160v/8a

[megajocke]

How long is the switching time now? I can't see any leakage inductance spikes so I'm guessing it's a bit slow - which will make all energy stored in the leakage inductance of the transformer be dissipated in the transistors.

 

[Fob]

100kHz. There is no spikes becouse of snubbers. Without them I have ~1MHz 600-700V overvoltage. Temperature is 60 'C on radiator with 175V/2A load for 1 hour. I can achieve 7A, but with too hot transistors.

 

[Eva]

Think about it, there is nothing wrong with the offset.

 

[megajocke]

What I meant to ask was how long the switching lasts, that is, how long is the time when voltage is rising/falling when transistors turn on/off.

What snubbers do you have right now?

 

[Fob]

~350nS rising, 300nS falling. Here is output waves.

 

[megajocke]

That sounds a bit slow.

How long is the on time per transistor?

Is 100kHz transformer frequency (200kHz output ripple frequency) or output ripple frequency (50kHz transformer frequency)?

 

[Fob]

100kHz 220V rectified pulses before output inductor. I draw circuit with pen.

 

[megajocke]

So the on time is about 5µs then?

With 600ns total switching time for a 5µs on time you might have upp to 10% of output power in switching loss. I believe you'll have to speed up the drive to the fets if you want lower losses.

 

[Eva]

But faster switching requires a better PCB and overall layout, low inductances, damping of parasitic resonances, ground plane, etc... It's always the same compromise.

 

[megajocke]

Of course 🙂

Another way would be to lower the frequency and/or trying to get higher duty cycle. But maybe there is a good design reason for the ~50% duty cycle, I don't know the application, required holdup, input voltage tolerance and so on.

 

[Fob]

Vin(DC) 250 - 330V
Vo 160 - 200 adj
Io 6-8A charge current for 13-15 batteries in series (DC UPS)

This will drive old russian 100V motors, 300-500m cable, hard losses, disipation etc. Here is the driver