MOSFET transistor This is a 400 or 800 volt, (125 watt,

low Rds < 1 ohm) MOSFET

transistor.

The 2 High Voltage diodes shown

are 1000 volt Rectifier diodes.

Jon Abel (Jonabel1971@gmail.com) – Resonant Regenerative Fuel Cell v 1.1 These 2 circuits were found free, online, and I interfaced them together. I achieved parametric resonance on June 20th, 2011. The left circuit

is a Dave Lawton Pulse Width Modulator, found at http://waterpoweredcar.com/pdf.files/D14.pdf. The right circuit is JL Naudin’s original

Water Fuel Cell replication from 2001, found at http://jnaudin.free.fr/wfc/index.htm .This design is cheaper & less complicated - and - is a

manually adjustable alternative to building and attaching the 8xa & 9xa circuits meant to automate the Stan Meyer WFC.

Power Resistor

The 1.2 kilo-ohm resistor is a higher wattage POWER

resistor, and can be used for High Voltage testing, but is

also not needed for low-voltage (< 30 volts) testing.

Windings & Magnetic pole locations. The labeled “1-4” north & “2-3” south positions on the transformer diagram are important &

matched for both transformers. You will need to connect the coil-system based on these pole

positions. Labeling each wire on the coil ends with masking tape/sticky labels is extremely helpful.

Design & Construction of Coil The required bifilar coil system shown to the left is based off of the 1894 Nikola Tesla bifilar pancake coil patent. I was able to get results using a 5/8”

diameter, 8” long ferrite rod as my core material. I used the suggested 24 AWG bifilar-wrapped copper wire, but 430 Stainless Steel wire has been tested,

and also works. Input to the primary is 0 – 30 volts. Initial tests on the ferrite core have shown resonant pulses to be as high as 100 volts with copper, and

200 volts with 430 Stainless steel wire.

The primary/secondary transformer is also wrapped on the same ferrite rod as the bifilar coil. The bifilar coil is a 1:1 winding ratio. Secondary/Primary coil

is a 3:1 winding ratio or higher.

1. Bottom layer is 2 wires, 24 AWG (copper or 430 Stainless Steel), wrapped bifilar, wound uni-directional, end-to-end.

** Note : 430 Stainless Steel wire is also considered “magnet” wire, due to its magnetic properties. It is also preferable to copper for this circuit.

2. Middle layer is 1 wire, 20 AWG copper, wound uni-directional, end-to-end.

3. Top layer is 1 wire, 30 AWG copper, wound uni-directional, end-to-end.

Pipesets (history & replication) Stan Meyer used variable length Stainless Steel Pipes for his

early testing.

Both 3 inch, and 15 inch pipes have been used by Stan Meyer.

Water Injectors used only a 1” reaction length.

Variable reactor area spacing of 1-10 mm has been

demonstrated by Stan Meyer – showing that closer proximity

improves output. He used SS pipes and rods, prior to

designing his water injectors.

I only used internal and external pipes, no rods. The pipes I

tested are ¾” and 5/8” OD diameters. Spacing is 0.7 mm.

Spacing for the “water injector” design is .020” or about 0.5

mm), but also requires the machining of round, tapered

cavities.

*** Note : Multiple pipesets - tested in series – improve overall

efficiency to a certain point. Cells are typically built with anywhere

from 1-11 pipesets.

Achieving the Polarization effect (greater than 1500 volts) Once resonance is reached with the above coil, the “Polarization” effect can then be studied and verified. Coil voltages of at least 1.5 kilovolts are needed to

achieve this claimed LENR effect. A larger 2000 volt coil can be constructed using thinner wire, CRGO Silicon Steel, and well-crafted, multi-cavity bobbins

made from Delrin. Plans for building this larger VIC (Voltage Intensification Circuit) coil - and associated water injectors can be found at RWGResearch.com.

Link : http://rwgresearch.com/open-projects/stanley-meyers-wfc-tec/stanley-meyer-wfc-water-injector-technology/ .