Been messing with bifilars recently on a small toroid for restricting current, mainly for proof of concept, had some success but usually the voltage is lost through resistance before you can charge a small capacitor or get any bubbles in a small WFC.
Been reading Stan's patents, went through a few schematics convinced we've all missed something because we've all built cells and either get no voltage on them or a sudden in rush of current.
Now at this point you'll be saying 'yeah yeah heard it all before' but please read on because i'm going to open your eyes. I've got some rather interesting news and I promise some rather large pennies will drop: The most popular VIC which everyone is copying, the one with the secondary with blue tape, the primary with yellow tape and the two chokes in red tape, remember that one? Well you've all been wiring it wrong and thats why no ones cell will work.
BOTH THE CHOKES ARE BIFILAR and I can prove it both in concept and in theory. Not only that I can show you exactly what the 220 Ohm resistor does and why it does it. This morning I created a VIC with a primary, a secondary and two bifilars on the same core, See below pics for the scchematic:
At this point lets get a small understanding of a bifilar, if you have a bifilar on a core with the primary and pulse it with dc this happens:
You end up with two positives at one end and two negatives at the other and the current runs in one direction only during the callapse of the magnetic field. Both of Stans chokes are wired in this way and on L1 both wires are positive, one of them goes to the water fuel cell and the other is wired to the secondary but the diode biases the voltage in favour of the secondary and stops two current fields meeting head on. At the other end of L1 there is a 220 Ohm resistor and we'll talk about that later.
L2 has two negatives on show, one goes to the cell and the other goes to the negative from the secondary as per schematic. What happens is the secondary, L1 and L2 try to collapse their magnetic fields because of the pressure applied on them by the WFC, The water fuel cell has immediate access to voltage from a natural positive from L1 bifilar and a natural negative from L2 bifilar and tries to draw current from both coils. But here is where the magic happens, the secondary is also trying to collapse its magnetic field in the direction of the diode and the resistor R1 but it can't because the residual current in L1 is trying to go in the direction of the WFC and its own magnetic field dictates that current can only flow in one direction not two. Now look at L2, you've got the secondary pulling on the current from it as well as the WFC but the other end of the L2 bifilar is shorted so that a bidirectional current can only occur which goes against the unipolar field.
What you have with the bifilar's is a unipolar magnetic field trying to be bi-directional, its the WFC in one direction verses the resistor in the other direction and the current is locked but you still have a natural positive and natural negative potential on the WFC.
About the resistor, it is the value of all three coils, L1 and L2 and the secondary because it has to be. If you are removing any residual current from the series circuit and causing a current lock then for impedance reasons it has to be value of the coils in series.
So what heppens when you put this into practise? As you approach resonance of the chokes the voltage potential rises by a massive amount compared to before with the single bifilar and the current is still 100mA but now I can charge caps at a very quick rate indeedy, the resistor removes any residual current from the series circuit even though its the wrong value for my smaller set up. Bubbles you ask? On my smaller twin plate cell there's plenty of bubbles.
Next step, i'm rewiring my chokes on my full set up so they are both bifilar and i'm going in full steam ahead.
Been reading Stan's patents, went through a few schematics convinced we've all missed something because we've all built cells and either get no voltage on them or a sudden in rush of current.
Now at this point you'll be saying 'yeah yeah heard it all before' but please read on because i'm going to open your eyes. I've got some rather interesting news and I promise some rather large pennies will drop: The most popular VIC which everyone is copying, the one with the secondary with blue tape, the primary with yellow tape and the two chokes in red tape, remember that one? Well you've all been wiring it wrong and thats why no ones cell will work.
BOTH THE CHOKES ARE BIFILAR and I can prove it both in concept and in theory. Not only that I can show you exactly what the 220 Ohm resistor does and why it does it. This morning I created a VIC with a primary, a secondary and two bifilars on the same core, See below pics for the scchematic:
At this point lets get a small understanding of a bifilar, if you have a bifilar on a core with the primary and pulse it with dc this happens:
You end up with two positives at one end and two negatives at the other and the current runs in one direction only during the callapse of the magnetic field. Both of Stans chokes are wired in this way and on L1 both wires are positive, one of them goes to the water fuel cell and the other is wired to the secondary but the diode biases the voltage in favour of the secondary and stops two current fields meeting head on. At the other end of L1 there is a 220 Ohm resistor and we'll talk about that later.
L2 has two negatives on show, one goes to the cell and the other goes to the negative from the secondary as per schematic. What happens is the secondary, L1 and L2 try to collapse their magnetic fields because of the pressure applied on them by the WFC, The water fuel cell has immediate access to voltage from a natural positive from L1 bifilar and a natural negative from L2 bifilar and tries to draw current from both coils. But here is where the magic happens, the secondary is also trying to collapse its magnetic field in the direction of the diode and the resistor R1 but it can't because the residual current in L1 is trying to go in the direction of the WFC and its own magnetic field dictates that current can only flow in one direction not two. Now look at L2, you've got the secondary pulling on the current from it as well as the WFC but the other end of the L2 bifilar is shorted so that a bidirectional current can only occur which goes against the unipolar field.
What you have with the bifilar's is a unipolar magnetic field trying to be bi-directional, its the WFC in one direction verses the resistor in the other direction and the current is locked but you still have a natural positive and natural negative potential on the WFC.
About the resistor, it is the value of all three coils, L1 and L2 and the secondary because it has to be. If you are removing any residual current from the series circuit and causing a current lock then for impedance reasons it has to be value of the coils in series.
So what heppens when you put this into practise? As you approach resonance of the chokes the voltage potential rises by a massive amount compared to before with the single bifilar and the current is still 100mA but now I can charge caps at a very quick rate indeedy, the resistor removes any residual current from the series circuit even though its the wrong value for my smaller set up. Bubbles you ask? On my smaller twin plate cell there's plenty of bubbles.
Next step, i'm rewiring my chokes on my full set up so they are both bifilar and i'm going in full steam ahead.