| The LM317T
is an extremely common positive voltage regulator - many laboratory supplies
and other equipment are based on it. It can produce any amount between 1.25V
and up to 35V by adjusting the resistance (opposition to current) between
its adjustment pin and ground.
There are two important things to keep in mind
when working with an LM317T:
First, the internal circuitry of the LM317T can
only handle 1.5 A of current as an absolute maximum. More on this
Secondly, and this is IMPORTANT, the LM317T
is a linear regulator. This means that it dissipates the excess voltage
as heat, with more heat produced as the voltage is set lower and lower.
You MUST have a heatsink mounted on the regulator that is capable
of dissipating the heat produced.
Most fans give their total output in watts - if
they give it in amps, multiply that by 12. Your heatsink MUST be
capable of dissipating the total wattage of all fans on the regulator safely.
Heatsinks can get BIG at the upper wattages. (Be careful with published
heatsink ratings; most sinks will say they dissipate 5W, but will heat up
to 20 or 30 degrees above ambient at that wattage.)
Here's one last thing to keep in mind; fans pull
more amperage when they're run at a lower voltage, on account of having less
torque. For example, a Panaflo 120mm H1A pulls 0.6 A at full 12V. However,
at 6V, it pulls closer to 0.85 A. You need to account for the highest
possible current draw (usually occurs at 6V) from each fan connected
to the regulator, and make sure you keep under the 1.5A limit.
If you need more than 1.5A of current, and have
a heatsink large enough to handle the wattage (old stereos and amplifiers
are great for finding massive heatsinks, btw), you can use an LM350, which
is rated up to 3 A and is identical to the LM317 in all other respects.
The LM338 is also compatible, and is rated up to 5 A.
you've decided how many fans you're going to run on the regulator, and how
big a heatsink you need, you can start gathering parts:
Once assembled, the output voltage of the LM317
is equal to 1.25V x (1 + R2/R1). Since we're feeding it 12V, a R2 (potentiometer)
of 10K and an R1 (resistor) of 1K will give us the full possible range of
the LM317 (minimum of 1.25V, maximum of 11.5V).
- The heatsink (I'm using a small 3W sink here, since this one is driving
the tiny 60mm Panaflo on my CPU heatsink.)
- The regulator itself. LM317/350/338s come in a variety of packaging;
I suggest using the TO-220 package, it's the most common. (You may also
find the TO-3 can package, which is much larger and heavier and has a different
pinout, but dissipates heat better).
- A 1KΩ (kiloohm) resistor. This will never have more than 100 microamps
going through it, as such you can safely get this as small as 1/8 watt.
However, I suggest 1/4 watt.
- A 0.1 μF (microfarad, sometimes also called MFD) ceramic capacitor.
This will go across the incoming power leads and smooth out any ripples
before it enters the regulator. You can also use mica, monolithic, or any
other kind of unpolarized capacitor.
- A 1 μF polarized aluminum or tantalum capacitor. This will
go across the output leads, and give you a smooth buffer effect when you
adjust the output. You can use larger capacitors if you want a larger buffer,
although anything over 10 uF is probably overkill.
- Heatsink paste/compound - this is a REQUIREMENT, just like a CPU.
I'm using cheap zinc silicone stuff here, but if you have leftover Arctic
Silver from your CPU or other paste, that's fine.
- A 10KΩ potentiometer or rheostat - this will be the knob for adjusting
the output voltage. Again, you can safely go down to 1/8 watt here, but
I suggest 1/4 watt.
- Finally, a board to assemble it on.
off, grease up the back of the regulator. It's pretty similar to greasing
a CPU - put on enough to fill up cracks between the heatsink and regulator,
a tiny tiny bit of squeeze-out is fine, but don't go overkill.
Then, screw on or clip on the heatsink, and solder
it to the board. If your heatsink has pins to solder to the PCB, make sure
you use those; you should somehow try to make sure the heatsink is properly
supported and doesn't bend or rip out the regulator.
Caveat: The tab is connected to the output
voltage pin. DON'T ground the heatsink, unless you enjoy watching a PSU
emit blue smoke and/or a regulator crack in half/explode/catch on fire.
bend one of the leads of the resistor over, and back, so it fits in two slots.
Mount it directly in front of the regulator.
It needs to connect across the voltage out and adjustment pins - these are
pins 1 and 2. (If you hold the regulator by the pins with the metal on bottom
facing away, the pins from left to right are adjustment, voltage out, and
Draw solder blobs between the regulator pins and
resistor pins (along the green lines drawn on the picture above).
attach two wires, which will attach to the potentiometer/rheostat.
One wire will go to ground, which we attach later.
The other wire needs to connect to the adjustment pin, along with the resistor.
My suggestion is to put one wire right below the resistor, and put the other
wire two holes below.
Extend the solder blob between the adjustment
pins and resistor pin to include the potentiometer wire. (See annotated
If the potentiometer/rheostat has two leads, use
those; most, however, will have three. In this case, use the middle lead
and either of the outer ones. (Don't ground or otherwise the leftover connection;
I suggest cutting it off and/or taping it over.)
attach the output capacitor. This needs to connect from the output voltage
pin to ground.
This capacitor is polarized - it has to
be oriented correctly. (If inserted the wrong way, it'll not work in best
case, and overheat/explode in worst case.) Most polarized capacitors have
the negative lead marked on their package/case; that lead should go to ground.
I suggest sticking it right in front, in the middle
of the regulator, so that the leads sit exactly parallel with the potentiometer
Draw solder blobs between output voltage pin and
capacitor, and connect the ground pin of the capacitor to the potentiometer
ground wire. (See annotated picture above.)
attach the input capacitor. This needs to connect from the input voltage
pin to ground.
This capacitor is not polarized - it will
work no matter which way it's plugged in.
I suggest sticking it on the other side and parallel
to the output capacitor, in line with the pin on the regulator.
Draw solder blobs between input voltage pin and
capacitor, and extend the ground line to the capacitor. (See annotated picture
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last part of construction is to attach molex plugs to the bottom side of
the board for the fan and power supply to plug into. The power supply 12V
line (usually yellow or blue, NEVER red) should plug into the input pin of
the regulator, near the ceramic cap; the fan output should plug into the
output pin in the middle. Both ground leads (take the middle black wire
nearest the 12V wire) should plug into the ground line at bottom.
Finally, trim down the board to an acceptable
size, and you're done!
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