Re: [TCML] Science Fair Project

[Jim Lux <jimlux@xxxxxxxxxxxxx>]

On 11/16/12 10:49 AM, mrapol@xxxxxxxxxxxx wrote:
> One way to vary the output by focusing on one component might be with
> the spark gap:
>
> simple spark gap
> multiple spark gap
> quenched spark gap
> magnetic quench
> 'hyperbaric' gap with air blown through or across it, etc.
>
> PBT

This is a good experiment, but has some problems in the science fair 
context. And it depends on what level fair you're competing at.. 8th 
grade school vs county, state, or ISEF, because the judges are 
qualitatively different and look for different things..

I'm going to comment here on the assumption that the ultimate judging is 
at the state or big county fair level or bigger, so if you're not in 
that class, then you can ignore a lot of what I have to say.

The issues with this have to do with the hypothesis and quantitative 
aspects..  That is, a "cut and try" or "we tried 6 different things and 
#3 worked best" doesn't do well, because it's not science nor 
engineering: it's random tinkering. That is, you want to avoid getting 
the result (e.g. quenched gap works best) and not know *why* it works 
best, or if it might have worked best because of some other factor.


To be a winner, there has to be an element of applying theory to predict 
behavior, and experiment to see if it matches theory.  And ideally it 
needs to be quantative, preferably on a continuous basis (that's just 
because of bias on the part of judges that prefer it)

Remember, science fairs are about winning the fair, not necessarily 
advancing the state of knowledge, so there's some peculiarities of the 
process that need to be addressed.


OK.. to the specifics of why this particular experiment would be hard to 
do well (although it *can* be done, and done well)

1) you'd have to make measurements on the gap by itself to determine the 
electrical properties.  For instance, you'd need to measure the voltage 
drops and currents.

2) you have to have a model of tesla coil performance, where you plug in 
the measured (or predicted) properties of the gap, and make a 
*prediction* of the performance of the coil.

This is the *key* to the whole hypothesis thing.. you have to have a 
predicted outcome based upon theory and prior measurements... then you 
go do the experiment and see how closely theory and experiment match. 
Then you do some statistical analysis to see if the difference is 
*significant*.

If you don't do this, then your project is a "cut and try", and no 
different from the "does rock or classical music make plants grow 
better" kind of thing.


Now, if you can come up with some way in which the various gaps affect 
the performance: maybe their quenching behavior is different, and you 
have quantitative theory as to why quenching affects spark length.  Or, 
maybe it's just about loss.  You feed 200 watts into the coil system, 
and gap 1 has 50 watts loss and gap 2 has 100, and lo and behold sparks 
are longer with gap 1.. But to make it good, what you should be able to 
do is reduce the input power with gap 1 down to 150 Watts (same 100 
watts after gap losses) and get identical power output.


There is also a problem with Tesla Coil projects in general.  You're 
being judged against other projects in your category.  It might be 
"Engineering" so you're up against everything from wind turbines to 
robots to solar power collectors, etc.    So you need to distinguish 
your project from the other neat and nifty things..  the way you do that 
is with theory and math and statistics.

What the judge really, really wants to see is that you did some research 
ahead of time, and were able to make a quantitative prediction of 
outcome based on theory.

Even worse is if you are being judged up against more "classical hard 
science" kinds of projects.. biology or medicine, where they are looking 
at comparing the effects of varying concentrations of a substance on 
something growing in a petri dish.  The engineeringy judges have no 
problem judging the biology project: they look at experimental methods 
and statistics.  The biology judges, on the other hand, have a tough 
time fairly judging engineering projects:  they're looking for things 
like "control groups" and "null hypothesis" and "Chi-square analysis of 
significance"

Science judges also like to see experiments where there is a "dose 
response" effect.  That is, rather than discrete effects from something 
being there or not, they like to see a continuum:  setting the knob to 
zero does A, Setting it to 1 does A+B, setting it to 2 does A+2B, etc. 
(or square law or something predictable)



So it's a challenge to come up with a good project using a tesla coil 
where "performance of the coil" is the variable.

Now... one thing that might be good is to use the Tesla coil as a part 
of an experiment.  Maybe you are developing a way to measure the 
electric and magnetic fields of a HV source?   Could you figure out 
whether there is really an "ion cloud" around the top load?

What about studying spark growth?  Some video cameras these days have a 
high speed frame rate option (slo-mo), and you could see how the spark 
grows on successive "bangs".  the theory is a bit complex, but it's doable.


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