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 - glass
- quartz
- ceramic
- brick
- copper
- aluminum
- cast
iron
- titanium
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 - brick
to iron
- brass
to glass
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 - carbide
- diamonds
- tungsten
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- ORDER
THIS DVD
Documentary
from locations around the world, including
actual use of Brown's Gas doing special welding,
explosions,implosions and running gasoline
engines on water.
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- NEWS
FLASH:
- New
evidence
of the unique properties of Brown's
Gas
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The current theory of Brown's Gas states that
Brown's Gas is a mixture of di-atomic and
mon-atomic hydrogen and oxygen. Brown's Gas,
Book One explains it in detail, but here is a
peek.
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- The
simplest
way to make Brown's Gas is
to use an
electrolyzer, which uses electricity to split
water into its elements of hydrogen and
oxygen. At the instant that the water splits,
the hydrogen and oxygen are in their
mon-atomic state, this is H for hydrogen and
O for oxygen.
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- Normal
electrolyzers encourage the hydrogen and
oxygen to drop to their di-atomic state.
Di-atomic
means the
hydrogen formed H2 and the oxygen formed O2.
The di-atomic state is a lower energy state,
the energy difference shows up as heat in the
electrolyzer. This energy is now unavailable
to the flame.
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- WHAT IF a
significant number of these H and O atoms did
not reform into di-atomic molecules? We start
by adding 442.4 Kcal per mole to split water
using electrolysis. This is an endothermic
(energy absorbing) action. But if we have no,
or little, 're-bonding' into di-atomic
molecules, then our electrolyzer wouldn't
heat up, because there would be no exothermic
reaction that would cause excess heat, beyond
the agitation of the fluid by the bubbles.
This 'lack of heat' in the electrolyzer is
what I noted in my experiments that actually
produced Brown's Gas.
There would
also be a significantly larger volume of gas
produced by the electrolyzer, well beyond any
reasonable expectation of a 'normal'
electrolyzer, because the mon-atomic moles
would take up twice the volume that the
di-atomic moles for the same weight of water
electrolyzed.
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- My
experiments verify this: not to that
efficiency, but much more volume than you
could expect by assuming a maximum efficiency
to a normal electrolyzer. The math and
experiments are well documented in Brown's
Gas, Book One'. For a quick example, let's
use the results of an independent test of
Brown's Gas by an engineer named Harald
Hanisch. Mr. Hanisch was Director of Research
and Development of Simmering-Graz-Pauker, a
large machine-building and railway-car
manufacturer owned by the Austrian
government. He couldn't believe that oxygen
and hydrogen could be mixed and burned safely
and he certainly would not believe that Yull
Brown got any 340 liters of gas per
kilowatthour.
- Mr. Hanisch
decided to go to Australia to see for
himself. He wanted to test for himself the
actual input of electricity and the actual
output of gas. During his actual testing,
with the water displacement method, he found
Yull Brown's machine produced 368 liters per
kilowatthour.
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