Sources, Collectors, and Power

Tapping Vacuum Energy. You're getting the excess electrical energy directly from the vacuum,
as we briefly pointed out above. The vacuum will freely replenish all the "trapped voltage" you
extract from the primary source during the electron relaxation time. It won't replenish a single bit
of "dissipated voltage" (power) you extract from the source.
Note that the same considerations apply in the collector. It's got to have a somewhat longer
electron relaxation time. Its electrons stay "unrelaxed" during the collection cycle, and allow for
some additional switching time to connect to the load. The "trapped voltage" across the collector
multiplied by the number of trapped coulombs in it, gives the number of joules of FREE EM
ENERGY you extract and get into and onto the collector (the shovel). In other words, that's your
"shovelful of coal." You then throw the "shovelful" onto the fire/load -- you simply disconnect the
collector from the primary source and connect it across the external load. The collector
(secondary battery) now powers the load and its own internal resistance, "killing" itself while
furnishing the energy for powering the external load as well.
The Source Can Be Almost Anything: You can use as a source a simple elevated wire, to
"tap" potential from the 200-300 volts/meter between earth and ionosphere. Here again, you
need to utilize calibrated, doped wire.
Finally, you must adjust the repetition switching in accordance with the discharge time through
the load. In other words, you have a serial process as follows:
(1) extract trapped energy (potential) from the source onto the collector, Δt1.
(2) Switch the collector off the source, onto the load, during time Δt2.
(3) Wait while the collected energy in the collector discharges through the load, during time Δt3.
(4) Switch the collector back off the load and onto the potential source, during time Δt4. That
completes one cycle.
The serial timing simply is [Δt1 + Δt2 + Δt3 + Δt4].
If you balance all the doping and the materials design, and correlate the switching, you can get
all the free energy you wish. Properly utilized, a single car battery can be used to power an
electric automobile indefinitely. Or even to power a battleship. In the real world, of course, you
will inevitably have a tiny bit of loss as you go, because there's a finite (though high) resistance
between the two poles of your battery. Handling that is a piece of cake. Simply run a separate
little collection circuit to collect a little bit of trapped EM energy from the slowly leaking source,
and ever so often feed the collected energy back into the battery as power, to "reseparate" the
charges (charge the battery) and replace the small amount of the primary source's potential
gradient that has been lost. The battery, load, and "trickle charger" then become a closed-circuit
free-energy source that will last for years and years.
Limited Only By One's Imagination: Of course you can see many variants; this is just the
"master key." You can have multiple collectors, collecting trapped energy simultaneously or in
sequence off a single source, and pooling their collected energy to more powerfully power the
load. You can utilize a very high "voltage", such as in the Swiss electrostatic overunity device, to
increase the energy collected per coulomb in each switching (in each shovelful) in accord with
equation [8]. For a battery, you can set a separate little collector/load device to trickle-charge
the battery, overcoming the small normal "leakage current" that does occur in batteries and in
real circuits and devices. The opportunities are endless. You can put in a unit to take mostly
only power-free energy from the "power line" feeding your business or home, reducing your
utility bill by -- say -- 90%. Or you can simply build a small home power unit to do the whole job,
for only a few hundred dollars. This simple secret can be used to power the world, cheaply and
cleanly, and to clean up the biosphere.