Water, Part 5 (Merry Christmas)

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Hi All,
I decided that I might as well make this my christmas present to the
world this year. Being on the verge of the new millennium makes it even
more appropriate and besides, I never had the chance to give the world a
present before. I weighed the option of trying to make a buck or two
off of it first but I would have had to get all greedy and secretive to
do that and I don't want all of the hassles. Maybe, if I turn out to be
right, the world will give me something back anyway and that's better
isn't it? Even if I got nothing back I'd be no worse off than I am now
anyway would I?
Right then, let's get to it. Here's how you can make water into a
real, cheap, limitless source of fuel. One that will replace all liquid
and gaseous forms of fossil fuels forever. And one which can be used
TODAY because most systems that currently use fossil fuels could be
retrofitted to use this fuel. When you are finished reading this you
will probably think is is a rather stupidly obvious answer but that's
not my fault is it?
The first thing that we have to do is to think of water as a
conductor. Not just realize the fact that it will conduct electricity
but actually think of it as you would a piece of copper or aluminum
wire. Interestingly enough I read somewhere that there were experiments
being done one time on using little water filled tubes as conductors in
situations where high conductivity with low resistance was needed. So
think about it that way. Water as a piece of liquid wire (with
electrolyte added).
Now let's look at the diagram of the simple electrolysis cell from
"Water, Part 4". Notice how the main electrical supply line from the
power source (Box P) feeds directly to the + terminal on the unit. Then
consider the water between the + terminal and the - terminal as a
conductor. One with high conductivity and low resistance. Sort of like a
splice in our normal copper feeder line. Picture cutting a copper wire
and then fastening a piece of aluminum wire between the cut ends. You
end will end up with a longer piece of total wire right? The basic
ability of the line to carry a charge would be unaffected.
If you wanted to be really picky such an arrangement would put a few
more variables into the mix since we are now using two totally different
conductors with different individual properties (aluminum is a better
conductor than copper for example). I don't think that the overall
performance of the line would be affected by that splice though. Do you?
Course not.
Now let's do the same thing but instead of using aluminum wire let's
put an electrolysis cell like the one in "Water, Part 4" in and see what
happens. Actually let's drop the EMF coil from it. We won't need that
any more.
The thing that we have to see here is that water is a difficult thing
for us to use as a conductor because of it's rather nasty habit of
decomposing into a potentially explosive combination of hydrogen and
oxygen gasses whenever an electrical charge passes through it. Here's
where anyone doing research into using water as a conductor would put
water on the shelf and forget about it. In this scenario the very gasses
that we want to use for fuel are an annoyance.
Now keep that idea of water as a conductor in your mind. Other than
that little problem with decomposing it should behave pretty much like
any other conductor. Look at the diagram from part 4 again. See how the
supply line from the - side of the seperator/splice (new name for our
electrolysis cell) runs on out to carry power to do other work and
eventually to a ground point somewhere? This is a crucially important
thing to consider. After all we didn't really use ANY electricity in our
electrolysis cell did we? Let that sink in for a moment.
We could figure some loss in because of resistance but actually we
lose less electricity by passing it through a seperator/splice than we
would in an equal length of copper due to copper's lower conductivity
and higher resistance. We do end up with some H2 and O2 gas though
because that is the inevitable by product of passing electricity through
this conductor.
These by products (H2 and O2 gasses) are created no matter how much
electricity we use. Well actually there are probably lower end limits
but I feel that they would be too low to be of any importance to us
here. I used 12v,30a in my experiments and that worked just fine.
What IS important is the fact that when water is used as a conductor
and an electrical current is passed through it the conductive material
(water) decomposes into it's basic component parts at a rate that is
directly proportional to the amount of electricity that the conductor is
being made to carry. That is my new law for that phenomenon. It would be
easy to create tables (if they don't already exist) so that you could
know the exact rate of decomposition at various power inputs.
Ok so here's the biggie: "What happens if you add ANOTHER
seperator/splice directly in line after the first?N

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Hi All,
   I decided that I might as well make this my christmaspresent to the world this year. Being on the verge of the new millenniummakes it even more appropriate and besides, I never had the chance to givethe world a present  before. I weighed the option of trying to makea buck or two off of it first but I would have had to get all greedy andsecretive to do that and I don't want all of the hassles. Maybe, if I turnout to be right, the world will give me something back anyway and that'sbetter isn't it? Even if I got nothing back I'd be no worse off than Iam now anyway would I?
   Right then, let's get to it. Here's how you can make waterinto a real, cheap, limitless source of fuel. One that will replace allliquid and gaseous forms of fossil fuels forever. And one which can beused TODAY because most systems that currently use fossil fuels could beretrofitted to use this fuel. When you are finished reading this you willprobably think is is a rather stupidly obvious answer but that's not myfault is it?
   The first thing that we have to do is to think of wateras a conductor. Not just realize the fact that it will conduct electricitybut actually think of it as you would a piece of copper or aluminum wire.Interestingly enough I read somewhere that there were experiments beingdone one time on using little water filled tubes as conductors in situationswhere high conductivity with low resistance was needed. So think aboutit that way. Water as a piece of liquid wire (with electrolyte added).
   Now let's look at the diagram of the simple electrolysiscell from "Water, Part 4". Notice how the main electrical supply line fromthe power source (Box P) feeds directly to the + terminal on the unit.Then consider the water between the + terminal and the - terminal as aconductor. One with high conductivity and low resistance. Sort of likea splice in our normal copper feeder line. Picture cutting a copper wireand then fastening a piece of aluminum wire between the cut ends. You endwill end up with a longer piece of total wire right? The basic abilityof the line to carry a charge would be unaffected.
   If you wanted to be really picky such an arrangement wouldput a few more variables into the mix since we are now using two totallydifferent conductors with different individual properties (aluminum isa better conductor than copper for example). I don't think that the overallperformance of the line would be affected by that splice though. Do you?Course not.
   Now let's do the same thing but instead of using aluminumwire let's put an electrolysis cell like the one in "Water, Part 4" inand see what happens. Actually let's drop the EMF coil from it. We won'tneed that any more.
   The thing that we have to see here is that water is adifficult thing for us to use as a conductor because of it's rather nastyhabit of decomposing into a potentially explosive combination of hydrogenand oxygen gasses whenever an electrical charge passes through it. Here'swhere anyone doing research into using water as a conductor would put wateron the shelf and forget about it. In this scenario the very gasses thatwe want to use for fuel are an annoyance.
   Now keep that idea of water as a conductor in your mind.Other than that little problem with decomposing it should behave prettymuch like any other conductor. Look at the diagram from part 4 again. Seehow the supply line from the - side of the seperator/splice (new name forour electrolysis cell) runs on out to carry power to do other work andeventually to a ground point somewhere? This is a crucially important thingto consider. After all we didn't really use ANY electricity in our electrolysiscell did we? Let that sink in for a moment.
   We could figure some loss in because of resistance butactually we lose less electricity by passing it through a seperator/splicethan we would in an equal length of copper due to copper's lower conductivityand higher resistance. We do end up with some H2 and O2 gas though becausethat is the inevitable by product of passing electricity through this conductor.
   These by products (H2 and O2 gasses) are created no matterhow much electricity we use. Well actually there are probably lower endlimits but I feel that they would be too low to be of any importance tous here. I used 12v,30a in my experiments and that worked just fine.
   What IS important is the fact that when water is usedas a conductor and an electrical current is passed through it the conductivematerial (water) decomposes into it's basic component parts at a rate thatis directly proportional to the amount of electricity that the conductoris being made to carry. That is my new law for that phenomenon. It wouldbe easy to create tables (if they don't already exist) so that you couldknow the exact rate of decomposition at various power inputs.
   Ok so here's the biggie: "What happens if you add ANOTHERseperator/splice directly in line after the first?N
 
 
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