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Re: [TCML] Tesla Digest, Vol 132, Issue 6

Look up a Baker fan to get the idea. This is just an axle with two or 4 flat paddles on it. As it rotates it generates wind resistance and will consume all the horsepower based on size and rpm. This principle is used as governors in music boxes and larger versions were/ are used a loads for tractors. The rotor on a spark gap will generate wind resistance and load the motor. If the gap is synchronous, the motor has to be big enough to run at a constant speed based on the rotor design and size. Even a asynchronous gap will require a proper size motor to spin it as if an AC motor is used as the motor still has to run at its rated speed or it will draw too much current if it cannot to get up to speed. As the size of the spark gap increases and the number of flying electrodes, the gap will require xxx horsepower to spin it at rated rpm. No real way to "calculate" the horse power because of too many variables and more of a trial and error. 

At 03:30 PM 22/11/18 -0800, you wrote:

Hi Steve,
Windage is the biggest issue. The Fan Laws [ https://en.wikipedia.org/wiki/Affinity_laws ]are merciless as you scale rotor size, speed and # of rotors. Even with aero shrouding, Electrum took 28.5 HP on the 30HP gap motor. 


On 11/22/2018 2:03 PM, tesla-request@xxxxxxxxxx wrote:

From: Tedd Dillard<tedd.dillard@xxxxxxxxx>
To: Tesla Coil Mailing List<tesla@xxxxxxxxxx>
Subject: Re: [TCML] Tesla Digest, Vol 132, Issue 5
Message-ID:
        <CABebsSmOTy+syG067FzyQN+mAkJep0PMKOT4hjT7PGU9sDby7A@xxxxxxxxxxxxxx>
Content-Type: text/plain; charset="UTF-8"

Greg,
I am missing something, please help me understand sir.
I do not understand why the rotary spark gap motor would necessarily need
to be so big as the size increases.
The diameter of the rotor would get bigger and so the weight would also
increase so the starting torque would also increase.
But as there is no mechanical friction involved the only power increase it
seems would be the increased windage from the rotating parts.
I can see maybe 5 horse power or so and if the motor is a regular induction
motor modified to be a synchronous motor there would be a loss of torque
due to the increases air gap but I must be missing something. So getting it
going could be an issue but once it was up to speed where is the large
power going?
Teddy

On Wed, Nov 21, 2018 at 5:20 PM Greg Leyh<lod@xxxxxxxxxxx>  wrote:


>Hi Steve,
>
>Turns out that IGBTs become easier to deal with than rotary spark gaps
>as the coil scales in size.  Here's a few reasons:
>
>a)  The freq drops with increasing size, and in the lower 10's of kHz
>range the bigger traction IGBTs start to work quite well.
>
>b)  The motor size on a rotary gap starts getting rather unwieldy at
>higher power levels.  Electrum needed a 30HP motor.  This 40ft coil
>would need almost 100HP... not a very portable rig!
>
>c) IGBTs can work at much lower impedance, typically a small fraction of
>an ohm, compared to many ohms for spark gaps.  That allows this coil to
>work with primary voltages <1kV.  Electrum was 44kV, and this coil would
>have to be 60-80kV for a rotary gap system.
>
>Since I had no funding, this scale prototype design had to pursue
>cutting costs as far as possible.  IGBTs provided the best value
>overall.  However, I totally agree that a rotary gap system for 240kW
>service would look much cooler than a box of IGBTs.  ;>

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