If you need assistance, please send an email to forum at 4hv dot org. To ensure your email is not marked as spam, please include the phrase "4hv help" in the subject line. You can also find assistance via IRC, at irc.shadowworld.net, room #hvcomm.
Support 4hv.org!
Donate:
4hv.org is hosted on a dedicated server. Unfortunately, this server costs and we rely on the help of site members to keep 4hv.org running. Please consider donating. We will place your name on the thanks list and you'll be helping to keep 4hv.org alive and free for everyone. Members whose names appear in red bold have donated recently. Green bold denotes those who have recently donated to keep the server carbon neutral.
Special Thanks To:
Aaron Holmes
Aaron Wheeler
Adam Horden
Alan Scrimgeour
Andre
Andrew Haynes
Anonymous000
asabase
Austin Weil
barney
Barry
Bert Hickman
Bill Kukowski
Blitzorn
Brandon Paradelas
Bruce Bowling
BubeeMike
Byong Park
Cesiumsponge
Chris F.
Chris Hooper
Corey Worthington
Derek Woodroffe
Dalus
Dan Strother
Daniel Davis
Daniel Uhrenholt
datasheetarchive
Dave Billington
Dave Marshall
David F.
Dennis Rogers
drelectrix
Dr. John Gudenas
Dr. Spark
E.TexasTesla
eastvoltresearch
Eirik Taylor
Erik Dyakov
Erlend^SE
Finn Hammer
Firebug24k
GalliumMan
Gary Peterson
George Slade
GhostNull
Gordon Mcknight
Graham Armitage
Grant
GreySoul
Henry H
IamSmooth
In memory of Leo Powning
Jacob Cash
James Howells
James Pawson
Jeff Greenfield
Jeff Thomas
Jesse Frost
Jim Mitchell
jlr134
Joe Mastroianni
John Forcina
John Oberg
John Willcutt
Jon Newcomb
klugesmith
Leslie Wright
Lutz Hoffman
Mads Barnkob
Martin King
Mats Karlsson
Matt Gibson
Matthew Guidry
mbd
Michael D'Angelo
Mikkel
mileswaldron
mister_rf
Neil Foster
Nick de Smith
Nick Soroka
nicklenorp
Nik
Norman Stanley
Patrick Coleman
Paul Brodie
Paul Jordan
Paul Montgomery
Ped
Peter Krogen
Peter Terren
PhilGood
Richard Feldman
Robert Bush
Royce Bailey
Scott Fusare
Scott Newman
smiffy
Stella
Steven Busic
Steve Conner
Steve Jones
Steve Ward
Sulaiman
Thomas Coyle
Thomas A. Wallace
Thomas W
Timo
Torch
Ulf Jonsson
vasil
Vaxian
vladi mazzilli
wastehl
Weston
William Kim
William N.
William Stehl
Wesley Venis
The aforementioned have contributed financially to the continuing triumph of 4hv.org. They are deserving of my most heartfelt thanks.
Registered Member #33
Joined: Sat Feb 04 2006, 01:31PM
Location: Norway
Posts: 971
After working on this project for a long time, I've finally decided to document it here. Since I have been working on this project over a long time, I will do the writeup in a chronological order.
This project got it's first start some time back in 2003. At that point I had already made a simple SGTC (some time in 2002, I think). I gathered many of the needed parts, and got a bit of it planned, but I was quickly sidetracked by other projects, and forgot all about it.
The real work on this project started just over a year ago. I had just returned from my first Teslathon (actually the Nottingham Gaussfest) and I was determined that I had to make a coil myself.
The secondary was wound on an 11'' piece of 3'' pipe. I wound a 10'' long winding on it with some wire from an old phone relay, estimated to be AWG30-32. The topload was a piece of flexible aluminium tubing and the primary was 6 turns of 15AWG stranded wire. The driver was my signal generator feeding a pair of UCCs, driving an IRFP450 halfbridge through a GDT. This was powered by halfwave rectified mains through a variac. Results were not very good but got a bit better when I discovered that if I tuned the oscillator to below Fres, spark loading would pull it into tune. It was still not very impressive though, partly due to the coupling being too low. Sparks were 5-6'' Video: . I blew a lot of FETs, partly due to it being out of tune, partly because my heatsinks were too small and the thermal interface was bad (I discovered this later).
Then I changed to a feedback scheme with a single gate from a 74HC14 with an antenna on it's input driving the UCCs. This worked about as well as my previous scheme, the sparks were maybe a bit longer. Video: . I also did some experimentation I still blew a lot of FETs. At this point, other projects took over my priorities.
In the autumn, I went to the Cambridge Teslathon. I became motivated to work on it again. I now made a new primary with much higher coupling and changed the heatsinks for some bigger ones. The primary is 5 turns of CAT5 network cable. Each pair is paralleled, and then each of these is put in series. This way it is tappable to 5, 10, 15 and 20 turns, without changing the coupling. I found out that it survived with 10 turns, but I didn't dare to go any lower. Picture: . I also added a startup-oscillator and made it run on halfwave rectified mains again. By now it had started working quite well, sparks were around 10'' and it could run indefinitely without blowing up. I then converted the power stage to a fullbridge. Max. sparklength now was around 16''. Picture: . From this point, I haven't blown any FETs for unknown reasons, but I have lost some during groundarcing and once when I ran the coil without the topload. I then acquired one of the beautiful spun copper toroids from Daniel Uhrenholt, and immediately the coil looked a lot better. Picture: .
After one of the times I blew the FETs due to groundarcing, I changed the FETs for some scavenged 20N60 FETs from Infineon. Strangely, spark length was a couple of inches shorter than usual. This frustrated me a bit, so I was thinking of removing a few primary turns to get the sparklength back up. Not wanting to remake my primary, I tried tapping it to 5 turns. I didn't really want to use this few, as I was sure the FETs would blow, but I decided to try it anyways, to see how long sparks I would get before it blew. I cranked the variac up to 240V and spakrs were 20-22''. The variac amperemeter needle was pegged to the end of the scale, a bit above 8A. Mezmerized by the sparks I kept it running. After about a minute, sparklength started diminishing, and then all 4 FETs blew. I felt the heatsinks, and they were very hot. It seemed that they were the limiting factor of my system now.
The logical next step would be bigger heatsinks. I replaced the FETs (with some scavenged ST 20N60 ones) and used a seperate heatsink for each FET, no electrical insulation between FET and heatsink to minimize thermal resistance. This is where I am at now, and it is reliable. No FET deaths since I changed the heatsinks to seperate ones. Picture of the setup: . Video: . Frame from the YouTube video with very long and straight spark: .
I am satisified with it's performance now. The next step is changing it to use secondary current feedback and making it into a compact, portable unit. Thread will be updated as things happen.
Registered Member #33
Joined: Sat Feb 04 2006, 01:31PM
Location: Norway
Posts: 971
I think I might be pushing around 2-3kW, but I'm not entirely sure, as my electronic power meter constantly resets and displays strange numbers when the coil is running. I should really connect up my digital scope to the line voltage and a current shunt, and set it to multiply the waveforms, and then calculate the average value. If I can find a reasonable resistor to use as a shunt I might try that later today.
Registered Member #1232
Joined: Wed Jan 16 2008, 10:53PM
Location: Doon tha Toon!
Posts: 881
Nice coil Anders and good performance in the videos too. The sword-like sparks remind me of my old SSTC.
The failures with the 20N60 FETs sound like thermal-runaway to me. The TC primary acts like a constant-current load, so as MOSFETs heat up and Rds(on) increases, conduction losses increase causing further heating, etc, etc. You will see a drop in performance right before the MOSFETs blow because more and more voltage is being dropped across the switching devices instead of across the TC primary.
You certainly went down the right route with eliminating the thermal pads from beneath the MOSFETs and mounting them on seperate heatsinks. The only thing I would be tempted to do is to replace the mounting bolts with a clamp (or spring-steel clip) that provides positive pressure over where the die is located in the plastic packages. Fixing semiconductors to a heatsink using a single bolt through the hole in the package actually acts to lift the heat-producing part of the device off the heatsink. It's okay when you're only dissipating a few watts, but if you want to run the devices anywhere near their Id rating, I'd definitely mount them in a way that forces the metal backplate against the heatsink.
Switching to base-current feedback might not make much difference to performance, and could cause problems with body-diode reverse recovery if you didn't bypass these with schottky rectifier diodes?
Have you tried running the coil from full-wave rectified mains!?!? This is visually very impressive, if you are wanting things to try. The spark will be a lot more bushy and flame-like (but shorter) and it sounds more like a full throated roar than the thudding sound you get with half-wave mains bursts. Of course the MOSFETs will get a lot hotter though, so either the thermal side of things needs to be sorted first, or you need to add a few turns to the primary to reduce the load current to compensate.
Registered Member #33
Joined: Sat Feb 04 2006, 01:31PM
Location: Norway
Posts: 971
Thanks for the comments everyone.
I found a set of heatsink clamps for TO247s in a power supply, and it'll be an easy task to mount them onto my heatsinks, so that'll be the next thing I'll do.
The main reason I wanted to use base current feedback was to eliminate the antenna, as I want it to be as compact as possible, and eliminate chances of sparks hitting the antenna, but if it leads to heavy forced recovery of the MOSFET body diodes I'll just stick with the antenna.
I did try fullwave rectified mains a couple of weeks ago. I didn't dare go higher than 50% on my variac though, as the sparks were pretty scary. I'll definitely try this again in the near future.
I'm planning to add a power controller to it so that I won't need the variac to vary the power. The plan is to add phase angle control. I know Richie tried powering an SSTC from a phase angle controller as a part of his SSTC experiments and the sparks ended up crooked due to the sharp rise in the RF envelope, just like with SGTCs and interrupted SSTCs. As I prefer straight sparks, I am going to cut off the end of the half cycle. This should avoid the sharp rise in the RF envelope, and hopefully not make the sparks too crooked. This could simply be implemented with a zero crossing detector and a monostable driving the enable input of my gate drivers, but I am going to implement it with a PIC12F675, which should be relatively simple. Any thoughts?
Registered Member #1232
Joined: Wed Jan 16 2008, 10:53PM
Location: Doon tha Toon!
Posts: 881
A couple of comments...
I did try fullwave rectified mains a couple of weeks ago. I didn't dare go higher than 50% on my variac though, as the sparks were pretty scary. I'll definitely try this again in the near future.
If it survived that 50% run for any length of time then it would likely survive 100% on the variac. It is interesting to note that after breakout the TC acts very much like a constant current sink. Therefore the current through the MOSFETs is almost constant from the point when breakout is reached, right up until full mains voltage. My point here is that the MOSFETs aren't actually stressed that much more should you have decided to increase the voltage from 50% right up to 100%. Switching losses will increase due to the increase in V. But conduction losses will only increase slightly because the actual primary current does not increase very much. (If you use a CT to view either the primary current or the secondary base current you will see what I am talking about. The current envelope is not like a sine envelope, but almost has its peaks squashed flat due to the constant current behaviour of the TC beyond breakout.)
As I prefer straight sparks, I am going to cut off the end of the half cycle. This should avoid the sharp rise in the RF envelope, and hopefully not make the sparks too crooked.
I have absolutely no idea what the sparks will look like or sound like with reverse phase-angle control! BTW Reverse phase-angle control using IGBTs is common in high-power light dimming applications because EMI is easier to control than with conventional phase-angle control with thyristors. (You can control how quick the IGBT turns off, but you have limited control on how quickly a thyristor turns on.) So you should be able to find some design references explaining how to do it.
Registered Member #1025
Joined: Sun Sept 23 2007, 07:53PM
Location: Czech Rep.
Posts: 566
Hi Anders, I hate your coil! Once I saw your pictures in "Post your cool SSTC picture" sessions I decided redesign my own coil completely and this attempt cost me already 4 transistors and I'm still far away! You should get the bill for those poor little BUP314...
Now seriously, in my eyes you have the best SSTC I have seen.
But, I have a comment to the sparks. The length is very impressive (compared to the size of the coil) but the sword-like appearance is not as attractive as branched sparks (my personal opinion). My coil is single switch working in classE and it produces branched sparks. I took few short exposition pictures today and sending them to compare (at 1500W BTW: The easiest way of measuring the power consumption of your coil is via the speed of rotation of you home power meter. You can even buy some old one in case it’s not easy to set up in your home).
The branching is a very enigmatic thing and your coil is very interesting by showing the opposite extreme...
Registered Member #95
Joined: Thu Feb 09 2006, 04:57PM
Location: Norway
Posts: 1308
I see you don't need to bother with DRSSTCs to get good streamers, Anders! Your SSTC is amazing, great job. I'm inspired to start a new coil myself. Keep up with the upgrades, it'll be interesting to see how this coil can be improved.
This site is powered by e107, which is released under the GNU GPL License. All work on this site, except where otherwise noted, is licensed under a Creative Commons Attribution-ShareAlike 2.5 License. By submitting any information to this site, you agree that anything submitted will be so licensed. Please read our Disclaimer and Policies page for information on your rights and responsibilities regarding this site.
My Solid State Tesla Coil
BTW Reverse phase-angle control using IGBTs is common in high-power light dimming applications because EMI is easier to control than with conventional phase-angle control with thyristors. (You can control how quick the IGBT turns off, but you have limited control on how quickly a thyristor turns on.) So you should be able to find some design references explaining how to do it.
Your SSTC is amazing, great job. I'm inspired to start a new coil myself. Keep up with the upgrades, it'll be interesting to see how this coil can be improved.