"Tesla's Lightning Generators"
"In addition to his many important contributions to electronics, Nikola Tesla gave us
"lightning generators" that to this day fascinate and entertain."
Rewritten by Tony van Roon (VA3AVR), with permission.
Nikola Tesla (1856-1943) was a brilliant Croatian physicist known for his research in the
field of alternating current and motor development. He also had a weakness for ideas and devices that many considered exotic. Among other
things, he postulated that the world could be made to blow up if it's frequency could be determined, locked in, and many to reinforce
itself, and proposed a motor driven by "tachions," particles faster than the speed of light.
He was also obsessed by the concepts of long-distance communications and the wireless transmission of electrical power and spent much
time and large sums of money on his experiments in those fields. At his laboratory in Colorado Springs, Colorado, Tesla built the world's
most powerful radio transmitter. Around the base of a 200-foot mast, he placed an air-core transformer that measured 75 feet in diameter.
The primary consisted only of only a few turns of wire; the secondary was 10 feet in diameter and consisted of 100 turns of wire. Using
the transformer, he generated on the order of 100-million volts. From the 3-foot copper ball on the top of the mast, bolts as long as 100
feet leapt; Tesla had created the first man-made lightning. And with that "Tesla Coil" he was eventually able to a bank of 200
incandescent light bulbs from a distance of 26 miles.
Unfortunately, Tesla's ideas were considered nonsense by most of the reputable scientists of his time. Even today, he receives little
recognition for his many important contributions to electronics and electricity. Chief among those, of course, is his development of
the AC power-distribution system, which is still in use today.
And, of course, there is the high-voltage generator he used for his Colorado Springs experiments. Scaled down versions of that Tesla coil
are popular among experimenters and hobbyists. When treated with care, they can provide hours of fun.
BEFORE you start building! SAFETY CONSIDERATIONS:
As mentioned previously, the primary winding is energized by a line transformer that delivers 5000-10.000 volts AC. Such a
transformer is potentially deadly and should be treated with utmost care. It would be more than prudent to house that transformer in an
insulating plastic case to protect yourself and curious onlookers.
Building a Tesla Coil:
Take a look at the schematic diagram of Fig. 1. Don't let its simple appearance fool you. For the circuit
to work, resonance has to be achieved and that is the catch. When dealing with high-frequency voltages (in the 200,000-volt range) exact
capacitance, voltage, and frequency measurements can be difficult and dangerous to obtain with apparatus that is too expensive for the
average hobby lab. Without that data, resonance formulas are of little help, and trial-and-error-methods can lead you a long way off the
path of success.
Our purpose here, then, is to provide you with a framework that will help you develop your own working Tesla coil; without that framework,
it could take you a long time to develop a good model. With all the necessary materials on hand (more on that shortly), a Tesla coil could
be built in a couple evenings. More likely, however, it will take you over a week of evenings especially if you have no experience in
winding long coils of thin wire without overlaps.
Before we go much further, we must make clear that this article is intended for experimenters. Other articles that have appeared
in Popular Electronics and elsewhere have given step-by-step instructions for building a Tesla coil of a particular design. Our
intension is to provide a starting point for you to develop a Tesla coil of your design. We will present some design criteria,
point out some of the pitfalls that we discovered the hard way, give some hints that will help you along the way, and show you some
interesting experiments to try. The rest is up to you.
Principles of Operation:
As the schematic shows, a line transformer (T1) with a 5000- to 10,000-VAC secondary energizes the circuit.
A heavy-duty hash choke (L1) can be used to keep the high-frequency electrical energy from entering the AC line and interfering with TV's,
VCR's, DVD players, computers, etc. It is not always needed; we do not use one with the type of transformer that will be described later
on when we discuss specific components.
A spark-gap driven resonating circuit (capacitor-coil) produces ragged high-frequency peaks that are extremely well-suited to induce high
voltages in the secondary air-wound coil (L3). Depending on the diameter of the secondary coil, it's inherent capacity can vary greatly,
effecting its resonant frequency. For the maximum transfer of energy, and hence best performance, the primary circuit must be tuned to
match that resonant frequency as closely as possible. That is done via a series of taps in the primary coil (L2) as well as by adjusting
the setting of the spark gap. Properly tuned, a Tesla coil as described here will deliver a high-frequency output in the range of
200,000 volts. Such a voltage will produce a corona--a ball of blue-glowing plasma (glowing gas)--or sparks up to 8-inches in length.
We will shortly describe a series of marvelous experiments that can be conducted with your Tesla coil.
As mentioned before, the primary winding is energized by a line transformer that delivers 5000-10,000 volts AC.
Such a transformer is potentially deadly and should be treated with utmost care. It would be more than prudent to house that
transformer in an insulating plastic case to protect yourself and curious onlookers.
Despite its 200,000-volt potential, due to the high frequencies involved, the secondary winding presents somewhat less danger.
However, while high-frequency current will not penetrate the human body, arcs will find their way to ground on
the surface of the shin, causing burns. Strangely, in our experience no blisters have formed, just little black
holes--and we've had our fair share of them!
The spark gap produces Ultraviolet radiation that can affect the eyes. So, it should be housed or shielded in
some way. You can use a plastic project box of sufficient size for that. the author has also used pieces of PVC pipe to
cover the spark gap.
Ionization of the air takes place at the spark gap and the high-voltage electrode. That generates significant
amounts of ozone that can be toxic, especially when concentrated, so a well-ventilated work area is a requirement. Further,
the device should be turned on for a short period of time only.
Finally, even though a hash suppressor is used, air transmission of electromagnetic impulses from the coil will interfere with radio
(evident as hum) and TV reception (appearing as white lines), and cause peaks on recorders or other sensitive nearby equipment.
Perhaps the biggest challenge in building a Tesla coil is gathering the needed parts. High-voltage gear is not as common as it used to
be, and usually can not be obtained from traditional hobbyists sources. Here are some hints to help make your hunt go a little smoother:
In the author's experience, the best type of transformer for this application is an oil-burner ignition transformer. If you cannot find
one in a scrap yard, ask a plumber who installs oil-burners. Normally these transformers have a 117-VAC primary and two 5000-VAC
secondaries that can be used singly; they can also be used in series (if properly phased) to give you a full 10,000 VAC at roughly 20mA.
These days, high-efficiency gas furnaces have the same system so is also good. Once again, treat these high-voltage
transformers with all due respect. They can be deadly if you are grounded! (Nikola Tesla himself always used shoes with a cork
I make it a point to stand on a dry floor with a cushion under my feet when working on high-voltage projects of any type whose performance
is unknown or unpredictable, and Tesla coils that are under development certainly fall into that category.
Also useful may be an old TV-technician's trick: That is, to keep your left hand in your pocket whenever you work with high voltages.
That way you can never be connected from high voltage to ground by way of hand-body (heart)-hand. By the way, that technique was first
used by Nikola Tesla!
Another possibility is to use a neon-tube transformer, the type used to illuminate signs. They normally have a 117-VAC primary and two
3500-VAC, 50mA secondaries that can again be connected in series. With neon-tube transformers, a hash choke is a good idea.
There are a few other ways to excite a Tesla coil. One is to use an automotive ignition coil. To do that, though, you need an interrupter
circuit. A suitable set up was discussed in the "Solid State Tesla Coil", which appeared in the October 1988 issue of Hands-on
You can also use a TV high-voltage supply to drive a Tesla coil. It works, but the coil is unlikely to be a spectacular performer...
Capacitor C1 is a 0.003 - 0.005uF (3000 - 5000pF) ceramic unit with a voltage rating that's suitable for your transformer. That means
if your transformer is outputting 10,000-VAC, you need a capacitor with a rating of at least 15,000 WVDC.
Such capacitors do not grow on trees, and can be expensive even when found. The author tried to get around that problem by building a
unit from scratch. After some pre-trial with metal plates and rubber mats, a home-built unit fashioned from 1-inch thick, table-top
sized, Styrofoam sheets with aluminum foil glued to both sides yielded the needed capacitance that was three-feet tall!
In all honesty, building your own capacitor should only be tried as a last resort, unless you are the sort that enjoys experimenting with
such things. If so, you'll probably want to get hold of the latest catalog from Lindsay Publications (P.O. Box 12, Bradley, IL 60915-0012).
Their unusual collection of books and a variety of electrical subjects includes a number that are dedicated to high-voltage
experimentation. Several of those offer information on building your own capacitors.
Turning to more Conventional alternatives, high-voltage ceramic "door-knob" capacitors are ideal for use in Tesla coils. Those capacitors
were once commonly used in TV high-voltage power supplies, but that is no longer true. Some full-line industrial suppliers do still
stock them, however, but they are very expensive. For instance Newark Electronics (stores nationwide) lists appropriated-value
units with ratings as high as 40,000 WVDC in their catalog, but they can run to over $40 each (though lower-rated units are a bit less).
A cheaper solution would be to salvage one from an early (1950's) TV set.
Another solution, and the one the author uses, is to use a series-parallel combination of ceramic capacitors in series, and paralleling
that combination with another string of four series-connected, 0.01uF, 8000-WVDC ceramic capacitors, a 0.005uF, 32,000-WVDC unit is
created. Of course, there are many other combinations that will also work.
Winding the primary coil is fairly simple. Place 10 turns of heavy-gauge wire (#10-#12) on a piece of 8-inch diameter plastic or PVC pipe.
As you are winding, twist a small pigtail every turn or two to act as a tap; the more taps the better. The turns can be held in place
by insulating tape of candle wax.
The author has wrapped dozens of secondary coils. Their diameters vaired from 3/4 to 4-inches, and have ranged from 400 to 7600 turns
and heights from 1 to over 6 feet. Some were built in sections and could be mounted one on top of the other. However, considering size,
effort, and efficiency, the best ones were wrapped on a 10-12-inch length of 3-1/2 inch O.D. PVC pipe. Wind about 400-500 turns of #24
lacquered or magnet wire. The turns must not overlap or efficiency will suffer severely.
To make the task of winding go much smoother, clamp a broomstick into a vise horizontally, place the PVC pipe over it, and turn the pipe
with one hand while guiding the wire with the other. The dispensing wire coil must turn freely. Pressure must be applied to the last
turn at all times, but pauses are possible if you keep a piece of insulating tape ready to secure the last turn and, with a second piece,
the last 10-20 turns.
Airplane glue or rubber cement can be used to secure the wire permanently at the ends and in spots along the way. But I found CA glue
(Cyanacrolate Ester) or crazy glue works really good and there is no drying time. The bond is immediate. When completed, several coats
of paraffin wax, molten candle wax, or bees wax should be used to cover the entire coil, especially at the high-voltage end. That will
suppress corona discharge in places where it is not wanted.
the coil is assembled by placing the secondary within the primary as shown in Fig. 2. The base of the coil
is grounded. The high-voltage end is fitter with an end-cap that serves as an insulator/high-voltage-electrode mount. Details for a
homemade end-cap fashioned from a plastic drinking cup, candle wax, and a doorknob is shown in Fig. 3; the
door-knob serves as the high-voltage electrode.
The spark gap can be formed in many ways. The author's units use two 1-inch pieces of 1-inch diameter aluminum or brass rod. After the
pieces are cut to size, on end of each is machined to a smooth ball-like surface on one side and drilled and tapped on the other of
mounting in a stand with bolts and nuts for adjustment. the author has also made spark gaps by soldering large, steel ball bearings to
A hash suppressor or choke will keep the impulses from your coil from getting into the electrical system from where they can be picked up
by a TV, VCR, DVD player, computer, etc. If no commercial product can be found, a 4-inch ferrite bar can be wrapped from beginning to end
with heavy lacquered wire.
You may want to also try some EMI (Electro Magnetic Interference) reduction techniques on the primary side of the transformer. You could
use a commercial line filter, for instance, but the cheapest and easiest trick to try if to wrap the line cord through an iron toroid-coil
form several times.
Note that the hash choke will not eliminate the transmission of electromagnetic impulses by air. Only a Faraday cage can accomplish
There really isn't too much to do to get your coil up and running. Basically, the different primary taps must be tried out and the
distance of the spark gap must be adjusted for maximum output as can be seen by size of the corona and sparks.
If something doesn't seem right, pull the plug before attempting any troubleshooting. Also, never adjust the spark gap or the taps
while power is applied to the circuit. Always power down between adjustments. Remember, a Tesla coil is a high-voltage device that could
cause serious damage to life and limb if you don't treat it with the proper respect. Fooling around with this Tesla coil can be a
shocking or fatal experience!
Now that we have a Tesla coil, let's see what kind of interesting things we can do with it.
By varying the shape of the high-voltage terminal, you can vary the nature of the coil's discharge. Using a round high-voltage terminal
as already discussed, charges can distribute themselves over a relatively large area and corona discharge is held to a minimum. Instead,
long sparks and streamers can be seen emanating in all directions. Note that more impressive sparking can be obtained on dry rather than
However, observing a corona discharge can also be exciting and interesting. That discharge consists of a ball of blue-glowing plasma
with sparks moving outward from the center. It occurs best when the high-voltage terminal ends in a piece of wire of a pointed object
rather than the ball shaped terminal normally used.
Grasp a light bulb (the 150 or 200 watt transparent type is best) by the glass envelope and bring the base near the high-voltage electrode.
Arcing from the filament to the inside of the envelope at the points your hand touches will form a spectacular display similar to that
produced by the "Lightning Bulb" shown in the Feb. 1989 issue of Popular Electronics. The glass envelope diminishes the
possibility of burns.
Fluorescent tubes will flicker and glow if brought to within 6-feet of a strong, operating Tesla coil. That's because the electromagnetic
radiation excites the diluted rare gas in the tube. If one end of a fluorescent tube is touched to the high-voltage electrode, the tube
will light up brightly. This means it conducts, so under no circumstances should you touch the other end; it will arc and burn you.
Build a little propeller using a brass rivet as a compass-needle-like bearing and two pieces of lightweight wire. Make opposing 90°
bends a the ends of the wire. Using a wire or other pointed as the high-voltage electrode, balance the rivet on the electrode. Apply
power to the Tesla coil and watch your propeller spin.
You can use a Tesla coil to power a "Jacobs Ladder". Mount two heavy-gauge, uninsulated wires so that they are isolated from ground and
each other, and so that they diverge (angle away from each other). Using jumpers, connect one wire to the Tesla coil's high-voltage
electrode and the other to ground. Pwer up the Tesla coil and a spark will form at their closest point. the spark's own heat will
carry it upward until the distance become too large and it opens. Whe that happens, a new spark forms at the bottom.
There are many other exiting experiments that you can try. for instance, plasma globes and Plucker tubes (evacuated glass tubes made
conductive by the addition of small amounts of rare gasses; at one time, these were used by "healers" against all sorts of diseases, can
be driven by Tesla coils. However, whatever you try, remember to trat your Tesla coil with repect!
Parts List for the Tesla Coil:
Copyright and credits:
C1 = .003-.005uF, 15,000-WVDC, ceramic capacitor, see text.
L1 = 8uF, 10A, heavy -duty hash-choke, see text.
L3 = 400-500 turns, 24-gauge (#24) magnet wire, see text.
T1 = 5000 volt, 20mA, dual secondary, oil-burner transformer, see text!
F1 = 10 amp fuse
S1 = SPST power switch
PVC pipe (see text), 3-terminal AC line cord, 1-inch diameter brass or aluminum rod stock, metal doorknob (for high-voltage electrode),
plastic cup, candle wax, paraffin wax, or bees wax, wire, solder, hardware, etc.
This article was originally written by Ralph A. Hubscher and published in "Popular Electronics" in September 1990 by Gernsback
Publishing, (Gernsback Publishing is sadly no longer in business since January 2000). All drawings, photos, pictures, and other
material copyright (C) Tony van Roon, unless otherwise noted.
Editor's note and Disclaimer:
This device is presented here for educational and experimental purposes only as part of our High-Voltage Projects.
Build and/or use at your own risk. The Sentex Corporation of Cambridge Ontario, host of "Tony's Website", or Tony
van Roon himself, cannot be held liable or responsible or will accept any type of liability in any event, in case
of injury or even death by building and/or using or misuse of this device or any other high-voltage device posted
on this web site. By accessing, reading, and/or printing this article you agree to be solely responsible as stated
in the above disclaimer.
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Copyright © 2005 - Tony van Roon