Andrew’s quite correct – anything can go wrong if you screw up the design… and yes there are load conditions you could apply to a 78xx output that can screw with its stability if you don’t design it right. All I’m saying is that if you follow the rather simple basic rules, a second 78xx isn’t one of them!
Posted by Cornish Jack on 20/11/2011 11:00:21:
Still can’t get my limited brain cells around why THREE Unregulated supplies metered out at 17 volts with each one selected to the 6 volt selection

Before anybody tries to jump down my throat, please bear in mind that I’m trying to keep this conceptually understandable, but not necessarily technically complete:
You have to consider what a ‘lack of regulation’ actually is. Put simply, in this case it’s the degree of ability of a power supply to go on supplying more and more current at any particular stated voltage. So for practical purposes, it’s a measure of voltage ‘droop’ under load. Invariably how good the performance of a transformer is depends entirely upon its physical characteristics. So, if you have a heftily built transformer with a dirty great thick secondary winding, and you power it up, you’ll get a voltage reading across this secondary that will droop very little under load – the winding is quite capable of supplying current without the voltage drooping very much, partly because it’s good at magnetically coupling the energy from the primary winding into it, and also because the wire has a good current-carrying capacity.
With your smaller transformer though, it has a very small-scale winding of thinner wire, and although you can measure 17v across the secondary when it’s unloaded, virtually any load at all will make this drop quite significantly. Even though the magnetic coupling inside is still quite good, something else has happened…
The performance in each case is pretty much determined by what’s known as the ‘internal resistance’ of the winding, and although that’s by no means the only factor, it’s probably the most significant one. A low internal resistance usually implies (all other things being equal) that the winding can supply rather more current without drooping than a higher internal resistance would (as per first example). With the smaller winding on the smaller transformer, the energy transfer available is essentially limited by the physical size of the winding wire, which limits its current-carrying ability.
One thing that’s worth noting about devices that have poorer regulation is that they have, to a degree, an in-built safety mechanism – if the load becomes too great, the voltage drops lower. What that actually means is that the current the device can supply is limited to quite a low maximum value, and is less likely to cause collateral damage if anything goes wrong. With a higher current available in a larger winding, an increased load will cause a higher current to flow because the regulation is better – so more energy leaves. Obviously the mechanism is the same in both cases, it’s just the amount that varies.
What an external regulator does is to take your 17v and make sure that what comes out is 6v, regardless of the current drawn. So it’s regulating the voltage, and not the current. In other words, if the current varies within the limits of the transformer winding supplying it, the voltage will remain the same. But, if you try to draw too much current, then the winding still won’t be able to supply it, and the device will shut down.
I hope that makes sense. If it doesn’t, then ask for more explanation!
Regards, Steve
Edited By Steve Garnett on 20/11/2011 12:23:35