s from the toroid. The high
electric field causes the air around the high-voltage terminal to
ionize and conduct electricity, allowing electricity to leak into the air in colorful
corona discharges,
brush discharges and
streamer arcs. Tesla coils are used for entertainment at science museums and public events, and for special effects in movies and television. A Tesla coil is a high-frequency, air-cored resonant transformer, which can be used to produce very high voltages. In Tesla’s early designs, a simple
spark gap was used to set up the oscillations in a tuned,
radio-frequency transformer. Tesla coils can produce output voltages from 50
kilovolts to several million volts for large coils. The alternating current output is in the
low radio frequency range, usually between 50 kHz and 1 MHz. The original, spark-excited Tesla coil circuit, shown below, consists of these components: • A high-voltage supply
transformer (T), to step the AC mains voltage up to a high enough voltage to jump the spark gap. Typical voltages are between 5 and 30 kilovolts (kV). • A
capacitor (C1) that forms a tuned circuit with the
primary winding L1 of the Tesla transformer • A
spark gap (SG) that acts as a switch in the primary circuit • The Tesla coil
(L1, L2), an air-core double-tuned resonant transformer, that generates the high output voltage. • Optionally, a capacitive electrode (top load)
(E) in the form of a smooth metal sphere or
torus attached to the secondary terminal of the coil. Its large surface area suppresses premature air breakdown and arc discharges, increasing the
Q factor and output voltage.
Resonant transformer The specialized transformer used in the Tesla coil circuit
(L1,L2), called a
resonant transformer or radio-frequency (RF) transformer, functions on different principles to transformers used in AC power circuits. While an iron-cored transformer is designed to
transfer energy efficiently from primary to secondary winding, the resonant transformer is designed to
temporarily store and transfer high frequency currents. A primary winding is in parallel with a
capacitor, while the secondary winding has a "parasitic' capacitance with its inductor, as illustrated by the diagram. The inductors and capacitors together function as two
LC circuits, "
tuned" so they have the same
resonant frequency, and each spark briefly completes a circuit on the primary side, producing oscillation back and forth between the primary and secondary. This is analogous to the way a
tuning fork stores vibrational mechanical energy. The
primary coil (L1) consists of relatively few turns of heavy copper wire or tubing, and is wired in parallel to a
capacitor (C1). Current flows through the
spark gap (SG) with each spark, and repetitively energizes the primary side LC circuit. The
secondary coil (L2) consists of hundreds to thousands of turns of wire on a hollow cylindrical form, and the primary is coupled to it by being wound on an insulating former outside it. The inductance of
(L2) resonates with stray capacitance
(C2) and the capacitance of the
toroid's metal electrode attached to the high-voltage terminal. The peculiar design of the coil is dictated by the need to achieve low resistive energy losses (high
Q factor) at high frequencies, which results in the largest secondary voltages: • The coils in a Tesla transformer are loosely coupled. The primary winding is larger in diameter and spaced apart from the secondary, so the mutual inductance is low and the coupling coefficient is typically 0.05 to 0.2; this means only 5% to 20% of the magnetic field of the primary passes through the secondary when open-circuited. The loose coupling slows the exchange of energy between the primary and secondary coils, which allows the oscillating energy to stay in the secondary circuit longer before it returns to the primary and begins dissipating in the spark. • Each winding is also usually limited to a single layer of wire, which reduces
proximity effect losses. The primary carries very high currents. Since high-frequency current mostly flows on the surface of conductors due to
skin effect, it is often made of thick wire with a large surface area to reduce resistance, and its turns are spaced apart, which reduces proximity effect losses and arcing between turns. The output circuit can have two forms: •
Unipolar: One end of the secondary winding is connected to a single high-voltage terminal, the other end is
grounded. This type is used in modern coils designed for entertainment. The primary winding is located near the bottom, low potential end of the secondary, to minimize arcs between the windings. Since the ground (Earth) serves as the return path for the high voltage, streamer arcs from the terminal tend to jump to any nearby grounded object. •
Bipolar: Neither end of the secondary winding is grounded, and both are brought out to high-voltage terminals. The primary winding is located at the center of the secondary coil, equidistant between the two high potential terminals, to discourage arcing.
Operation cycle The circuit operates in a rapidly repeating cycle in which the supply transformer
(T) charges the primary capacitor
(C1) up, which then discharges in a spark through the spark gap, creating a brief pulse of oscillating current in the primary circuit which excites a high oscillating voltage across the secondary: • Current from the supply transformer
(T) charges the capacitor
(C1) to a high voltage. • When the voltage across the capacitor reaches the
breakdown voltage of the spark gap
(SG) a spark starts, reducing the spark gap resistance to a very low value. This completes the primary circuit and current from the capacitor flows through the primary coil
(L1). The current flows rapidly back and forth between the plates of the capacitor through the coil, generating radio frequency oscillating current in the primary circuit at the circuit's
resonant frequency. • The oscillating
magnetic field of the primary winding induces an oscillating current in the secondary winding
(L2), by
Faraday's law of induction. Over a number of cycles, the energy in the primary circuit is transferred to the secondary. The total energy in the tuned circuits is limited to the energy originally stored in the capacitor
C1, so as the oscillating voltage in the secondary increases in amplitude ("ring up") the oscillations in the primary decrease to zero. Although the ends of the secondary coil are open, it also acts as a tuned circuit due to the capacitance
(C2), the sum of the
parasitic capacitance between the turns of the coil plus the capacitance of the toroid electrode
E. Current flows rapidly back and forth through the secondary coil between its ends. Because of the small capacitance, the oscillating voltage across the secondary coil which appears on the output terminal is much larger than the primary voltage. • The secondary current creates a magnetic field that induces voltage back in the primary coil, and over a number of additional cycles the energy is transferred back to the primary, causing the oscillating voltage in the secondary to decrease ("ring down"). This process repeats, the energy shifting rapidly back and forth between the primary and secondary tuned circuits. The oscillating currents in the primary and secondary gradually die out due to energy dissipated as heat in the spark gap and resistance of the coil. • When the current through the spark gap is no longer sufficient to keep the air in the gap ionized, the spark stops ("quenches"), terminating the current in the primary circuit. The oscillating current in the secondary may continue for some time. • The current from the supply transformer begins charging the capacitor
C1 again and the cycle repeats. This entire cycle takes place very rapidly, the oscillations dying out in a time of the order of a millisecond. Each spark across the spark gap produces a pulse of damped sinusoidal high voltage at the output terminal of the coil. Each pulse dies out before the next spark occurs, so the coil generates a string of
damped waves, not a continuous sinusoidal voltage. The high voltage from the supply transformer that charges the capacitor is a 50 or 60 Hz
sine wave. Depending on how the spark gap is set, usually one or two sparks occur at the peak of each half-cycle of the mains current, so there are more than a hundred sparks per second. Thus the spark at the spark gap appears continuous, as do the high-voltage streamers from the top of the coil. The supply transformer
(T) secondary winding is connected across the primary tuned circuit. It might seem that the transformer would be a leakage path for the RF current, damping the oscillations. However its large
inductance gives it a very high
impedance at the resonant frequency, so it acts as an open circuit to the oscillating current. If the supply transformer has inadequate
short-circuit inductance, radio frequency
chokes are placed in its secondary leads to block the RF current.
Oscillation frequency To produce the largest output voltage, the primary and secondary tuned circuits are adjusted to
resonance with each other. The
resonant frequencies of the primary and secondary circuits, \scriptstyle f_1 and \scriptstyle f_2, are determined by the
inductance and
capacitance in each circuit: :f_1 = {1 \over {2\pi \sqrt {L_1 C_1}}} \qquad \qquad f_2 = {1 \over {2\pi \sqrt {L_2 C_2}}}\, Generally the secondary is not adjustable, so the primary circuit is tuned, usually by a moveable tap on the primary coil L1, until it resonates at the same frequency as the secondary: :f = {1 \over {2\pi \sqrt {L_1 C_1}}} = {1 \over {2\pi \sqrt {L_2 C_2}}}\, Thus the condition for resonance between primary and secondary is: :L_1 C_1 = L_2 C_2\, The resonant frequency of Tesla coils is in the low
radio frequency (RF) range, usually between 50 kHz and 1 MHz. However, because of the impulsive nature of the spark they produce broadband
radio noise, and without shielding can be a significant source of
RFI, interfering with nearby radio and television reception.
Output voltage In a resonant transformer the high voltage is produced by resonance; the output voltage is not proportional to the turns ratio, as in an ordinary transformer. It can be calculated approximately from
conservation of energy. At the beginning of the cycle, when the spark starts, all of the energy in the primary circuit W_1 is stored in the primary capacitor C_1. If V_1 is the voltage at which the spark gap breaks down, which is usually close to the peak output voltage of the supply transformer
T, this energy is :W_1 = {1 \over 2}C_1V_1^2\, During the "ring up" this energy is transferred to the secondary circuit. Although some is lost as heat in the spark and other resistances, in modern coils, over 85% of the energy ends up in the secondary. At the peak (V_2) of the secondary sinusoidal voltage waveform, all the energy in the secondary W_2 is stored in the capacitance C_2 between the ends of the secondary coil :W_2 = {1 \over 2}C_2V_2^2\, Assuming no energy losses, W_2\;=\;W_1. Substituting into this equation and simplifying, the peak secondary voltage is {{Equation box 1 |indent =: |cellpadding=0 |border=1 |border colour=black |background colour=transparent |equation=V_2 = V_1\sqrt{C_1 \over C_2} = V_1\sqrt{L_2 \over L_1}. }} The second formula above is derived from the first using the resonance condition L_1 C_1\;=\;L_2 C_2. Since the capacitance of the secondary coil is very small compared to the primary capacitor, the primary voltage is stepped up to a high value. The above peak voltage is only achieved in coils in which air discharges do not occur; in coils which produce sparks, like entertainment coils, the peak voltage on the terminal is limited to the voltage at which the air
breaks down and becomes conductive. As the output voltage increases during each voltage pulse, it reaches the point where the air next to the high-voltage terminal
ionizes and
corona,
brush discharges, and
streamer arcs break out from the terminal. This happens when the
electric field strength exceeds the
dielectric strength of the air, about 30 kV per centimeter. Since the electric field is greatest at sharp points and edges, air discharges start at these points on the high-voltage terminal. The voltage on the high-voltage terminal cannot increase above the air breakdown voltage, because additional electric charge pumped into the terminal from the secondary winding just escapes into the air. The output voltage of open-air Tesla coils is limited to a few million volts by air breakdown, but higher voltages can be achieved by coils immersed in pressurized tanks of
insulating oil.
Top electrode Some Tesla coil designs have a smooth spherical or
toroidal metal electrode on the high-voltage terminal. The electrode serves as one plate of a
capacitor, with the Earth as the other plate, increasing the secondary capacitance. The large diameter curved surface reduces the
electric field at the high-voltage terminal, increasing the voltage threshold at which air discharges. Suppressing premature air breakdown and energy loss allows the voltage to build to higher values, creating longer, more energetic discharges. If the top electrode is too large and smooth, the electric field at its surface may not be high enough cause air breakdown. Some entertainment coils have a sharp "spark point" projecting from the electrode to start discharges. ==Types==