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Hello, here is my PSU design, please comment/advise.
I have built a prototype and tested it with small transistors (not high power ones yet). It seems to work OK. My output transistor blew when I shorted the output (during testing). The current sense circuitry works well, but I had a capacitor at the base of the switch-off transistor (2.2uF) which probably made it too slow to protect the output transistor (doh!)
So my current testing/problems are:
(1) will the protection circuitry be quick enough to save the output transistor? Or do I have to select the output transistors carefully to withstand huge current spikes? Or do something else?
(2) the input sawtooth like ripple (sometimes 300mV peak to peak) hits the output transistors directly (without going through the LM317 first) and a capacitor at the exit completely eliminates the resulting output ripple. However, I am wondering if there is a better way to eliminate this ripple. When I say "eliminate" I mean what I can detect with my oscilloscope which goes down to 5mV per division. With the output cap I get a vague flat trace at 5mV, without it I get about half the input ripple (so from 300mV at the collector to 150mV at the emitter) and what's worse I get funny instability when I touch the collector. The output capacitor seems to completely eliminate these two problems, but I lack in theory so may be other factors are there unknown to me.
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The design went like this: take the unregulated DC from the bridge/filter and put a transistor in common collector configuration in series (so all current goes through it) and make sure you give it a stable voltage at its base no matter what the supply is. To obtain this "stable voltage" I could use a zener but with prices what they are I used an LM317 which also allows me to adjust the output voltage.
The LM317 is man enough to feed the output directly, so what's the point of the extra transistors? Well, the LM317 will do 1.5A and I want in excess of 5A, and what's more I want 5A at say 3V output - with a 35V DC input that means we would have to expend 32*5=160Watts somewhere.
So I decided to use the pass transistors but not in the way shown in the LM317 datasheet. In my configuration the LM317 does not feed the output directly, so the onus is on me to protect the output transistors from shorts as well as deal with the ripple voltage.
Edit: the output voltage is adjusted with a dual gang pot 10K each in parallel to minimise errors and again in parallel with an 11K resistor (all to minimise errors).
Edit2: I have a problem with the two output transistors: it seems one is bearing all the load whereas the other is taking less load. I have just almost burned my finger trying to see which one (if any) were hot during a shorted output test case (ok they are not mounted on any heatskink so they are not sharing the heat). How to solve this problem? Place very small resistors at the emitters to create some feedback which will "hold back" the runaway transistor? Or just use just one hefty output transistor?
I have built a prototype and tested it with small transistors (not high power ones yet). It seems to work OK. My output transistor blew when I shorted the output (during testing). The current sense circuitry works well, but I had a capacitor at the base of the switch-off transistor (2.2uF) which probably made it too slow to protect the output transistor (doh!)
So my current testing/problems are:
(1) will the protection circuitry be quick enough to save the output transistor? Or do I have to select the output transistors carefully to withstand huge current spikes? Or do something else?
(2) the input sawtooth like ripple (sometimes 300mV peak to peak) hits the output transistors directly (without going through the LM317 first) and a capacitor at the exit completely eliminates the resulting output ripple. However, I am wondering if there is a better way to eliminate this ripple. When I say "eliminate" I mean what I can detect with my oscilloscope which goes down to 5mV per division. With the output cap I get a vague flat trace at 5mV, without it I get about half the input ripple (so from 300mV at the collector to 150mV at the emitter) and what's worse I get funny instability when I touch the collector. The output capacitor seems to completely eliminate these two problems, but I lack in theory so may be other factors are there unknown to me.
******************
The design went like this: take the unregulated DC from the bridge/filter and put a transistor in common collector configuration in series (so all current goes through it) and make sure you give it a stable voltage at its base no matter what the supply is. To obtain this "stable voltage" I could use a zener but with prices what they are I used an LM317 which also allows me to adjust the output voltage.
The LM317 is man enough to feed the output directly, so what's the point of the extra transistors? Well, the LM317 will do 1.5A and I want in excess of 5A, and what's more I want 5A at say 3V output - with a 35V DC input that means we would have to expend 32*5=160Watts somewhere.
So I decided to use the pass transistors but not in the way shown in the LM317 datasheet. In my configuration the LM317 does not feed the output directly, so the onus is on me to protect the output transistors from shorts as well as deal with the ripple voltage.
Edit: the output voltage is adjusted with a dual gang pot 10K each in parallel to minimise errors and again in parallel with an 11K resistor (all to minimise errors).
Edit2: I have a problem with the two output transistors: it seems one is bearing all the load whereas the other is taking less load. I have just almost burned my finger trying to see which one (if any) were hot during a shorted output test case (ok they are not mounted on any heatskink so they are not sharing the heat). How to solve this problem? Place very small resistors at the emitters to create some feedback which will "hold back" the runaway transistor? Or just use just one hefty output transistor?
Attached Files
Older versions of the datasheet had many more application circuits, all the way up to a precision current limit with a LM301 op-amp (now obsolete too)
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