ELECTRONIC
CANDLE
INSTRUCTION SHEET
Price - Stock No 210
This circuit will detect light falling
on the Light Dependent Resistor (LDR or CdS). When light falls
on the LDR the arrangement of resistors
at the base of the transistor T1 gives a change of
voltage. This biases or turns on the transistor
which turns on T2, allowing sufficient
current to flow to light the globe. The arrangement of
the resistors at the base of T1 is called a Potential Divider. It is
adjusted to suit ambient light conditions by the variable resistor VR1. A
typical use would be to set the project up in the refrigerator. The light will
light up in another room if you have enough wire, or you could put
a buzzer in instead of the light and catch whoever is
raiding the refrigerator.
Check Your
Kit
Schematic Diagram
PCB Layout
- Check the P.C.Board for damage to the tracks in
transit. Continuity of tracks is best checked with an OHMS setting on a
multimeter, or with an Electronic Circuit Tester.
- Turn the board copper tracks down and begin to mount
the components in the locations shown on the Placement Sheet. The values of
the Resistors are determined by the colour bands. The resistors
will fit this Board more comfortably
if they are mounted vertically to the Board. The Trimpot will fit
the holes and position the legs correctly. Remember that the
resistance is varied between Centre and one outside leg. The other
outside leg is a passenger, but is soldered to improve firmness of the trimpot
to the Board.
- Both Transistors are BC548 (or BC547) so they are
interchangeable. The drawing shows the way the flat on the body goes.
- The LED is polarised. The flat on the globe goes
to the K (neg) side. It won't work the other way
round.
- If a buzzer is being fitted, the
polarity must be observed - Red wire is Positive (A), Black is Negative
(K). A power diode, D2 - IN4002- is fitted to avoid
feedback to the circuit from the LED and mainly, the buzzer.
- The battery snap is connected, Red to
Positive. A slide switch is included for a power on/off switch.
One wire of the battery snap, usually the red one, is cut and the
switch soldered in series in the line.
- The Light Dependent Resistor is
soldered across the two tracks shown.
- Soldering can be done progressively as components are
mounted if you like. Refer Soldering Technique.
To test the Electronic Candle, connect a 9V battery and
switch it on. Shield the Light Dependent Resistor from the
light source and adjust the trimpot until the LED goes off (and the buzzer
stops). Expose the LDR to light and the LED (and buzzer) will
operate. Differing ambient light conditions
will require adjustment to the trimpot. If the light is very strong
- say sunlight - you may have to replace the trimpot with one
of much higher value, say 100K or 500k or perhaps 1M.
TROUBLESHOOTING
If the project doesn't operate the process of trouble-shooting will
consist of
- checking each component for
correct value, polarity where applicable (LED, Diode
IN4002, Transistors, Buzzer).
- Inspect all soldering and
resolder any suspect joints, and watch for
bridges of solder across tracks which will create short circuits.
- As a party interest piece you can adjust the trimpot so that
when you shine a small torch at the LDR
the LED will light. If the LED is located away from the torch with
two insulated leads, say in the next
room, then the LED will light up
"on command", provided that the "command" is loud
enough for the guy in the next room with the torch to hear
and shine his torch on the LDR. Or perhaps you could conceal the LDR
under a cloth. Shine the torch at the spot where the LDR is
and the LED will glow in another place across the room.
MAGIC!
TECHNICAL NOTES
- You will find it interesting to measure the
different resistance across the legs of the LDR under varying
light flux. A Multimeter set to the OHMS modes will show the enormous
changes to resistance across the
legs. The Light Dependent Resistor is a Cadmium-di-sulphide Cell
as used in photography for light meters and self-adjusting
(automatic) exposure cameras.
- The Potential Divider consists of the arrangement
of LDR1 on one side, VR1 on the other side and the tapping
point between them. The Voltage at
the tapping point is varied by the proportion of
the values of these two resistors, and the total of the Voltage - Tap to
Positive rail + Tap to Negative rail
= the total supply Voltage (9V). Both the resistors are
variable in this case so a balance can be established to suit a range of light
conditions. When the Voltage at the Tap (the Base of Transistor 1) rises, the
transistor will switch on. This allows current to flow between C and E
legs. The E leg is connected to the Base of Transistor 2,
so the voltage turns T2 on. The output of T2 with this setup is
very large so a fairly large device could be driven. Transistors in this
setup are called a Darlington Pair. The GAIN of each of these
transistors is about 100, but with Darlington Configuration the
total Gain would be 100 X 100. This means that 1 milliamp at the
Base of T1 would result in 10000 milliamps available at C or
E of T2. R1, R2, and R3 are protection metering resistors,
and R4 meters the current to the LED to approx. 20 milliamps, the specified
draw of LEDs.
- Notice that the polarity of the Diode D2 is the reverse
to what you would expect, viz. the K band is to the Positive (A)
rail. This diode prevents damage to the circuit components that
can occur from feedback from buzzers, relays, or other
output devices.
- Connect a Voltmeter from the B leg of
T1 to Negative rail. Switch the Candle on
and slowly increase the light intensity
on the LDR (by turning it slowly towards the light). Note
the Voltage reading when the LED just lights.
This will give the Switching Voltage
of the transistors. Check your reading against a Data
Table for this transistor (BC 547).
- Check also the different readings +ve rail/ tap and -ve rail / tap.
These will be different, but should add together to give Cell Voltage
(around 9 Volts).
Contact CdS electronics
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