Flyback Transformers Flyback Transformers Disclaimer: I'm not responsible for anything. You can kill yourself with the circuits shown here. "Fly Flybac back" k" transformers transformers (or line output o utput transformers) transformers) are hi high gh frequency frequency ferrite-cored ferrite-c ored transformers, used to generate high voltage needed to operate a Cathode-Ray Tube (CRT) device (such as TV, monitor...). This voltage can be anything from few kV to few tens of kV (color TV ~25kV; B/W TV ~15kV usually). Operating frequency is around 16kHz in TVs, butt the bu the fl flyback can be operated operated any anywh where ere from from sev several eral kHz to several several ten tenss of kHz kHz.. In order to get some output from the flyback transformer you need a fairly powerful high frequency driver circuit. I'll give you a few examples of such circuits. Types of flyback transformers
Type [1] is the older AC unrectified type. This one isn't usually good for anything over 30kV, because becau se itit wi will flash ov over er soon (an (and d also also because because itit has has usu usual allly low nu number of tu turn rnss on its secondary winding and thus it is difficult to get high voltages out of it). However it is often suitable for higher power outputs than the other types. Found in old TVs.
Type [2] is probably the best one. Its secondary winding is divided into sections, which are separated by diodes, so there's just little AC voltage present, which makes insulating it easier, so it can output much more voltage than type [1] (voltages of 60kV and more are often possible). Found in newer TVs. Type[3] is the same as [2] except it has high voltage capacitor on its output, which makes it nearly useless for drawing arcs (because instead of an arc, you get a series of (loud) spark discharges). Found mostly in computer monitors. Finding the high voltage negative pin on your flyback
Before you can make any sparks with your flyback, you must find the high voltage negative pin. If you have the old type flyback without diode, it's easy. You can find it with an ohmmeter, the secondary winding will have anywhere from few tens to few thousands ohms. If you have the new potted type with build-in diodes, it can't be measured with an ohmmeter, because the diodes starts conducting at ~20V. For this purpose, connect a positive voltage of about 30V (three 9V's in series) to the flyback output wire, and measure a voltage between negative output of the power supply and all pins on the flyback's base. The pin that gives the most voltage will be your negative output, which you should in all cases connect to the mains ground. Now some circuits for driving your flyback transformer: Circuit 1: Single-ended driver
Output power: Medium to low Output voltage: High This circuit works best with the newer type potted "diode-split" flybacks. It can provide quite high output voltage (50kV from diode-split transformer is not unusual). This driver is not too efficient above around 100W at which the switching transistor starts getting very hot. If you want higher output power I suggest the second driver. The switching transistor (IRFP250) needs a small heat-sink. Wind a primary windong of 12 turns of insulated wire around the exposed part of the ferrite core. Turn the "duty cycle" pot down, and set the "frequency" pot to greatest resistance (lowest frequency). Turn up the duty cycle until you can just hear a high-frequency sound. Make some sparks with the flyback (they will be quite small at this point) so you know the driver is working. If the flyback has built-in diode (the newer "potted" type), try to reverse polarity of primary winding and see if the sparks are longer. If not, reverse it back. Turn up the frequency until you just can't hear it (this is usually the best frequency to run your flyback at, but you can experiment). Now you can try slowly increasing the duty cycle (increasing output power), watch the transistor so it doesn't get very hot. If you now can get a nice purple arc from the flyback, that can be drawn to few cm, your driver is working well. If not, something is probably fried (most likely the flyback itself). Some pictures of my driver: The driver
Inside
Short arc
Long arc
"spraying" (corona)
Circuit 2: Half-Bridge driver
Output power: Very high Output voltage: Medium to low The transistors need heatsinks, but these don't need to be large. Wind a primary of about 40 turns (of 0.5mm or thicker wire) around the exposed part of the core. Insulate the primary from the core well!
Something on resonance: All transformers have their resonant frequency, flybacks included. If your driver accidentally runs on the resonant frequency (or its harmonics) of your flyback, an excessive voltage builds up on the output from the flyback (which could theoretically rise many times the voltage the transformer can sustain), and the transformer literally bursts in flames. For this purpose, I suggest to put a small lightbulb (40W) in series with the mains. Now, turn on the driver, and without drawing an arc from the flyback, adjust the frequency to where the lightbulb is darkest (the least current is drawn), this indicates you are safely away from resonant frequency (and its harmonics), because at resonance the current drawn is the highest. Make a few sparks with the flyback so you know it's working. Now you can remove the bulb (or if you want to be safe, use a larger one until you remove it completely). The power of this driver is mainly limited by your flyback, most flybacks start getting hot above some 300W. The arc generated using this driver is very hot and powerful, has appearance of a yellow/white flame, and can be drawn out in over 10cm in some cases. If you want more power, you can try to remove some turns from the primary winding, but remember, removing turns raises resonant frequency, so frequency usually needs to be readjusted. Also watch the temperature of the transistors, they can get quite hot at high power after some while. Video of arcs[1] Burning a CD[2] Arc pictures:
1. http://youtube.com/watch?v=CqUtfInNYqU 2. http://youtube.com/watch?v=GNCs-C4q4bg