steenss wrote:That's the key, switching speed. You can build a higher powered PSU with half-bridge, but the pennies you save there cost elsewhere. You'll need decent heatsinking, more bulk storage & larger main transformer. For example a Delta/Newton 350W dual P2/3 era PSU (~2000), employed a 10A bridge, 2x 1000uf primaries & ERL39 transformer all for only 15A@12V & 35A@5V. Now, the VRD specs were quite different then, but when circa 2010 half-bridge designs have 4x1.5A diodes, 2x560uf primary caps & ERL35s all on ATX spec 2.01 PCBs yet tout >20A@12V - call me unimpressed. That's without even looking at the secondary side.
Wester547 wrote:That older Dell/Delta/Newton isn't a single switch forward, is it?
c_hegge wrote:I occasionally pull 250W PSUs from older Dell Dimension 3000 and 4700 PCs (usually Newton). They are single transistor forward, and are often still holding up fine even after 7+ years.
Wester547 wrote:This may sound silly, but... I take it there isn't really such a half bridge design that uses MOSFETs on the primary, is there?
Thanks. I haven't seen that one before.Th3_uN1Qu3 wrote:Yes there is. Look up the L6599D. It's used in some 230W power bricks from Delta (rebadged DAP015D) but it's the same thing. Resonant half bridge with MOSFETs. Efficiency way above 80+. Just because it's not common, it doesn't mean it doesn't exist or can't be done. It's just that driving a double forward is easier.
Well, it was posted on the Badcaps.net forum that considerable modifications would need to be made to the primary circuit of at least a run-in-the-mil half bridge PSU in order to use FETs instead of BJTs. I don't think most half bridge PSUs would take FETs without the linked changes, and as you said, it's easier to use FETs in forward topology than half bridge. I didn't think it couldn't be done, though, which is why I asked. I agree that efficiency is important, but so long as it's above 70%, other things matter to me lots more, like the amount of ripple in any given design. TO-247/TO-3P parts obviously have the advantage of covering more surface area when it comes to heatsinks (their ability to conduct heat away) and power dissipation. Speaking of resonant half bridge and those ST FETs, though, I have read that there are in fact BJT/MOSFET hybrids...Th3_uN1Qu3 wrote:Wester547 wrote:This may sound silly, but... I take it there isn't really such a half bridge design that uses MOSFETs on the primary, is there?
Yes there is. Look up the L6599D. It's used in some 230W power bricks from Delta (rebadged DAP015D) but it's the same thing. Resonant half bridge with MOSFETs. Efficiency way above 80+. Just because it's not common, it doesn't mean it doesn't exist or can't be done. It's just that driving a double forward is easier.
I remember reading that. Not sure if you'd be able to do the same thing with an 115V input as that would be less efficient but yes, cooling does make a big difference, so does hugely overspec'ing the secondary side, as you have said before. In fact, that probably makes the biggest difference and that's probably how the commonly known OEMs design PSUs such that they are not stressed and last a while even with underpar capacitors - hugely overengineer the secondary side. That is probably where the efficiency really is affected, though I think the primary side matters lots too, like the "On" resistance specification of FETs and the input capacitors, etc.Th3_uN1Qu3 wrote:Even the old 13009s in TO-3P can put out some decent power if you know how to use them. I've pulled 650W from one pair, with only a regular 80mm fan for cooling. And they did that for hours, at 35C ambient temp. They didn't blow - i just turned it off because it got unbearably hot in the room from the load resistor. I did that 2 years ago.
I can believe it with full bridge.Th3_uNQu3 wrote:I also know of someone who did 4kW with a full bridge of 'em, but can't verify the story.
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