDs are connected in parallel with a 100-ohm resistor in series with each. The common-anode junction of all the twelve LEDs is connected to the collector of pnp transistor T2 and the emitter of transistor T2 is directly connected to the positive terminal of 6V battery. The unregulated DC voltage, produced at the cathode junction of Bridge(Diodes), is fed to the base of transistor T2 through a 1k resistor. When mains power is available, the base of transistor T2 remains high and T2 does not conduct. Thus LEDs are off. On the other hand, when mains fails, the base of transistor T2 becomes low and it conducts. This makes all the LEDs (LED1 through LED12) glow. The mains power supply, when available, charges the battery and keeps the LEDs off as transistor T2 remains cut-off.

During mains failure, the charging section stops working and the battery supply makes the LEDs glow. Assemble the circuit on a general-purpose PCB and enclose in a cabinet with enough space for battery and switches. Mount the LEDs on the cabinet such that they light up the room. A hole in the cabinet should be drilled to connect 230V AC input for the primary of the transformer. I have tested the circuit with twelve 10mm white LEDs.You can use more LEDs provided the total current consumption does not exceed 1.5A. Driver transistor T2 can deliver up to 1.5A with proper heat-sink arrangement.

 

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Blaise

Hello, what is thé part VR1 , 2.2 K?

Blaise

Thanks a lot

Blaise

I am still concerned by this potentiometer. How do I know the correct tuning to ensure correct charging of battery?
Thanks in advance

EkoMulyono

Sir.. can 16R/5W resistor replaced with other?

Awnish Sharma

Tested above circuit. It works great however it takes 2-3 seconds to glow the LEDs after power cut. Can we use 12 V 7.5 Ah battery here? In that case what components values need to be changed to ensure trickle charging.
Planning to build one for my home. Please help 🙂

durga

1.2k = ? watt

2.2k vr ? watt

180R = ? watt

Adrian

Can a 12V lead acid 9ah battery be used with this charger and if so what components would I have to change?

Awnish Sharma

Can we use 12 V 7.5 Ah battery here? In that case what components values need to be changed to ensure trickle charging.

Able Utopia

Rather very inefficient way to design a battery charger. Routing the output of LM317 across BC547/180 ohms resistor is a total waste of energy, just producing heat. Besides, marginal battery charging monitoring and no trickle charge.
It will work, but much room for improvements.

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