Thanks Duncan.
f=w/2pi


So to know the exact capacitor one have to know inductance and frequency yes?

unless you have a nice variable HT supply like Mr Clean .. yes
but normally get very close and then alter the coil connection slightly XL is the way to go.

Whilst I'M not hyping this company in particular ,, I would seriously think of working along the same lines lines (or some thing similar) / Its relatively cheap and its the foundation of Mr Cleans circuit . ( which you’ve seen working) As you will see It has the advantage of a variable frequency HT power supply this company sticks you £50 for the unit but the schematics there and a 555 will cost buttons .. with a variable frequency supply you can tune anything to anything (within reason) couple of coils from the scrap yard .. It makes sense XL is directly proportional to frequency and XC is indirectly proportional to frequency so get some where near and then hit the nail right on the head by altering the frequency slightly.. takes a lot of the hassle away
RMCybernetics - DIY Mini Tesla Coil

I was simply pointing out what the mechanism is that sets the secondaries in motion. The event in my test was simply an extreme example of what is going on, smaller devices obviously would operate on a much smaller pulse.

Dumping a .005uf cap at 5000 volts into a coil of say 50uh would give you a pulse of around 50 amps depending on the coil and it's internal resistance as well as the capacitors characteristics.

With a loose coupling a reasonable portion of the amperage would be transferred to the secondary coil(s). We want to contain the primary event in the secondary oscillator and allow the secondary to "freewheel" at it's natural resonant frequency. This is where tesla states that an "activity" in excess of the input is created. Not overunity - an activity...

The primary tank, if constructed and tuned precisely, will require only the initial input and enough to cover any losses that are inherent to the system then it simply recycles the amperage. This activity is transferred to the resonant secondary which operates in a similar fashion.

The problem arises when power is to be extracted as any load you place on this "freewheeling" activity will alter the parameters of the circuit. An example would be to measure a standard transformers inductance with no load then measure the same with a resistive load on the secondary... the inductance is changed considerably which means you have to back to the beginning and retune the entire system to that particular load. This makes the resonant system quite proprietary to it's output.

In order to make it less dependent on a load you need to separate the input and output. This is typically where the problems arise and you start playing the "time" game - that is charging caps at HF and discharging small amounts at a lower frequency. Tesla also stated you can only remove that amount of it's natural accumulation. Keep in mind the cap/inductor discharge also applies to output circuits as well.

If you look at Don's original drawings, he was depending on the primary tank circuit as the only resonant portion of that circuit, the output coils were simply set up as a full wave rectified output to charge capacitors then to be discharged through an output transformer via inverter circuit, most likely a distribution transformer. This tank circuit had to be precisely tuned to the charging load presented by it's secondary system.

Dealing with the output is definitely a challenge... I put together a rotary spark gap inverter to discharge the storage caps through a distribution transformer. My tests with this so far has proved to be one possible solution. Below a schematic of a basic spark gap inverter and the rotary device I built for testing the idea... I used a MOT in reverse which isn't the best choice as I'm limited to input voltage but it proved this would function as expected. I'd like to build a commutator make and break with some adjust-ability in the pulse width.

Considering the action that takes place in the cap/inductor discharge where you loose 90% of the voltage to convert to amperage you can come fairly close to calculating the output side to get a more useable voltage without all the conversions. As an example, say we have a 10 turn primary that we dump 5000 volts into and 90% is converted to amperage leaving 10% of the voltage intact or around 500 volts. Divided by 10 turns we have 50 volts on each turn which is transferred to the secondary coil. We need, say, 250 volts for our output inverter so our secondary would be at or around 5 turns. Most likely slightly higher factoring in the loose coupling. Basically, we need maintain as much amperage as possible cycling in the primary tank, tuned to reduce input requirements as much as physically possible, so the transfer to the secondary maintains a reasonably high amperage with the voltage level needed in our output. Inductive heating circuits are good ones to follow for the primary tank. Tesla mentioned briefly that when he placed a foil in close proximity of his primary coil it would disintegrate instantly giving us a good idea of the currents circulating.

I'm playing with a few ideas that should show this whole process can be done at a much lower voltage. Remember, we aren't building the classic tesla coil here.

If you need help with building Tesla coils i can recomend the guys at www.telsauniverse.com chat room. They live and breath 'Coiling'. Just don't mention ou devices at all. They are so helpful as long as you don't try and educate them on ou. They get really funny with you if you do.

Hey Mr Clean, why don't you measure your amperage output by blowing car fuses?

like charge up caps and detonate them thru some fuses? cool!
ok i'll do that right now

Those scrap yards make me feel like a kid in a toy store ! Great find. The biggest problem I've found with the MOT's is they need a voltage much higher than they can handle to bring the output up to a useable level. Good for testing but I don't believe they would handle a final design. A nice small 15kv pole pig would definitely fit the bill or something custom made and oil filled.

There are some interesting video's on youtube showing how the distribution transformers are made. Wouldn't take much to make up smaller units for our purpose.

I fully agree that the output is almost more important than the input circuit. Charging the caps is a fairly easy task, dealing with the HV output is considerably more challenging.