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COILBLD1.TXT
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To: tesla-at-grendel.objinc-dot-com
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Subject: COILBLD1.TXT
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From: richard.quick-at-slug-dot-org (Richard Quick)
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Date: Mon, 27 Nov 1995 06:17:00 GMT
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REVISED AND UPDATED 11/26/95
Text file for COILBLD1.GIF, graphical instructions for
construction of high performance 1/4 wave Tesla resonators.
1) The first step in winding a coil is to select a coil form.
The coil form should be a low loss material (we are talking
about radio frequency losses in the 50 - 1000 kHz range) like
polyethylene, polystyrene, or polypropylene, polycarbonate
(Lexan), acrylic (Plexiglas), or even ABS: but the most common
material used from the standpoint of cost and availability is PVC
(poly-vinyl-chloride), which is VERY HIGH LOSS. PVC may be used
if the material is properly prepared before winding on wire.
Regardless of the material selected, the thinnest possible coil
form should be used; avoid heavy walled or pressure rated tubing.
The ratio between the actual winding length and diameter is im-
portant. The ratio of the winding length to the winding diameter is
known as the ASPECT RATIO (height : diameter), where the diameter
always equals 1. Aspect ratios may be expressed by a single number
such as "3.21". Please review the simple chart below when selecting
a coil form and the proper wire gauge: (All dimensions are in U.S.A.
measurements, inches, feet, AWG, etc..)
Coil Form Diameter Aspect Ratio Winding Length
3 inches 6:1 18 inches
4 inches 5:1 20 inches
5 inches 4.5:1 22.5 inches
6 inches 4:1 24 inches
7 inches 3.5:1 24.5 inches
8 inches 3:1 24 inches
larger than 8 inches 3:1 multiply the coil diam. by 3
This chart is based upon the physical characteristics of the actual
winding. Do not assume that "six inch PVC drain pipe" actually
measures six inches o.d., and be sure to allow a few inches of
extra coil form length. When selecting and cutting the coil form
you should allow at least an extra inch of coil form on each end,
and I generally figure on cutting the coil form three inches longer
than the actual winding length. After determining the length of the
coil form required, measure twice, then cut. Make sure that both cut
ends are square.
2) The coil form must be free of major surface imperfections. I wet
sand my coil forms with #150 wet/dry sandpaper (or emory cloth) and
water to remove markings, oxidation, scratches and cuts. After wet
sanding, the coil form must be dried thoroughly. If PVC plastic is
used the coil form should be dried in a drying box, gently baked
under a heat lamp, or even placed in a very low temperature oven for
a few days. PVC coil forms must then be sealed to negate the high
RF loss factors that are inherent to this plastic. Sealing also pre-
vents PVC plastic from reabsorbing moisture. Using a sealer such as
petroleum based polyurethane varnish, two-part clear epoxy paint, and
some acrylic spray sealers is important. Avoid water based and milky
"emulsion" type sealers.
When I am ready to seal a PVC coil form, I mount the form up on a
winding spindle. I work in a well ventilated area, and I turn on at
least one fan to keep air moving over the work. I set up a few heat
lamps or other spark-free radiant heat source. Then I begin a four
hour coating process. I prefer a high-gloss polyurethane or epoxy
sealer applied with a good varnish brush. Sealer is slopped on while
the coil form is spun. I use the brush to apply and smooth the heavy
coats, and to spread out drips and runs. Coats may be applied almost
continuously in this fashion for an hour or two. After coating the
coil form, it should be rotated on the winding spindle for a few hours
while radiant heat and moving air are used to speed a cure. Using this
method it is possible to build up a high-gloss finish which is free of
runs, drips, and sags. If drips and sags do occur, then can be "grated"
off with a body putty grater, or carefully trimmed away with a knife
while the sealant is still pliable.
3) The coil should be close wound with a good quality magnet wire. I
use double Formvar enamel coated magnet wire purchased surplus, but
newer insulations such as Polyimide coatings are even better. Magnet
wire gives the maximum inductance per unit volume of coil form. The
coil should have over 800 turns, but not too many over 1000 turns.
There is a little leeway here. Use the thickest gauge of magnet wire
that will allow the correct aspect ratio, and between 800 - 1000 turns.
It has been suggested that all coils be wound with at least No. 22 AWG,
or larger, magnet wire. I would concur with this recommendation.
I plug the ends of the coil form with a tight fitting wooden disk and
run a dowel or threaded rod through a center hole so that it will spin.
I set up the wire spool so that it will spin at one end of a pair of
sawhorses, with the coil form at the other end. I wind the wire on by
hand, making sure the windings are close-wound, tight, smooth, and even.
Overlaps and gaps will adversely affect the performance. I use a dab of
hot glue, epoxy, or tape to hold the first turns in place, and I make
sure to leave a 3 foot tail of wire at both ends. Do not drill holes or
permanently route wire inside of the coil form.
ROUGH FREQUENCY CALCULATIONS:
Assuming the information given in the text and chart above is used,
a rough calculation of the resonate frequency is given below. In the
chart below: OD = outside diameter in inches, Wire Gauge is in AWG,
TPI = turns per inch, Turns = total number of turns of wire on the
coil, Resonate Frequency is given in kilohertz and the figure is
approximate only.
Coil Form OD Wire Gauge TPI Turns Resonate Freq.
3 22 37 666 840 kHz
4 22 37 740 540 kHz
5 22 37 832.5 380 kHz
6 22 37 888 290 kHz
7 22 37 906 238 kHz
8 22 37 888 206 kHz
9 22 37 999 163 kHz
10 21 32 960 152 kHz
You can see by reading through the text and looking at the charts
that some design problems occur in coils with a small outside dia-
meter. Coils under five inches in diameter must make sacrifices:
either they must get long and skinny to obtain a sufficient number
of turns; or they must be wound with smaller diameter wire. When
making this decision, after determining that a larger diameter coil
will not be satisfactory, it must be understood that 75% of the
voltage produced by a 1/4 wave Tesla secondary results from pure
resonance; meaning that the "ratio of turns transformation" calc-
ulated with the primary coil is not responsible for the majority
of voltage gains: go with heavier wire as I have indicated rather
than additional turns. On small diameter coils the aspect ratio may
be increased somewhat rather than sacrifice turns or wire diameter.
COILBLD1.TXT 11/26/95 Graphics and text prepared by:
Richard T. Quick II <richard.quick-at-slug-dot-org>
10028 Manchester Rd
Suite 253
Glendale MO 63122 USA
*************************************************************************
FREQUENTLY ASKED QUESTIONS:
> Question:
> How would someone go about drying a PVC or similarly hygro-
> scopic material before it was to be sealed? In the oven? What
> temp? Is the interior of the form sealed as well?
Before I get to the drying stage, I go ahead and wet sand the
coil form with abrasive paper or emory cloth. I use a #150 grade
of abrasive and sand with water until all printing, oxidation,
and major dings (cuts and scratches) are removed.
One of the best ways to dry this plastic is to get a large
cardboard box. Cut a few small vent holes in the top and bottom
of the box. Thread some string or light cord through the top of
the box to form a sling to hold the coil form. You will need two
or three loops of cord inside the box to securely suspend the
coil form near the top vent holes.
Place a light bulb on a heat resistant insulator inside the box
directly below the coil form. Depending on the ambient temperature,
the size of the box, and the number of vent holes, the wattage (or
number) of bulbs may be varied.
The heat from the bulb(s) will produce a warm air convection inside
of the box that will effectively dry the coil form over a period of
no more than three days. The temperature does not need to be very
high, temperatures between 120 - 150 degrees F are just fine.
Once removed from the drying box, the outside of the coil form
should be sealed immediately, then wound with wire. Once the coil
form is wound, the ends of the coil form are capped with plastic
disks glued down with epoxy to form a hermetic seal.
However, if the coil form is removed from the drying box and
winding is delayed for some reason, one coat of sealer should be
applied to the inside of the coil form to prevent moisture from
reabsorbing. If the winding proceeds at an orderly pace without
delays, then the end caps will prevent air exchanges which
removes the need to seal the inside surface of the coil form.
> Question:
> Besides polyurethane what is a good sealer for a secondary coil
> form and and where do I get this sealer?
Quoting Chip Atkinson:
The coating that I used is called
Super Gloss
Build 50
by Behr.
I got it at the hardware store. (Hugh M. Woods, aka Payless Cashways)
It is in two paint cans, shrink wrapped together. The can wrappers are
orange. The stuff is stocked in the varnish section, right next to the
polyurethane. The potential problems are bubbles, which didn't seem to
make much of a difference for me, and annular bulges. The bulges appear
if you don't get the coating on evenly and the form is turning. I would
not recommend using Build 50 as a coating unless you feel confident in
your abilities to apply it smoothly and evenly. I ended up with some
bulging, but it doesn't detract from the over all appearance. It would
however cause problems if one used it to seal a PVC pipe under the
winding. This would make the windings irregular and probably cause the
top coat to be very uneven as the stuff bulges and climb towards the
high spots as the form turns. Nevertheless, I still recommend Build 50
since it goes on in one coat and is quite tough and hard. Chip Atkinson
Question:
> I got the 8" PVC today. Cost me $7.00 for 3 feet. It is solid wall
> about 5/16" thick. I am going to setup something to dry it later
> today. I got a basic polyurethane varnish to coat it with.
No problems here. The coil form could be thinner walled. I always
try to use the thinnest walled material possible for my coil forms.
> You said you did not want to put any holes on the coil form if
> necessary because of moisture seeping in. What about throwing a couple
> packets of silica gel in before sealing it up? Or maybe some other
> dessicant?
Holes in the coil form are avoided primarily because holes compromise
the electrical strength of the construction. The fact that a properly
sealed and capped secondary coil prevents re-absorbtion of moisture
when using properly dried and prepared PVC is an added bonus. Desiccants
such as calcium sulfate, silica gel, etc. will simply trap water. I
would not use these desiccants with the idea that these compounds are
going to end up as permanent parts of the coil. Desiccants can be em-
ployed as part of the drying process if desired, but these compounds
should be removed (along with any absorbed moisture) and not left as
part of the sealed construction.
> Oh, how did you cut the plexiglas disks in a circle?
I use a band saw or a jig saw. A plastics dealer will be able to custom
cut these disks if required, and the same plastics dealer is usually
able to supply the correct blades and cutting advice if you ask.
> And what about using a Silicon RTV type cement to attach the ends.
> This stuff is deffinitly non-flamable and is hard to screw-up with.
Good Question!
Sounds great does it not..? But... These adhesives leave a residual
acetic acid vapor which is trapped in the coil form. The acetic acid
vapor is highly conductive and ionizes readily. DO NOT USE THESE
PRODUCTS in this particular application.
> I am also going to order the wire today. What gauge should I use?
I would used about 888 turns of number 22 AWG enameled magnet wire.
You will need about 3.75 pounds of wire to complete this project, so,
figure on buying four pounds of No. 22 AWG enamel covered magnet wire.
Richard Quick