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Re: [TCML] 20KV primary drive voltage tips ?



Hi Gary,

15/30 NST's are commonly used with a sync RSG. So a simple 15kV NST is out of the question?

Well other than cost and actually locating one, would be far easier just to use a NST which could peak to 20KV, I only have 10KV so choke charging would be the only option.





I know my 10KV primary is spaced out about 0.5" so I assume a 1" gap between
turns will be needed ?
No, you should be just fine with 0.25" between turns. A 1" gap will make the primary needlessly large.

I'm not so sure, 0.5" was about the min distance I could cope with with 10kv.. I am hoping not to need a great number of turns also






The 20KV drive should help spark gap quench times ?
I don't know that I've heard that bang voltage correlates with quench time.
Ideally I want to aim for 1st notch quench and keep the transfer cycle time
to 3 cycles maximum( so >0.3K needed)

Quenching suffers as K is increased. It's not even clear that first notch quench is the best thing for streamer production. And running with a K of 0.3 is simply unrealistic. >You'll get racing sparks long before achieving anything close to that.

It the same issue I think as increasing the tank size, too much current/heat effecting quench times. A higher voltage over current shouldn't heat the gap and as there is physically a larger gap, should quench better... AFAIK..

20KV will probably suffer from corona on the primary, but that will have to
be delt with if/when it happens.
I've never noticed any.

Well thats a good sign then. Was some conflicting views on this a while ago.





I also want to keep the coupling as tight as possible. Going by my
simulations 0.38K seems to be the maximum before hitting problems. Also
should a cone or vertical primary be used ?


What simulator predicts coupling problems? Predicting racing sparks is one of the unsolved mysteries of coiling. I'm unaware of any method of predicting it beyond noting >the experience of many coilers, where coupling much above 0.15-0.20 seems to be unmanageable.

http://www.future-technologies.co.uk/IMPULSE/simulation.htm

coupling tests are there, though I did a 0.45K simulation as it showed up the problem a lot more than a low value. 0.38K appeared to be the maximum before the strange humps in the waveforms.



A vertical (helical or solenoid) primary is typically shunned in favor of a flat spiral primary, for the very reason of having TOO high a coupling.

Understood, but if I do go for higher coupling then it could work out better for me in that respect.


Onto the key points now, the last system I built was 500khz 10KV, so 20KV
should allow a 1mhz coil to be used.  Really its half the inductance and
double the voltage input to get the same spark output. A bit of a long story
for another day that one!

I don't follow your logic. The experience of most successful coilers is that larger coils make for bigger sparks, and that larger coils inherently operate at lower frequencies.

True to a point, though there was a huge talk about this on the list not to long ago. That area of coiling has been "done to death" already. I am seaking a new direction based on my own ideas. Fail or not, im going to do it anyway ;-)


I am aiming for 1ohm DCR on the secondary. the larger dia wire should help
with the running at 1mhz.

The DC resistance of the secondary is of little importance, given that the load (streamer) impedance is many orders of magnitude higher. AC resistance will be far higher, >especially if you're talking about 1MHz, but I still don't think it's a major consideration.

True, but I am going to do it anyway.



The secondary form will be 6.3" dia and about 50-60" tall. A lot of figures
to crunch up and some compromises no doubt.

Yours would be considerably more candle stick-like than most well performing coils.

True, my coil could be made better though I am more into alternative "fun" with coils than producing long sparks.






The design is to start at 500watts input power as before, keeping the
secondary size physically the same size, but just using a larger dia wire. Will run at a higher frequency and have less turns/inductance hence the need
for a 20KV input.

I'm not sure that the secondary geometry cares what the primary bang voltage is. One typically sizes the secondary by the bang-SIZE.

The idea was based on some tests I did years ago, during SSTC work among others. I built so many coils and tested so many aspects of the coil. Really twice the voltage and half the inductance is not hard to accept or understand. Not saying thats solid exact fact but trying to keep things as simple as possible to give a overview of my intended design.

I hope this helps!

All input is of course welcome :-)

I think probably that most will think its a waste of time and won't work, but I've done the "dead end" road already and want to have some fun with what I think will work out as higher Q systems. I think the data collected from the experiments will be nonetheless very interesting. Its a lot more interesting to experiment with ideas then just going to build a large dia/inductance coil like everyone has been doing for the past 50 years or so ;-)

Chris




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