Michel WFC Report_Jan06.pdf
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Cars running with pure water !
MichelÔs project status (January 06)
Reminder:
See also MichelÔs project status (Sept 05)
Among lot of projects related to water running with water, only one seems for us credible, the
Stanley Meyer Project.
Our goal is to produce Hydrogen and Oxygen using the fracturing process on the water
molecule, as described by Stan Meyer is his patents and notes
Our experiments are based on the Patent N 4 936 961, with the help of 11 extra documents:
see Memo WFC 422 È from S. Meyer.
We have worked on this project for 2 years.
Our main conclusion for the moment:
the process, as described in the patent È961 doesnÔt
work! Most information in the patent and in the notes is separately true and seems coherent,
but globally, some information seems missing, or hidden!
We understood through the video, that Meyer would have protected his invention
We have to investigate with patience to find again his secret.
One major point in our understanding of the patent is that the WFC is not a capacitor as
explained in the patent.
The WFC is in fact a pure resistor, very constant for any frequency and wave form.
The value depends on the size of the electrodes, the distance, and the type of water.
Consequence:
• the electrical resonance between WFC and resonant charging choke has no meaning
• The current leakage in the water is very high
• The step charging effect seems not possible.
In the next pages, you will find a sum up of the most important experiences we did, with
diagrams, explanation, pros and cons, and conclusion.
Then you will see how we are coming back to the original patent as described by Meyer.
Before reading this document, please note that we have not yet produced any H2/O2 bubbles
using the explained process of Meyer.
All conditions are not yet finalized and completed to start the fracturing process.
È a long way to the free energy È
Report dated 2
nd
of February 2006
Main idea: => generate a Ñstep charging effectÒ, high voltage, with no
current in the WFC. The WFC is simulated by a true capacitor C
Diagram:
Y1
scope
L
Electronic rectifier
Transformer Tr
scope
D
Gen
600
Y2
Power
amplifier
20 Vcc max
WFC
R
Y cap
B
T1
Circuit description:
• Sine wave generator: output 10 Vcc / 600Ohms, frequency is adjustable (used range 1 to 40 KHz)
• Electronic rectifier to have a half sine wave (home made)
• Audio Power amplifier (HiFi or similar)
• Transformer Tr different versions have been tested
• Diode D : 800 V, rated for switching power supply (high frequency)
• inductor L: the resonant charging choke: different type, from 0.1 mH to 5 H,
with or without ferrite core;
the value changes depending of the position of the ferrite core
inside the charging choke
• WFC:
replaced by a true capacitor (Y type, used in the main filter in
switching power supply; rated 400 V, can absorb 2 KV
Results:
Input of the transformer:
0 to 20 V c max
Output of the transformer:
0 to 600 Vc max
Caution: depending of the signal frequency, and core type, signal distortion could appear
Without discharging circuit, the voltage on the WFC (= capacitor) became constant (DC)
Like a classical power supply!
Need of Discharging circuit:
Resistor R = 1 K ohms, carbon type, 3 W
Transistor T1: Mos type or Hex Fet, rated 800V, 4 A
Principle:
When the capacitor is charged, after some pulses, the transistor T1 is driven ÑonÒ to
discharge the capacitor with a 1 Kohm resistor, see next page.
Report dated 2
nd
of February 2006
Whole circuit:
scope
Y1
L
Electronic rectifier
scope
Transformer Tr
D
Gen
600
Power
amplifier
Y2
20 Vcc max
WFC
Rd
Clock
Y cap
A
Counter
B
Clock
Discharge B
Number of pulses adjustable from 1 to 16
Driving A
Number of pulses adjustable from 1 to 16
The counter circuit is a home made design, using 2x 40193 counters and gates
Input:
The clock signal is generated by the pulsing signal
Outputs:
driving A: for the primary of transformer
driving B: to control the discharge time
Report dated 2
nd
of February 2006
Different transformers have been tested:
• Power supply transformers 50/60Hz
• Switching power supply from old PC or other electronic devices
• Fly back transformer for line deflection unit in TV
• Home made transformers
Objective:
Our need is to define and to find the right transformer to get a 1500 V pulsing signal;
Ratios of 50, with 30 V signal input should comply.
Sump up of the tests and results :
1. Power supply transformers 50/60Hz,
Prim: 220Vac, sec: 6Vac, reverse connected, ratio = 35
The bandwidth is limited: the useful frequency of the driving signal is
from 50 Hz to 1 or 2 KHZ max, due to the metal core itself and high inductance
2. Switching power supply from old PC or other electronic devices
Since the core is in ferrite material, the frequency could reach 50 KHz, or more,
depending of the core type and the number of turns involved in the primary and
secondary windings.
The ratio between Primary and Secondary is 15 to 30 max.
3. Fly back transformer for line deflection unit in TV or PC monitor
o
Typical frequency: 15 to 90 KHz
o
Typical voltage on the primary: 200 to 400 V
o
Typical voltage on the VHV:
30 KV (colour TV)
o
Ratio is approx:
75 to 150 max
High voltage diodes D are built in the transformer
Unfortunately, the gauge of the wire is not adapted for high current (must be < 0.5
mA!) It could be used only in process working with insulated electrodes and
low current in the WFC.
4. Home made transformers:
We have now got a device to do windings and home made transformer.
E core are in ferrite material, used wires are 0.15mm, 0.25mm, 0.4mm
Transfo 1: primary: 20 turns; 0.4 mm
secondary: 600 turns; 0.15 mm
Transfo 2: primary: 20 turns; 0.4 mm
secondary: 900 turns; 0.15 mm
Conclusion:
There is no ideal transformer; it depends on the need and associated circuits and
process.
Report dated 2
nd
of February 2006
Results: different views of the step charging effect. Voltage can reach 800Vp
2 signals: driving signal on the pulsing transformer, and step charging effect
With the programmable counter, we can define:
o
the number of pulses needed for the step charging,
o
and the numbers of pulses for the relax time
The max voltage of the step charging is defined by the ratio of the transformer Tr, and the
adjustable input voltage.
Typical value is 400V peak; higher voltages are possible, but some
problems occur: distortion, noise, È
The shape is also adapted by tuning the charging choke L
Note: More detailed information is of course available, but written in French!
Report dated 2
nd
of February 2006
Plik z chomika:
czegoniema
Inne pliki z tego folderu:
The Voltage Intensifier Circuit.pdf
(1658 KB)
stan_meyer1.pdf
(2834 KB)
Possible Theory On How The Water Fuel Cell Works.pdf
(645 KB)
Stanley Meyer_ Water Fuel Cell.pdf
(551 KB)
The Gas Voltage Control Circuit.pdf
(436 KB)
Inne foldery tego chomika:
Dave Lawton
DAVE_STANLEY_MEYER_REPLICATION_WATER_FUEL_CELL_2004
jnaudin
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RAVI_STANLEY_MEYER_REPLICATION_WATER_FUEL_CELL_4_SEP_2007
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