It's easier to use a voltage doubler or tripler that it is to find a
multi-section former off-the shelf. The occasional high voltage power
supply that I've dismantled clearly used proprietary formers, as do the
Coilcraft parts

I suppose one could use self-bonding wire to make a series of
self-supporting pancake windings, but I've never heard of anybody doing it.

The Baxandall configuration is definitely a resonant trick, and copes
with the interwinding capacitance by resonating it with the winding
inductance.

There's nothing "low current" about it, but if you are working at higher
currents and powers you can justify even more elaborate switching
arrangements.

http://sophia-elektronica.com/Baxandall1959JM.pdf

Jim Williams talked about it a lot - application notes AN45, AN49, AN51,
AN55, AN61, AN65 - but described it as a "a current driven Royer
inverter" which is simply wrong.

MOSFETs work better as switches than bipolar transistors, and don't seem
to "squeg".

A C-W multiplier gives DC.
I think CCFLs should use AC not DC, to prevent fast blackening of one end.

Arie

I sometimes use an autoflyback stage with a DRQ-series dual inductor,
followed by a c-w multiplier using sot-23 dual HV diodes. That's cheap
and easy, given a reasonable supply voltage, like 24.

You can also just buy a potted HV supply and move on to design
something else.

There are also potted c-w bricks, but they are a lot more expensive
than buying the diodes and caps.

Custom magnetics only makes sense at high volume, or for real exotica
like transmission-line transformers.

I'm about to embark on a custom tapped inductor and I'm not looking
forward to it. Drawings, quotes, revised drawings, more quotes,
samples, tests, released drawings, MOQs, all that.

Yes, probably better to just wind it with distance between the turns

Interesting article, thanks.

They also reduce the parallel capacitance of the windings, and give you
are higher resonant frequency for the transformer as a whole.

"Layer stress" and "section stress" aren't specific electronic
engineering terms, and the "v/n" limit of the core is pretty vague.

There is a volt per turn limit imposed by the magnetic field that
saturates the core - but at higher frequencies you can tolerate more
volts per turn before the core saturates - it's a linear function of
switching frequency, up to the point where resistance around the current
loops inside the core lets enough current circulate to heat the core
above its Curie temperature.
Imagination does seem to be what's being applied here.

There's a least one truly horrible 1969 text book on transformer design

https://www.amazon.com.au/Soft-Ferrites-Applications-C-Snelling/dp/0408027606

and it took me years to realise quite how confusing it was.

Yes, but there will loss associated with the distributed capacitance
between turns, that's why I am trying to reduce that one also
I am actually working on an alternative idea, using 2 CCFL transformers,
since as you write they are normally rated for 1600V. Incidentially, the
1600V is the start voltage, runs steady state at 600V.

The idea is to parallel 2 CCFL transformers primary winding, and series
connect the secondary windings. Then connect the center tap to GND, that
way I get -1600V and +1600V, total 3200V without violating the ratings
of the transformer

I see trandformers claimed for 15kV with 6 sections of loose wound
magnet wire. This is however Chinese consumer marketing kilovolts.

https://www.aliexpress.com/item/1005002225061453.html

Given the ~2mm spark gap it suggests something less than 15kV

I order some similar ones some weeks ago, still waiting for the mail :-)