Dave Lawton. A solid-state semiconductor
circuit which has proved successful in producing pulses like this is shown as
part of Dave Lawton’s replication of Stan Meyer’s Water Fuel Cell. Here,
an ordinary NE555 timer chip generates a square wave which feeds a carefully
chosen Field-Effect Transistor the BUZ350 which
drives a water-splitter cell via a combined pair of choke coils at point “A” in
the diagram below.
Stan Meyer used a toroidal ferrite ring when he
was winding these choke coils while Dave Lawton uses two straight ferrite bars,
bridged top and bottom with thick iron strips. Chokes wound on straight
ferrite rods have been found to work very well also. The effects are the
same in all cases, with the waveform applied to the pipe electrodes being
converted into very sharp, very short, high-voltage spikes. These spikes
unbalance the local quantum environment causing vast flows of energy, a tiny
percentage of which happens to flow into the circuit as additional power.
The cell runs cold, and at low input current, quite unlike an ordinary
electrolysis cell where the temperature rises noticeably and the input current
needed is much higher.
Stan Meyer used a toroidal ferrite ring when he was winding these choke coils while Dave Lawton uses two straight ferrite bars, bridged top and bottom with thick iron strips. Chokes wound on straight ferrite rods have been found to work very well also. The effects are the same in all cases, with the waveform applied to the pipe electrodes being converted into very sharp, very short, high-voltage spikes. These spikes unbalance the local quantum environment causing vast flows of energy, a tiny percentage of which happens to flow into the circuit as additional power. The cell runs cold, and at low input current, quite unlike an ordinary electrolysis cell where the temperature rises noticeably and the input current needed is much higher.
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