OK, so you want up to 6A and a voltage variable up to 12V. We're talking 72W here, which is a lot for a linear power supply. Let's see if we can do it.
Just take it from me that placing several voltage regulators in parallel is not a great idea unless you can ensure that they share the current more or less equally. The problem is not so much the amount of heat (it will be the same in all cases) but that it is spread evenly over the devices you're planning on using
I'm also conscious that you've already bought some stuff and that reusing as much as possible would be a good thing.
Here is a way of paralleling several regulators so they share current:
The 0.2 ohm resistors help the regulators share the current. These are 1.5A regulators, so this circuit is rated at just a little under 3 x 1.5A. You have several 3A regulators, so you should be able to get 6A easily.
Now, there are some complexities here that result in good regulation, but that's probably not your primary concern.
I would recommend you try this:
This won't regulate the voltage quite so well. The voltage will sag by about 0.2V at 6A, but that's reasonably small.
Note that I have not shown any capacitors. The input and output capacitors that you had before are still required.
The VERY important thing to note is that the case of the regulator is connected to the output terminal so you will have to insulate the LM338's from the heatsink. The heatsink you've selected is *way* too small. I'll suggest one in a minute.
Let's assume you have a 12V secondary when bridge rectified, you will get a peak voltage of about 15V under load (it will be higher without load). For a 12V output, you need an input voltage of 14.5V, so in theory you need 100,000uF of filter caps to keep the ripple below 0.5V.
Now you have said that you really only want up to 6V, so for this you could get away with 10,000uF.
Now let's look at the total power dissipation. At a reasonable maximum (supplying 2V at 6A), the regulators are dissipating 12.5 * 6 = 75W. Let's assume a 25C ambient temperature and a maximum die temp of 115C. If the heat is being spread between the three of them, we can assume about 1.5 degC/W junction to heatsink. So the heatsink needs to be about (115-25)/75 - 1.5 = -0.3 degC/W -- in other words it can't be done!
A 10V transformer would be better, but it still wouldn't work.
Maybe if you used the TO-3 versions of these devices AND the lower voltage transformer... you would need a 2 degreeC/W heatsink FOR EACH DEVICE.
This is a 2 degC/W heatsink...
http://www.digikey.com/product-detail/en/HS14/598-1373-ND/1761997 <-- you need three of these!
This is why you do calculations before you design stuff.
I would now recommend a switchmode power supply.
