€€À JNÀ THEORETICAL ELECTROMAGNETIC STUDIES AND LEARNING ASSOCIATION 522 WEST THIRD STREET LEADVILLE, CO 80461 (719) 486-0133 COMPUTER AIDED DESIGN OF TESLA COILS BY TOBY GROTZ Coil Tuning & CAE Comparisons Of Three Similar Coils Software for Tesla Coil design has only recently become available. Computer Aided Engineering using appropriate software not only helps during the initial design but helps to refine system operating characteristics. We have used three programs for Tesla Coil design. One of the first was developed by Kovak1-7 and was written for Commodore-64, Apple II-e and Sharp computers. The program has excellent graphics and contains separate sections on design theory and the mathematics of Tesla Coil design. The program is supplemented with a video for VHS or BETA which details design examples and use of the program. (see TCBA NEWS Vol. 4, #1, pg. 3, 1985) One word of caution: the calculation for the resonant frequency of the secondary may differ from measured values by a significant amount. This program provides an excellent introduction into Tesla Coil design and construction for amateur experimenters and students beginning their study of Tesla Coil design, but it does not take into account calculations for the extra coil. TSCAD by Robert Jamison1-8 is the most comprehensive and sophisticated program that we have reviewed to date. The program features improved scaling for unusual conditions, an expanded entry range, and comes with a comprehensive manual with multiple hardware examples. The program, in my opinion, is not for beginners, but for experienced builders and design engineers. This program is quite versatile in its ability to allow "what if" inputs. The main screen which contains the electrical and physical parameters permits easy entry of new values and allows a designer to quickly change many parameters leading to a fast and easy design. Help screens and comments are readily available as well a a built in commentary which points out design discrepancies and offers suggestions for re-design. After several sessions of running TSCAD, I remembered the first time I sat down at a computer to run a Tesla Coil design program. I am amazed at how far Tesla Coil CAD has come in five years. TSCAD blends the art of Tesla Coil construction into the science of electrical design. TCTUTOR by James F. Corum and Kenneth L. Corum1-9 is a program that does to Tesla Coil design what the 6502 did for personal computing. Running on a PC, the program will be appreciated by engineers, hardware designers, and students of electrical power and RF theory. The program is attractively and professionally packaged with a three ring binder ÜjÜŒ that con program instructions and a comprehensive dissertation, Tesla Coils - An RF Power Processing Tutorial For Engineers. The theory of Tesla Coil design begins with elementary principles of resonance and continues up through graduate level course work. TCTUTOR is a program that can be used at any level to demonstrate the principles under study. The program calculates wave forms, spectral power distribution through the use of a fast fourier transform (FFT), and performs Smith Chart calculations for the case of the extra coil. (Technically the Extra Coil is a quarter wave helical resonator and mathematical analysis is quite complicated) If or when wireless transmission of power is finally attempted, it is to be expected that TCTUTOR will play a part in the final design. Because it is the only program that allows for Extra Coil design and analysis, we have used TCTUTOR to compare and contrast three of the largest Tesla Coils built to date. The first, of course was described by Nikola Tesla in The Colorado Springs notes of 18991-10. The second and third coils are those built in Colorado and Utah and described above. Using the measured and assumed values in Table I, print outs from TCTUTOR show the voltage induced from primary excitation, the Fourier Spectrum of the induced voltage, and the final output voltage and extra coil characteristics, for all three cases. TABLE I Tesla - 1899 Utah Colorado Input Voltage (kv rms) 70 44 45 Capacitance in Primary Circuit (C1 uf) .127 .2 .177 Primary Resistance (R1 ohms) 8 * * Primary Inductance (L1 uh) 57 33 33 Secondary Inductance (L2 mH) 9 9 9 Secondary Resistance (R2 ohms) 10 * * Secondary Capacitance (C2 pf) 300 * * Secondary Resonant Frequency (kHz) 97 64 64 Extra Coil Resonant Frequency 92 94 94 Coefficient Of Coupling .6 .6 * (*) indicates that the quantity was not measured, the default program value was used in the analysis. R1 & R2 are AC resistances at the frequency of operation. Since minimal data was available for the Utah configuration1-11, an assumption of values was based on the fact that the Colorado system had been built as close as possible to that used in Utah, which in turn had been built electrically and physically as close to the the Colorado Springs design as possible. The coil dimensions were the same and the length of wire used in the primary, secondary, and extra coil was the same. As a matter of fact, the same wire used for the Utah experiments was used for the recent experiments in Colorado. Figures 1 - 9 show the computer analysis based on values presented in Table I. The first four figures show the output of TCTUTOR for the values Tesla used in 1899. Figures 6 - 9 show the Fourier Spectrum and the peak voltage induced in the secondary for both the Utah ( Figs 6 & 7) and Colorado (Figs 8 & 9) experiments. ÜjÜŒ FIGURES - FROM TCTUTOR Fig. 1. Circuit diagram with values used by Tesla in 1899. Fig. 2. The equivalent lumped circuit of the secondary. 1899 Fig. 3. Induced Secondary voltage vs. time. 1899 Fig. 4. The Fourier Spectrum if the induced voltage. 1899 Fig. 5. The final output from the extra coil with Smith Chart factors, calculated voltage step up, and estimated spark length. 1899 Fig. 6. Fourier Spectrum, Utah experiments. Fig. 7. Induced voltage, Utah experiments. Fig. 8. Fourier Spectrum, Colorado experiments. Fig. 9. Induced Voltage, Colorado experiments. PHOTOGRAPHS 1. QUENCH GAP Barrel covering top half is a safety measure in case of rupture due to ceramic failure while pressurized. (see text) 2. ROTARY BREAK turns at 7110 rpm and breaks 2370 times per second. 3. PRIMARY AND SECONDARY note height of primary above floor, also standoff insulators and heavy wire used on the upper most turn of the secondary. 4. EXTRA COIL showing PVC construction and standoffs used on first and last turns, note also the sloped design used on the upper section. 5. CAPACITORS connected in series, total capacitance, .177 uf. 6. TRANSFORMERS used in step up step down step configuration. 7. SPARKS output from the extra coil. 8. TOWER constructed as described in the article, note size compared to extra coil. As stated above, in the initial summary, two reasons for poor coil performance are given: over loading and poor tuning. As can be seen from the data obtained using TCTUTOR, the fact that the secondary and extra coil are tuned so far apart, contributes greatly to degraded coil performance. The supposition that the secondary and extra coil must be "detuned"1-12, in order for the system to work cannot be explained by the author. Any explanations or suggestions to explain this oft repeated statement would be appreciated. In the future, more accurate measurements will be made and the coil will be properly tuned. All parameters will be measured and checked against the values given in the Colorado Springs notes. The observation to be made here is the difference between the experiments of 1899 and those of Utah and Colorado. As can be seen from the graphs of frequency distribution, Tesla's coil was a masterpiece of fine tuning. FOOT NOTES 1-7. Kovak, Ron, "Ball Lightning Research Via Computer Tesla Coil Design", Astro Electronics Corporation, 1165 Hancock, Boulder, CO, (303) 444-5447. (Also contains photographs and speculation about Ball Lightning) ÜjÜŒ 1-8. TSCAD, Robert M. Jamison, 6809 Mayfield, #1554, Mayfield Hts., Ohio, 44124. 1-9. TCTUTOR, Corum & Associates, 8551 State Route 534, Windsor, Ohio, 44099, (216) 272-5722. 1-10. Nikola Tesla, Colorado Springs Notes, 1899-1900, Nolit, Beograd, Yugoslavia, 1978. (Available from the Tesla Book Company) 1-11. Golka, Bob, "Long Arc Simulated Attachment Testing Using A 150KW Tesla Coil", Golka & Associates, 400 Warren Avenue, Brockton, MA 02403. 1-12. Golka, 1987, 1988. TESLA BULLETIN BOARD SERVICE (TESLA BBS) Networking, results of research, on going dialog etc. Supports 300/1200/2400 Baud, Phone Number 719-486-2775 data, 719-486-0133 voice. 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