Binary Resonant System
Harvey Norris ( (no email) )
Sat, 30 Jan 1999 15:40:13 PST
To give an idea how this BRS works as a resonant choke circuit I will
give an example of two different loads placed between the unobvious
potentials, a neon bulb and a 55 ohm incandescent bulb. First I measure the
voltage with no load. I tried using a surplus kilovolt meter which the
measurement pegs past the 6,000 volt range. I know this is wrong because
only about 3,000 volts should be measured. Now when I connect a neon bulb
across the midpoints about .7ma conduction@300volts is observed. When the
55 ohm incandescent is placed across this input the voltage then only reads
about 1/10th of a volt allowing 5.6 ma conduction which will not light the
bulb. In this kind of circuit a short or low ohmic resistive load then
chokes off the voltage that would cause more amperage to exist than is
inputed. Likewise a high resistance allows a higher voltage to be used. In
this example the neon bulb will not light from wall voltage but will light
from the BRS which can raise the voltage to a load without using a
transformer, as is used in common applications where a voltage rise is
necessary. To compare the efficiencies involved here ;the neon bulb
consumed 16ma input from the wall times the 120 volts equals almost 2 watts.
The neon bulb itself used about 0.2 watts. The rest of the energy is
assumed wasted as heat on the two 1000 ohm coils placed in parallel to make
this binary resonant system. The other example of the incandescent bulb
shows how these near short conditions approximate parallel resonance. Only
0.25 ma input is recorded although conduction through the bulb is 5.6 ma.
However again the actual wattage drawn by the load is far below input. One
can see by these efficiencies that this method of raising a voltage to a
load is very impractical compared to that of the transformer. But the
advantages of the BR System is that very high frequencies can be evolved far
past that used in typical quarter wavelenth predictions used in tesla
coils. These coils of 9 miles length should yield a quarter wavelength
value of around 5,000 hz but I am obtaining a frequency of about 166,000 hz
using the BRS arc gap method.
Sincerly Harvey D. Norris (formerly Meat Truck)
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