It also follows that the cell itself could serve as a kind of transformer if the induction coils were wound around the cell. A soft iron core could be included in the center of the cell (isolated from the solution within the cell). Then the wire feeding the cathode could be wound in say 100 turns around the cell and the wire coming from the anode could be wound 200 times or whatever. I have constructed such a cell in a small scale and with a 9volt transistor battery connected the mini cell produced steady streams of gas for over 2 days before draining the battery.
Another way is to have the inductor positioned between the electrodes. This creates a parallel circuit with the inductor boosting the voltage and the cell carrying the current. As long as the resistance of the cell is substantially lower than that of the inductor this configuration will work. I have designed and constructed prototypes which have functioned as predicted.
Conclusion: Based on the data obtained in this experiment and the experiments detailed in my previous paper; "VLR Cells", I believe that I have shown that a) a cell or series of cells can be designed which will produce ANY amount of hydrogen desired if the design of the cells is such as to allow a sufficient amount of current to flow through the cell or cells and a minimum voltage (around 2v) can be maintained across each cell.
With this paper I believe I have shown that the electricity delivered to the cells can be manipulated or augmented in at least one way in order to recapture the energy which is lost as the "voltage drop" across the cells by the use of permanent magnets and or by induction.
My next paper will deal with other ways to reduce or eliminate
the voltage drop and after that I will look at ways to modify the link
between the cells and the power source in order to lessen the amount of
current which has to pass through said power source.
END
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