Weekend Projects: SSTC Slayer Exciter on Steroids!

Wow! You can achieve that with this shitty design? You are certainly pushing it much farther than I did lol. First of all, IGBTs, despite their great on-paper specs, suffer from a very slow turn-off response called tail-current. They continue to conduct current after turning them off and this causes lots of power dissipation. Monitor the temps of your IGBT with a thermocouple and see what temps they reach. You can do some basic thermal resistance equations (no more complicated then ohms law) and infer the temp of the junction. With such a high voltage you also need a considerable more number of turns on the primary and perhaps a smaller capacitor.
When the switching element initially turns on, it it short-circuited to 140V because of the tank capacitor. They don't like instantaneous changes in voltage. This is a fundamental flaw with this design. I am moving towards an H bridge design similar to OneTesla and Steve Ward designs, although with the use of MOSFET driver IC's instead of gate drive transformers so the driver can be used for everything from flyback transformers, ignition coils, etc. It is also frequency-modulated via a PLL for audio. Check out my latest video as a teaser for that.

Amazing job, although I'd use high power MOSFETs, since their low on resistance means they aren't as hot.

+Garrison T My first "tesla coil" was powered by a overdriven bug zapper and a capacitor was made by using 2 aluminum pie trays separated about half an inch (10ish cm). It produced extremely faint sparks about 2mm to 5mm long only with a breakout point. I originally thought that changing the spark gap is how it needed to be tuned, so I was using machine screws (erector set pieces) for the gap.

Keystone Science Thanks! I don't remember the name of the song but it's from incometech

MacLeod latin industries

Kelvin Macleod - latin industries

@@power-max can u make musical Tesla coil

+deven bo yes. (4:40)

C1 needs to be tuned to be close to the resonant frequency of the secondary side.

I’ve been thinking about using the tcc4420 for the driver on the sstc. Another option I’ve been thinking about is using a BJT as a mosfet driver.

yes

No idea.

I've just watched yours...

Actually it makes a lot of sense. You are probably familiar with traditional constant voltage supplies, and the less resistance he more current something pulls. You can think of the output here as more like constant current. When a short arc is drawn the voltage is low and power is low. But with more and more resistance (less "load" in the traditional sense) the more power is needed.

@@power-max The power doesn't necessarily go down. The power factor changes as you load the coil. The real power might even increase (depending on arc lenght), and more power is transferred to secondary and less burned off in primary

@@imeprezime1285 I probably should have described the power transfer into the secondary and arc in terms of Q factor, unloaded (in the case of open circuit no breakout and short circuit the Q factor of the primary is very high, limited by the copper and MOSFET losses. With an established arc the Q factor goes way down because energy is being dumped into it. Ideally the Tesla coil always operates at resonance so the capacitive and inductive reactance cancel out, power factor isn't a great metric since we are dealing with a variable frequency system unlike 60Hz mains electricity where frequency is a fixed constant.

Pin 6 is I believe one of the outputs Forcing any other signal onto that pin would blow up the DS0026 and bypass it (assuming you used that output for the MOSFET gate drive) And no, because the circuit relies on feedback to oscillate at the natural frequency of the coil, which is in the high KHz to low MHz region. That is why the 555 is used to modulate the power to this chip at a much slower rate, it effectively turns the tesla coil on and off very fast. The 555 *CAN* be replaced with a any binary signal, (not an analog voltage signal as would be the case with any normal audio source) That I think does include a MIDI generator that only outputs a single voice square wave output. You will the the sound quality of early IBM computers without soundcards.

Manuel Procchieschi Thanks. Are you asking if it can be powered by your power supply? Sure. But you will not get the performance I got with a bunch if smaller power supplies in series for an equivelent supply of 55V.

"They were not just a simple high-frequency air-core transformer." They are air-core _resonant_ transformers, you are absolutely right, my particular circuit design actually relies on parasitic capacitive coupling between the secondary and ground. This is why the resonant frequency changes depending on the surrounding and how much it's loaded. (which also affects the Q factor of the coil due to resistive elements and losses) This is clearly observed in my last slayer exciter video where I display the waveform seen on the base of the NPN transistor in real time with changes in external loading.
My understanding is that the secondary coil must have low parasitic capacitance (for high frequency operation), good dielectric strength (to withstand enormous voltages), and reasonable coupling between the primary and secondary, esp. for SSTC designs, due to the limited magnetic flux strength. This almost exclusively limit's the design to this classic single layer cylindrical coil design. Especially if you are looking for strong RF field emissions.
If you follow the moving charges that are observed in the secondary coil, you can use the right hand rule and vector fields to trace out how this thing would radiate electromagnetic waves. I believe the output will be circularly polarized, but I am not an RF expert.

Something I would try is decouple the secondary from the driver circuit and then wind a two or three turn loop close to the ground section of the coil for a feedback loop. You just want enough voltage to set the resonance and keep everything in tune. You ought to figure the total length of wire used to get an idea of the wavelength involved. If you resonate a very long wire with a shorter wavelength (higher frequency) drive unit it will still produce sparks, but you will get high voltage nodes at the spots on the coil where that frequency hits 1st and 3rd quarter resonances. Basically, your coil gets high voltage "hot spots" that will produce corona or arcs from specific spots on the body of the secondary coil itself, instead of at the top where you desire it. If the primary is driving at too low a frequency, then it royally shortens your spark length since the two circuits would essentially be out of phase, even if they are both resonating. You want as close to Q as you can get between the two, while at the proper design frequency.
I just realized that I didn't specify something necessary to clear up the confusion someone reading this might need. I have read Tesla's works and one thing became quickly evident. He did not use the standard lingo, but like many we see today he often used the words of electronics, but gave them his own modified definitions. That is why he was so misunderstood by many scientists of the time, and for good reason. If you want to see what he was after, draw out a sine wave and then mark out the quarters. Now, look at where the voltages fall on those quater-wave sections. The wave starts at0V, proceeds to Max +V, drops back down to 0V in the center, to Max -V, and finally back to zero voltage. He used the length of the secondary as either a single wire quarter-wave antenna for his vertical coils or as a half-wave dipole for his horizontal coils. He built coils like he was designing a radio or T.V. antenna, not simply as a resonating circuit. It was brilliant, but confusing if you tried to put everyone else's definitions on the words he used. He used the term "resonance" the way Einstein used the term "equivalence." He did this so as to create standing wave signal amplification within the secondary circuit, meaning he could get much higher amplitudes out of the available signal than would have been available otherwise.

I just spent 3 hours calculating my coil's approximate resonance frequency because I don’t have an oscilloscope and then realized... does this circuit really need to have tuned primary with secondary when it autotunes the frequency?
Edit: i made a mistake. Now I understand that you were only talking about the secondary, not primary.

+Kalanchoe1 Good job!

+Power Max I wrote that comment an hour before i blew up the second one. no joke!

Lol! :D excellent! A+ Yup I blew quite a few 555s too, that's why I order them in buckets.

+Power Max Ebay... 100X ne555s for $3 free shipping! crazy! Anyways, i have yet to figure out why they go nuclear on me. I figure it must be some high voltage transient on the power rails. my circuit varies from your's as i do not have a FET driver so I've been using a BPJ transistor as the driver. that part works great but when i put the 555 in the equation it goes bang.

+Kalanchoe1 Nuclear 555 timers, ummm :) Maybe that would be useful! If you are getting them from ebay that could be some of the problem. Ebay electronic component sellers are notorious for producing crappy knockoff counterfeit of parts. Often they will take low end transistors (like IRFP250N) and scrub the part number off and print a "better" part number (like IRFP460N) and sell it at a slight markup but still much less than a real part.

I think mine was rated a few hundred volts, I didn't put alot of effort into choosing one. I would recommend using a capacitor rated for resonant operation, such as a mica capacitor, or a class 1 ceramic capacitor.
As for the MOSFET driver, just about anything can work, but I'd recommend any low side gate driver IC that has below 30ns propagation delay and can supply 4A source and sink into the MOSFET gate. Keep the connections between the MOSFET and gate driver as short as possible, minimize the loop area between the gate driver output, gate, source, and return path of the gate driver IC. Also keep the bypass capacitor across the gate driver IC as close to the power pins again minimizing loop area.

@@power-max Amazing, thanks for the help! What wattage should I rate the resistor on the power side? How much does the resistance affect the stability?
Oh, and does the 555 timer interrupt freq matter? I'm asking because I want to make my coil quiet, and don't want it bothering my dog either. If there's a limit, I'm fine with running it at lower frequencies.
Finally and most importantly, how do I best protect the MOSFET? I'm planning on using a FET with a low on resistance and therefore much less heat. But I don't want it to die, since it's over twice the cost of an IRFP260N.
Thanks again, you're a massive help.

@@power-max Could I use a 1/4 watt resistor, or will I need something more powerful?

Circuit Ideas Labs i tried it because it was the only one i had laying around and it kinda worked. Which you probably already found out because it was 5 month ago.

@@mareksvrcina5279 i tried it too and it worked alright. It heated up and melted my breadboard with no interupter and primary resonant capacitor.

@@juntendo6104 could you give me the schematic.

+Tesla Explorer Thanks!

It isn't a vttc

it is to

Tesla Explorer a VTTC is a Vacuum Tube Tesla Coil, which this is not. I do have a couple of tubes, but only low current low power radio tibes which are not suitable for high power stuff.

Yes. The DR stands for "Dual Resonant". The primary is a resonant circuit tuned close to the resonant frequency of the secondary, by definition. In fact, this is the most correct type of tesla coil in my opinion, as it is a solid-state version of a bog standard SGTC. It is possible to audio-modulate a continuous-wave tesla coil, however have been having trouble with the PLL circuit. It likes to fry my half bridge transistors frequently. Burned through all 40 of my transistors now so I am out of the race until new ones arrive.

My theory is that the audio modulated PLL driver (which uses antenna feedback to lock on to the resonant frequency of the secondary), has a pretty uncontrolled phase delay at the 280 to 300kHz, as the closed-loop phase depends on a variety of components in the control loop, including the interaction between primary and secondary. This complicates analysis a lot.
My H-bridge PCB is optimized for the current slightly lagging the drive voltage waveform (i.e, drive the primary a slightly above resonance such that the primary appears predominately inductive) In this mode, ZVS soft switching is achieved during turn-on, and diodes used to discharge the gate for a snappy turn-off, minimizing switching losses. Because as either the top or bottom MOSFET turns off, there is still current flowing in or out of the primary, and given inductor action the voltage suddenly shoots to the other supply and is clamped by the body diode of the other transistor, which, when turned on, has almost no voltage across it!
The MOSFET driver has a 12 ohm series resistor to limit the turn-on time but since the transistors are switched off during maximum current and the voltage also happens to rise to the other supply rail, a diode is placed to turn the transistor off as fast as possible to limit turn-off switching losses. This also prevents issues with di/dt and dv/dt when the MOSFET is turning on due to miller effect and the parasitic BJT found in all MOSFETs, which can cause the wrong FET to suddenly turn ON briefly and cause a shoot-through condition (both FETs are on)
When I set the primary to appear predominately capacitive by driving a lower frequency than the resonant frequency then turn-on losses are increased and turn-off losses are decreased and it operates in ZCS region instead of ZVS region.
For the moment I am just messing with the standard jellybean DRSSTC type circuit with a LM339 comparator for feedback from a current transformer that drives a 74LS86 quad XOR gate that I use to implement controllable dead-time so both FETs are not accidentally turned on simultaneously. For audio modulation, I have found that modulating the frequency of operation only really works when the coil is purposely de-tuned, due to how slope demodulation works.

Idk about the MC33151 but i used tc4426 and it worked fine. Tc426 should also work.

that is no where NEAR enough. you need 5A absolute minimum

50V 6A+ to get my results.

im worried my IRF640 will blow up. Oh and i'm powering the DS0026 with 10 volts from a zener, with 200 ohm 10 watt resistor

+chems IRF640 is not good enough :(

you mean for power or its just not a good transistor?

I am actually experimenting with FM modulation to do audio. Check out my latest video using a PLL! I upgrade from this single-ended driver circuit to something more akin to Steve Ward's design (but instead chose to use a MOSFET driver IC.)
The trouble I see with a PWM based interrupter for audio modulation is that the frequency of the coil is just too close to the required interrupting frequency for clear audio. I haven't tried it, but to get clear audio you need to set the interrupter frequency to around 40kHz, and the coil resonates at 100kHz. I don't think you can get clear audio this way. Hence I switched to a PLL to allow an audio signal to modulate the frequency of the coil instead. The secondary demodulates it by slope detection.
A PWM or 555 flyback driver works because each cycle you charge up the primary with a current and then when the MOSFET opens the field collapses, and how much depends on how long the MOSFET was conducting so the energy dumped into the secondary is proportional to the duty cycle.

@@power-max It actually works better than I would have thought and how I've usually done it is switching the entire circuit at the power rail. The first plasma speaker setup
I made was just an injected audio signal into the gate of the mosfet switching the flyback and by using an lm386 to boost the signal I was able to get some really high fidelity highs and decent lows but I remember thinking there was no way a Slayer would be viable volume-wise. Turns out with the right setup it can get pretty loud. I tried it on a Slayer I knew had decent output from around 40 watts using a TL494 to drive the PWM. I recently tried it on a smaller tower running at 2.5mhz also and it worked about the same. Same thing with a different push-pull tower I have. It seems like so long as I set the PWM frequency to above the audible I can then adjust the duty cycle to somewhere around 40% or so and get clear audio. The higher frequencies sound great.
I saw the PLL setup and it pulls some awesome arcs. Those are the kind of beefy yellow arcs I see the most impressive sounding setups using but whenever I try to modulate arcs that beefy the sound just sort of sounds drowned out. The thinner the arcs the louder they seem at times but don't carry enough lower frequencies. I still haven't figured out how some of these other guys are getting what sounds like very clear full-range audio but I can at least seem to get any Slayer to become musical by just powering them with the PWM. I can't say one running at around 100khz would work about the same but a lot of people seem to think that kind of setup only works with midi and basic tones but it can play most music fine.

@@Magneticitist I might give PWM a shot. I like my PLL circuit and may eventually sell it as a kit. It works by converging on the resonant frequency of the tesla coil (the circuit does have to be tuned to be roughly correct but once close enough it locks on) and by injecting a AC coupled signal into the VCO pin via a small blocking capacitor I can "tug" the voltage up and down around the operating point and modulate the frequency. The circuit works best slightly detuned because of how slope detection works on the secondary.

@@power-max Voltage control may be the better way to go about it and it seems like you can actually get audio from the really hot arcs that way which I cannot using the PWM. Only real advantage to the PWM is that you can just make a universal driver with the audio jack and have it play audio through various things that may already emit good arcs.

@@Magneticitist That would be Amplitude Modulation, AM. The problem with AM is that it's very inefficient. I did this to audio-modulate a ZVS flyback driver. The only way I know how to do this easily is to use a transistor as a emitter follower / source follower and biased at the mid-point, VCC/2. You immediately lose half your voltage and 50% of your power is dissipated in this transistor. Once the transistor is biased such you feed in an AC-coupled audio signal that has been amplified to be about 1/3 VCC in peak amplitude (to avoid reaching cutoff and saturation) This is, in essence. a high power class A amplifier. It will work but less than half of the power goes into the Tesla coil. I simply don't have a power supply big enough to get good results, and It requires a separate large CPU heatsink for that sort of power dissipation.

30awg

You should see my "it keeps blowing up" Tesla coil! it is even more cursed

yes

It's a fun novelty.

Not this one. My PLL tesla coil (latest video) is capable of it but it is still unreliable, and it is more complex.

@@power-max ok, so with that driver i ca only use flyback transformers?

@@ElIsraelJijijiji A tesla coil is a form of an LLC resonant converter. You can learn about them here.
ua-cam.com/video/tCEqm-RoP20/v-deo.html
The flyback driver (the typical one w/o the resonant capacitor I added on my video of it) operates VERY differently. The flyback transformer is not a transformer but a coupled inductor, and it works like a boost converter, but the energy stored in the core is discharged into the secondary. Learn about flyback topology here:
ua-cam.com/video/OXibsOzjipw/v-deo.html
So can you run an air core resonate transformer like a flyback? Well maybe, but it will not work well, if at all. The slayer exciter sortof does. the coupling between primary and secondary isn't good (0.3 to 0.5 typically) which limits energy transfer and the remaining energy will be dissipated via avalanche breakdown in your MOSFET. Also the output is not rectified and can conduct both cycles, and it is resonant which is just wrong, although I don't know what the effects of that would be besides the high Q of the secondary filtering out all but the fundamental.

@@power-max Thanks man

You can use a regular gate drive IC and flip the primary with the opposite polarity.
A NOT gate chip might not have enough grunt to drive a 1nf capacitive load at 300kHz to 1MHz.

@@power-max Thanks I didn't think you would answer me :)

Breadboard. They are fundamental to all hobby electronics, great for prototyping circuits, but they can be problematic for RF or high power (3A maximum) circuits. Low quality ones especially can be intermittent but often they are good enough. For more permanent projects you want to consider using either a perforation board (simalar to a breadboard but you solder stuff in) or even better, a custom manufactured PCB. Breadboards are not compatible with modern SMT SMD (surface mount) parts, although many modules for sensors and stuff can be purchased which allow easy hobbyist interaction. (to use PCB modules on a breadboard like any other component)

+Lugar. M There is no feedback antenna. The bottom of the secondary connects to the input of the DS0026 chip with those protection diodes in place to prevent destruction to the DS0026.

ok thanks :)

You should be able to. They have pretty beefy output

A Phase Locked Loop is one way. Refer to my latest video.
www.analog.com/en/analog-dialogue/articles/phase-locked-loop-pll-fundamentals.html
Full bridge driver is recommended. Place capacitor in series with primary. The C and L value are chosen such that it's natural frequency is known and tuned to the same natural frequency as the secondary, which must also be known. chose the values for the Voltage Controlled Oscillator such that it outputs that frequency at around halfway point on the voltage control in. Then AC couple an audio signal into this for frequency modulation. Since this relies on slope demodulation for audio, you may want to tune it slightly off the resonant frequency for the clearest audio. Close the loop with the phase comparitor and feedback from the secondary or a long wire acting as an antanna for the circuit to be mostly self-tuning and provide the longest sparks.

@@power-max will you please make one yourself and turn your sstc into Musical one.

+kunal singh You're welcome! I did it because I needed to lower the power consumption, and decrease the load on my power supply. Doing that also allowed longer sparks because the voltage rose from about 35V to 50V. (yes, that is how underpowered my power supply was!)

+Power Max Ok..:) thats a neat trick!

It isn't so straight forward. The phase of the (any) closed loop system is frequency-dependant. The idea is to have positive feedback at the resonant frequency for oscillation to occur. You can look into the stability criteria for LTI systems (like phase and gain margin) for more info on the topic.

@@power-max I know that the Slayer exciter works due to a negative feedback to the base of a transistor, however since you are using an inverted buffer, are u looking for a positive feedback for the inverted gate driver?
If this is true then the circuit should work only when the primary is wound in the same direction of the secondary right?

@@bhu1334 Even the basic slayer excited is more complicated then that. With negative (180°) feedback at all frequencies no oscillation will occur. You need positive (360°) feedback in the frequency of interest all cases. I think I mis-spoke in the slayer exciter tutorial. These circuits are all really basic examples of LC harmonic oscillators. Learn more about them here.
www.electronics-tutorials.ws/oscillator/oscillators.html

Incorrect hardware. Use proper hardware to avoid the problems I had. The datasheet will specify the dimensions and tolerance of the hole on the tab, and the heatsink should have an appropriate hole, which may or may not be threaded. Use the correct screw that will allow you to tighten the screw down. Other heatsinks use a retention clip. *Also most importantly, be sure to use a dab of thermal paste between the heatsink and MOSFET!*

Thanks. And one more question: Don't I need some thermal spacers or whatever they're called between the MOSFETs and heatsink to go with the thermal paste, or is just the thermal paste to the MOSFETs and heatsink good enough?

Jared Evans As long as you can keep the metal tab in good contact with the heatsink so heat can dissipate effectively, that's all that matters. If you were concerned about electrical isolation, since the drain is connected to the tab, then you would use a sil pad and nylon nut and washer or a retention clip that does not contact the tab but the plastic part of the package

Yes they most certainly do clamp the voltage to no lower than -0.6v and no higher than 0.6V above VCC. That's the hint. Think about it, and the answer is in the read more section.
Imagine you connect 120V AC through a ~10kOhm resistor (or any high impedance) to the diode clamped input with a 12V supply. When the voltage swings far negative then the diode between the input and ground begins to conduct and effectively clamps the voltage to -0.6V. Then when the signal swings the opposite way the upper diode again ends up forward biased and clamps the voltage at 0.6V above VCC. Remember diodes have pretty much constant voltage drop regardless of what current flows through them. (Really it's exponential; google the schlocky diode equation for more info.)
Now if your high voltage source also has a high current and low ESR the diodes will act like short circuits and a lot of current will be dumped into them, possibly exploding them. And when the voltage goes positive it does backfeed power into the supply rail, if it is enough average current, it could cause the 12V supply to begin rising above 12V to some unknown value. I have noticed that when the circuit is running, sometimes it continues to work even if you remove the 12V supply if the primary is still powered for this reason!

@@power-max Thanks for the reply!

Don't kill yourself with that MASSIVE capacitor. :O Seriously, that thing fully charged has nearly 300 Joules of stored energy. It will make a hell of a bang if you short it! You will want to use a pre-charge circuit to charge it slowly, to avoid shorting your power supply.

@@power-max yeah, I know. Just a joke. I charged it up to 12 volts and its sparks when short circuited were already quite impressive.

Your capacitor is FAR too high in value. I used 4 to 5 1000pF capacitors in series to get 200--250pF. It acts like a short because at the resonant frequency that we want to achieve (1MHz let's suppose), then the "capacitor" you have chosen has a reactance of *just a couple ohms*.

Power Max Thanks for the answer!I will try it,but the resonant capacitor makes more powerful output and higher current drawn?As i said without the cap i get about 1 cm arcs and only around 10mA up to 30-40mA input current.

You just need to spend time to fine tune your circuit. You can try to calculate the resonant frequency of the secondary coil (the inductance of it and parasitic capacitance of the topload and objects surrounding it) and knowing the frequency and inductance of the primary, calculate the theoretically ideal capacitor value for the primary. But due to non-ideal conditions and unpredictable loading conditions, it's not particularly accurate way of determining the best capacitor.

Is a mosfet driver IC better than the two transistor in the driver configuration?Is it worth to buy a driver?
By the way i could not build the circuit to test if it's working,because no one mosfet could survive my flyback driver. :D

Yes the driver is a better option, there are many. the ds0026 has 2 amp output, but there are newer and better ones with higher output, that are also cheaper and have an enable function for the interrupter (so no need for transistor between interrupter and driver chip) . It's around 3euros for the 9 amp rated ones, the 2 amp rated ones i found for 1,5 euros. Texas instruments has many options. And this circuit should not be tested with a flyback i suppose.

NEVER! muauahaha but really it is just a rehash of the classic steve ward design. Only difference is Im using a IRS2186 driver IC. And a CD4046 PLL for FM modulation
I am using a resonant series capacitor and not just DC bias caps. But the coupling still needs to be good, or else the reactive energy builds up until damaging currents are flowing (I measured over 140A at times)

@@power-max Also is it possible to replace the 555timer with a square wave musical signal?

@@jasonsaj.3 The 555 in my circuit serves as an interrupter just like in the DRSSTC designs you see floating around on the web, so yes.

Refer to FAQ in description

Short answer is no, probably not. At 50V the back EMF on the MOSFET as well as the power dissipation are already too high for reliable operation. Any additional stress may cause lots of magic blue smoke. I would look into using a better designed circuit for more performance at rectified mains.

IGBTs, while having high breakdown voltage ratings and power ratings, are generally pretty limited in terms of frequency as there is a long tail current after switching off that is not present in MOSFETs as the charges in the PN junction has to deplete. Also they have a positive temperature coefficient, which could result in thermal runaway. So for this reason they are generally not the optimal choice for smaller tesla coil designs.

Yes

Ok, cool. Thanks for the quick reply.

Enameled aluminium should work.

Guitar Guy no.

The reasons are:
A) the 555 timer cannot produce a square wave of high enough frequency. (Especially true for the original NE555.) The chip was not intended to operate above 100kHz. Some versions of the 555 timer (the newer CMOS chips) can go higher, but generally 1MHz is hard to achieve, even with nothing connected to the output besides a scope probe.
B) The chip is not designed to drive the high gate capacitance of the MOSFET. It will overheat. This is why even flyback drivers typically use a intermediate buffer. In my experience, a heavy load on the output of the 555 will result in strange undefined behavior. (Frequency and duty cycle deviate from what calculations predict due to the loading effects.)
C) A standard astable circuit provides no means for feedback, and hence you would need to very carefully tune the output manually. ElectroBOOM has constructed a simalar performance tesla coil using comparators for creating the oscillations necessary. His is manually tuned. The problem with manual tuning is that any change in the topload or the surrounding the secondary is exposed to causes the resonant frequency to shift, detuning the coil and reducing performance.

lots.

Bourhan Dernayka yes. The thickness matters mostly for structural support. PVC comes mostly in quarter inch thickness. The diameter is given by the inside measurement. If you are really serious about making coils (like the ones used professionally for shows) the dielectric properties of PVC are not ideal and acrylic is commonly used instead I think.

Power Max the thing is that i already built a PVC core coil and I’m stuck with it not producing a magnetic field, so I’m searching for a way to make use of that 22 cm length and 4cm diameter coil for my college project.

Bourhan Dernayka oh I see. You ask about the things you were not sure about _after_ making the mistake 😉. The dimensions are ok, although not ideal. Neither are the dimensions on the coil in this video. I should have made it on 3 inch PVC and about 10 inches to a foot tall.

Bourhan Dernayka choose a topload such that the resonant frequency is somewhere between 100KHz and 500KHz. Tutorials online about how to do that. It's easy if you have a scope. *Pro tip: oscilloscope is mandatory if you want to make this thing work in a reasonable timeframe.. Just FYI.*

Don't understand, you want output rating? Shunt regulators are really easy, I'm sure there are tutorials that would teach how they work.

Did that alternative work out for you?

@@power-max @powermax no :(

@@siddhantsinha9276 It should work very well. This circuit is hard to get working without electrical knowledge and a scope. I wish you the best of luck. If you have a specific question feel free to ask.

Idk about the tc4420 but tc4426 and tc426 worked great for me

@@siddhantsinha9276 i think it didnt work bc tc4420 is non-inverting driver. Try tc4426 or tc426, they should work.

+DanielTseng100 9V batteries cannot supply enough current for the task (too much internal resistance), and also it helps to have the circuit electrically grounded at some point for breakout.
I dare you to measure the voltage of the batteries before they are connected to the circuit, and while they are connected to the circuit... What do you notice? I think you will see that the voltage falls drastically!!!
Seeing corona is a good thing, as it means the circuit is oscillating! However, you will want to eliminate it before it melts, carbonizes and completly destroys the dielectric materials. (plastic insulation on the wires, PVC pipe, enamel coating on the magnet wire, etc.)
Also it would help if I knew which version you built, the one including or excluding the 555 timer. There are advantages and disadvantages to each type.

Power Max I built both of them, but they do the same sparks and have almost the same power, the only small difference I noticed is that with the 555 circuit I don't have to bring the cfls very close to the coil to light them up and also when I start moving them away I see a bit of flickering. One more thing that I noticed is that the cfls light up easier at the center of the coil, but when I bring them close to the top they light up very dim. Is that supposed to happen? (I don't have any topload yet)
PS: even that I built both circuits, I use the 555 version more frequently

+DanielTseng100 That sounds fine. Here is a small checklist of things to do:
1) check power supply/add capacitance to the power supply
2) try different number of winding's on the primary coil
3) try moving the coil up and down relative to the secondary
4) try reversing the polarity of the secondary.
5) try different value components (try a different R3 @ 1:41)
Having a topload will improve performance marginally, using a proper power supply will also help. I was using a 30V 1.5A transformer in series with another 12V 4A transformer, in series again with yet another 12V 12A hacked Xbox power supply This is *NOT* a recommended configuration as different power types of power supplies should not be put in series like that, and that is why I had to make the 555 version, to cut down on the current so I do not stress the smallest supply in that series.
If you select the right resistors and capacitors for the 555, the circuit should pulse on and off. The 555 version should draw much less current than other one. Hope this helps!

well, today I noticed that the power supplies at my school have two outputs that I can connect in series to get 60v at max, so I adjusted it to 40v and guess what... It works! so now I just need to add a topload and a 40v supply with enough amps to make this little thing work in my house. Thanks for the tutorial!
PS: when I was using the supply, I accidentally left my finger very close to the switch (metallic lever) and I felt a painful burn, but I didn't saw anything burnt in my finger. do you think that the tesla coil could have transmitted the high voltage to the supply?
================================
this is a warning to anyone who has never touched a plasma arc or wants to draw arcs from this sstc for the first time:I was playing with the sstc today and I noticed that the arc didn't looked very dangerous at first, because "it was small", but now I know that it takes less than one second to get a not so nice and very stinky black dot on the fingertip xD. It only takes a very VERY short direct contact with the skin and a plasma arc to get a 3º degree burn. And the best (worst) part is that it doesn't hurt, so you won't notice until you smell something like burnt popcorn but stronger. at that point it's too late and you can only pray for the burn to be just a small black dot and not a whole line in your hand or worse. I was lucky this time fortunately, so if you want to draw arcs, use a screwdriver or another metallic piece, even better if you connect it to ground, but never touch it with your fingers/hands/whatever part of your body please

+DanielTseng100 Sounds like you got struck a few times by that mean plasma arc lol! Have a look at Mehdi Sadaghdar's (electroBOOM) video on this! ua-cam.com/video/L5E4NiP4hpM/v-deo.html
What I have learned is that while the circuit is operating, you standing close to it (only feet away from it) your body will act like an antenna and pick up all that power, and touching conductive things that are at a different potential (voltage) That power supply switch is hopefully grounded. But be careful, it is easy to kill electronics with the strong electromagnetic and electrostatic fields produced from this circuit. I actually killed my old oscilloscope during my last flyback driver video! :O

this one: www.digikey.com/product-detail/en/fairchild-semiconductor/HGTG20N60A4/HGTG20N60A4-ND/820808

Take a look at the datasheet, it has everything in it you need to know to know if it will work. Compare the specs with the IRFP250, I'll let you decide ;)
Important ratings include:
Vce or Vds (higher = better)
continuous current (higher = better)
on/off switching time (lower = better)
gate charge (lower = better)
As for the transformer, yes, probably. What supply do you have that can supply 60W at 5A?

Power Max a car battery charger :)

it turns on and off the inverted buffer fast so that it uses half the power and has longer arc

Avon Pubudu Jayaweera Its an n-channel, I'm sure you could find a way to use a p-channel in the circuit though.

that's perfectly fine, and recommended.

Power Max Ok awesome, Thanks for the quick reply :)

Another question. What is the diameter and length of the pvc pipe for your secondary ?

2 inches is fine. I think 3 or even 4 inches is more preferable however. (long thin secondaries are less good because of how the cross sectional area decreases as a square of the radius and decreases inductance per turn significantly. Also because more turns are required to get to the same inductance for the same output voltage, then the windings closer to the top are much further away from the primary and coupling into those is weaker.)

What capacitors did you use for the tanks caps? like what voltage and picofarad values per cap?

That is already more current than my chain of random smaller supplies in this video could supply. I bought a meanwell 48V 7.5A supply on amazon for something like $40 to make a stronger version of this circuit (see latest video). I think your supply will work fine. You will need to tune your circuit to not overload your supply anyway.

@@power-max thank you, so I think my 24v 10a + 19v 4a should work fine.

@@imanb608 Place a beefy reverse diode across the weaker supply, so if the voltage collapses it does not invert (diode will enter forward condition with -0.6V across that supply) and will help prevent damage.

@@power-max thanks again, and lastly about 8:35 , what do you mean by "the phase 2 of this transformer is wrong"? can you please explain what's exactly wrong?

@@imanb608 Phase in the context of transformers generally refers to the relative polarities of the separate coils. On a schematic it is designated by phase dots. "Phase" as a term refers to the "lead" or "lag" of one periodic waveform in relation to another periodic waveform in degrees. For sine waves, an inverted sine wave is basically the same as a 180° phase shift. hence the (confusing) terminology.

are you talking about the resisor substitution box? I picked it up at an auction for $1 along with a transistor tester, capacitor substitution box, and a smaller resistor substitution box. I was the only bidder!

Yes. Keep the loop area between the source of the MOSFET and the MOSFET driver IC as short / tight as possible also. I recommend a series resistor and a stronger gate driver IC.

Just about any low side gate driver IC should do. Digikey lists over 6000 suitable parts to choose from.

@@power-max Ok sir

I started electronics by twisting wires together and using office supplies (paperclips, scotch tape, and LOTs of AA batteries) to make really basic things like lamps and used legos to make cases for stuff. I then got a 200-in-1 electronics kit with a breadboard in the center and many components (interfaced via spring terminals to stick wires into). These kits start around $80 but you get bags of electronics, a project book or 2. That's what I used to learn everything I know in these videos.
Just pay attention to the pinout of the breadboard, understand how they work. Be careful to not shove wires too big or small in diameter into the slots, as it will either damage the slot or not make good contact respectively.

Power Max : Were did u go man?

I did when I burned up all my DS0026 ICs! Good find. (I assume you mean BJTs set up as pull pull emitter follower.)

@@power-max yes those gate drivers, NPN AND PNP, like the one diodegonewild has on its circuit,

@@power-max Im planning to make it with TIP41C and TIP42C, but how can i use a feedback to the push and pull circuit?

@@power-max well thats what my circuit design has, it has the output of the 555 driving the BJT push and pull gate driver, then the MOSFET'S gate

@@power-max im planning to make it on the breadboard first, then i will solder it to a perf board, but im thinking to use a tcrew terminal block so if the MOSFET blows up i can screw it out, but i have one last question, why on most circuits they use a capacitor between Source and drain in parallel?

+Scotlahn Mccallister Anything is possible, you could modify my design and do audio modulation, but I would suggest trying ElectroBOOM's circuit, Unlike mine, his is not a closed loop controlled design and relies on a discrete oscillator which he modulates in order to do pretty good audio modulation.

@@power-max Could you not just use the old method (as in from ancient radio days) of putting an audio signal on a transformer primary, and wiring the secondary in series with VCC of your circuit? Tested To Destruction did that with a ZVS and it worked very well.

@@starchief93 you want to do amplitude modulation, that is achieved by multiplying your carrier wave to your audio signal by means of a mixer, usually. In practice, you could achieve this by modulating the supply voltage to the tesla coil resonator as a function of the audio signal.
Powering it with a class A amplifier to introduce this voltage modulation on the DC rail is probably the easiest ways to do it.
I have more recently been messing around with the idea of using frequency modulation or phase modulation instead, and demodulation occurs by means of the high Q factor of the tesla coil resonator as it gets pushed and pulled into and out of resonance.
The problem with this approach is that the circuit can flip between running above and below Fres of either the upper or lower pole (whichever you tuned it to) and consequentially flipping between ZVS and ZCS, which can result in destruction of the switches, as I found out in my "it keeps blowing up" video. Also using a PLL, there is a risk it might lock onto some really strange undesired harmonics which result in excessive gate drive losses and blown up.

@@power-max Right, that makes more sense. I was wondering about demodulation. It didn't seem to be happening with the ZVS though.

@@starchief93 Join the HV discussion over on the styropyro discord server, I and a lot of other HV enthusiasts are pretty active there.

Henry Swan Honestly I was not sure. My guess was that by reducing the average current consumption, the average supply voltage increased as the power supplies had less loading. When you draw a lot of current from unregulated power supplies the supplied voltage tends to droop.

thanks, does that mean if you had a really high current power supply it would waver less and thus the output power would be closer to the maximum

It's important to not confuse the maximum current rating with load regulation. In general, yes. An unregulated power supply with a higher current rating will have better load regulation than a unregulated supply with lower current capability. But it's still entirely possible to have a regulated lab bench supply which can maintain a constant voltage almost regardless of the instantaneous current draw , so long you don't exceed it's rating, of course!

ok, thanks!

please reply sir I want to know it

or tell me which transistor I can use instead of 2N4401

depends on the supply.
Probably.

If only I had a function generator 😞 Even if I did have a nice one I'd be afraid of frying it.
Yes, a MOSFET gate driver is in essence a current amplifier. It takes a dmall negligable drive current from a logic level signal and delivers a sizable current to the MOSFET gate. If you understand capacitance then you will understand why it is nessesary. Think about capacitive reactance (measured in ohms), with a square wave signal consisting of maybe 10 harmonics. Or the desired rise/fall time and voltage level and the dv/dt if you prefer time domain analysis (which is conceptually simpler for this example)
But also I am using feedback from the secondary to drive the gate, I created an oscillator, positive feedback at the resonant frequency of the secondary. You can google how crystal oscillator circuits work, same principle, just with a tesla coil transformer instead of a ceramic resonator or quartz crystal.

@@power-max So you think the 555 timer can generate a bigger frequency than a function generator without frying? Yeah I know probably you fried some 😅 Oh and don't you think you would get better performance with the circuit in a perfboard instead of the breadboard?

​@@felipesantana2126 It depends on how nice of a function generator you get. A good on should have a high bandwidth, be capable of arbitrary waveform, etc. It will have a well-characterized output impedance of 50 ohms via a BNC connector just like a scope, which can travel down a 50 ohm characteristic impedance coaxial transmission line to your Device Under Test (DUT). Done right the high speed edges should be preserved by impedance matching of the output of the generator, the coaxial cable, and the input impedance of your DUT. A crappy one will be little more than an analog oscillator (like a 555) with maybe some different waveform outputs, a buffer amplifier, and a 50 ohm series resistor to a BNC, bandwidth depending on components used and design. A 555 is limited to under 1MHz, and most breadboard designs are limited to this as well just due to parasitics (see below)
Yes, you will absolutely get better performance from a soldered up perfboard or even better, a custom PCB, like this one. github.com/power-max/universal-half-bridge
A breadboard has a lot of parasitic capacitance between adjacent nodes, the steel contacts have relatively high resistance on the order of dozens of milliohms which limits current capability (I've melted many breadboards) and not to mention how flaky the connections in especially the cheap chinese clones. Also wires on a breadboard and lack of a ground plane can increase series inductance which can limit di/dt capability and cause damaging voltage transients.

@@power-max but shouldn't I do the circuit in breadboard anyways, because of the components that might explode? It's easier to replace components in a breadboard

@@felipesantana2126 That is up to you. Sometimes that is simply not an option. However this is not a circuit where such shortcomings matter quite so much. Mostly an issue for very high power designs with many (10+) amps and/or high frequencies.
In the world of electronics 1MHz is child's play. Intel CPUs have clock speeds in the many GHz range, and those are (supposed to be) square wave signals with a number of additional harmonics. With the recent advancement of III-V semiconductors, Sub THz millimeter wave communication is even starting to become power efficient and economical, and for that literally millimeters of conductors matter, along with permittivity and permeability of the substrate material. At those frequencies the skin effect means electricity travels along the surface of a conductor rather than through it (due to general relativity) and the EM waves around a conductor is what carries the energy rather than the wire itself. Hence waveguides become more efficient than wire based transmission lines. most day to day capacitors would look like inductors just because of the length of the leads and the pacakage.
TL-DR The world of RF and microwave is black magic.

+Surprise Taco I don't see why not. some small modifications may be necessary though. (sorry for not responding sooner, youtube once again proves unreliable for notifications.)

+Power Max No worries. I ended up building Steve Ward's micro SSTC.

+Surprise Taco Cool! I have yet to work on that design, though I do prefer the simplicity of this one!

For me the tc4426 worked great

+gary adams Well first you will need to pinpoint what the problem is. Having a oscilloscope really becomes worth it's weight in gold with analog circuits like these, as you can literally "see" what is going on around the MOSFET and pinpoint the problem quickly! and if you shop around for second-hand ones, you can get ahold of one for close to nothing, and someone might even be nice enough to _give_ you one! It is not necessary though.
There are a few ways to kill MOSFETs: One way would be the most obvious, letting them overheat and thermally fail. (That might be due to the way they are driven or not a large enough heatsink, or too much current through the MOSFET when it is on, or driving it in the linear region, so it acts like a huge resistor)
Another way they could fail is with high voltage spikes on the drain, exceeding the MOSFETs rating. (this might be due to not using a resonant tank capacitor to absorb the EMF kickback from the coil, although when the coil is resonant, adding more energy into it causes the voltage oscillations to get larger and larger, and if that power entering it is not escaping via a spark on the output, it can also kill the transistor for the same HV reason.)
And the last way I can think of that they can fail is by exceeding the maximum voltage allowable on the gate of the MOSFET. This one is the most sneaky type of failure and is actually relatable to the last type of failure. For the IRFP250N, You need to keep the voltage on the gate (Vgs) clamped to less than ±20V. If you are powering your circuit with less than 20V, than you should not be getting 20V on that gate, and adding some diodes the same way as
1:17 would help to clamp the voltage to within the power supply limits.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Judging by the fact that you discovered that the IRFZ48 seems to be the most reliable might hint at an overcurrent situation, and the fact that it occasionally burns out instantly with power also hints that there might be some sort of inrush current problem. The IRFZ48N is rated to handle 50A continuously, while the IRFP250N is only rated for 20A. But the IRFZ48N can only handle voltages up to 50V across the drain and source, while the IRFP250N can handle up to 200V!
I would first try to run this at a lower voltage, like 9-12V before using like 50V, to see if that solves your problem.

+Power Max Hey thank's man!!! i will see what happend's when i get more mosfet's!! also could i use dif interupter maybe with audio ???. by the way im getting 4.5" spark's prty cool bud!!!

+gary adams ElectroBOOM has built a similar SSTC thing, but it uses a separate oscillator for driving the coil rather than relying on feedback from the secondary. The disadvantage with that method is that it has to be tuned, and the tuning to get the best performance will depend on how the secondary coil is made, and what surrounds it. However, it is much easier to modulate with audio, check him out!

+Power Max Thank's do you know what video on youtube?

+gary adams ua-cam.com/users/msadaghd

+Proto G Thanks!

It really nice. Can you show me 1 video is more easy?

NARENDRA teegala off course they get hot! I hinted as to why in the video. Calculate the voltage drop across that resistor 38V! You can see that the power losses are going to be very high. DO NOT USE A SHUNT REGULATOR if you have any better option for a 12v rail.

Shall I use two different power supplies. I mean 12v SMPS for ic and 50v transformer for mosfet.

NARENDRA teegala as long as you make sure that the 2 power supplies can commoned together (make sure you can connect the negitive of one to the negitive of the other. That should be fine so long as at the supplies are electrically isolated fron each other.

Power Max thanks for your response. Please, let me know, I have one 12v SMPS and 50v transformer with rectifier. Shall I common the both of their negitives? Is it ok sir?

Resepected sir.... Pls reply

Try and see! Use the datasheet as a reference (compare the specs)

Rispes is TC4420 is suitable

Try tc4426 or tc426 they worked fine for me.

It would be more beneficial to you to learn how to troubleshoot, diagnose, and figure out why your circuit does not work. If you have any plans on doing anything STEM related for your career, then you will be expected to figure things out on your own, independently. (as well as good at working in a team) The only resources you would have available is documentation (datasheets, user guides, books, company databases, etc) and maybe fellow co-workers that are just as ignorant in said subject
If you want to get this circuit to work, put some effort into figuring it out. You will learn so much more. I personally think the answers to your questions are obvious, but I suppose I do expect a lot for "newbies." I think you are smart enough to solve these problems!

That's not to put you off from asking questions, just be mindful of what questions to ask. If you are getting frustrated then you should get help. Anyways best of luck!

I would not go less than 35AWG, but that is up to you. If you get too thin, it becomes very easy to break the wire. 40AWG is thin as hair.

ua-cam.com/video/q9dAIKrRdR4/v-deo.html

+Power Max how many turns is your secondary