FIRST FREE ENERGY DEVICE REACHES MARKET IN OCTOBER -- The Game Changer is Here

[Rafa12]

any idea about how much it could cost the home edition?

[Goat]

You might be right.
It's a long time ago since I practiced some calculations on pressurized gassed so let my try in this case:
Weight of one liter Hydrogen at 1 Bar is roughly 0.09 grams
The 5 KW unit that will be developed has an hydrogen bottle with an estimated volume of 5 liters at most
According to the 'formal' website hosted by PesWiki, it consumes 1 gram each 6 month on average before requiring a refill.
A container of 5 liter pressurized at 50 Bar could contain 5 x 0.09 x 50 = 22.5 grams of hydrogen.
So, I think we can safely assume you are right about using pressurized hydrogen with that kind of consumption

Any useful reference(s) on such results with only pure nickel and hydrogen?

@ teslaalset & All

Chemalloy I believe it's called could be used indefinitely to provide Hydrogen to the system, never running out of a supply of Hydrogen to supply the reactor isn't a big problem, no need to get complicated.   But the most remarkable discovery was when the metal was ground down to a fine powder. When powdered ChemAlloy was placed in water, it immediately began producing hydrogen and oxygen bubbles. Check this....

From: http://www.free-energy.ws/samuel-freedman.html

"This process continued until all of the water was gone! But like before, the metal itself remained inert and chemically unchanged."

So if you could provide Hydrogen to the system using water and Chemalloy the only thing left to resolve is the reactor ..

Regards,
Paul

[Goat]

@ All

Found another forum discussing ChemAlloy...

http://www.godlikeproductions.com/forum1/message1055061/pg2

I couldn't copy the thread link but here's the information...

"This is very old news
Chemalloy powderized to about 1,000,000 particles per pound exhibits the same elecritical properties (Fig. 2) as the solid rod. Here it generates slightly more than .5 volt, and in addition decomposes the water, liberating hydrogen.
Chemalloy splits H2O into HHO at ambient temperature, this alloy was made in the 1950's, a cell of powdered chemalloy was used to produce HHO non stop for 7 years with no visible oxidation of the alloy before the test was halted.

Here's more info from Keely.net
Chemaloy Smelting Process from Patent # 2,796,345 of June 18, 1957

In preparing the alloy of the present invention, the following metals and metal alloys are melted together in a crucible in the following proportions to provide the metallic ingredients:

Pounds
Yellow brass (30% zinc and 70% copper)---------------- 8
Aluminum -------------------------------------------- 8
40-60 solder (40% tin 60% lead) --------------------- 1.5
Silver (.1%) or -------------------------------------- .1
Nickel (.1%) --------------------------------------- .1
Zinc, to make up a 100 pound batch or -------------- 82.3
-----------
100.0

The chemical ingredients are next prepared in approximately the following proportions, for a 100 pound batch of the above metal ingredients:


Powdered copper slag ---------------pounds--------- 3.0
Yellow sulphur ----------------------do------------ 1.25
Willow charcoal ---------------------do------------ 0.75
Commercial muriatic acid ----------gallons--------- 0.50


The chemical ingredients are mixed together thoroughly and the acid added and stirred into the dry ingredients until a thin or watery paste-like mass is produced.

Meanwhile, the metal ingredients in the crucible have been heated until they reach the temperature of approximately 1450º F. and a layer of fine grain powdered charcoal of approximately a half-inch thickness is deposited on top of the molten metal to form an insulating blanket. When this charcoal layer has become red in color, the wet mass of chemical ingredients is deposited entirely over the top of the charcoal blanket in a thick layer. Using a suitable pushing device, such as a metal rod, the chemical mass is forced down through the charcoal blanket into the molten metal mixture, a small area at a time. The charcoal blanket shields the remainder of the mass from explosion or excessive reaction.

As the chemical mass is pushed into the molten metal mixture in the crucible, a multitude of tiny reactions occurs throughout it, instead of a single large explosion, due to the fact that the chemical particles are separated from one another by the porous inert slag and by the particles of charcoal.

As each portion which has been pushed down into the molten mixture is absorbed into the latter, another portion is pushed down and so on, until each portion of the chemical mass or layer has been pushed through the insulating charcoal blanket, a small area at a time.

After all of the wet chemical mass has been pushed downward into the molten metal mixture in the crucible, the entire mixture is stirred thoroughly to release all of the chemicals from the pores of the copper slag and to cause the tiny reactions and the explosions to be completed. When this has been done, and the slag has lost its chemical impregnations by these reactions and minute explosions, the slag floats to the surface of the molten metal mixture, along with other impurities or superfluous materials, these being skimmed from the surface of the molten mixture, leaving the latter in its finished state. The chemically-impregnated alloy thus formed is then poured out and formed into suitable shapes such as rods, bars or ingots.

During the period in which the chemical ingredients are being pushed downward through the charcoal blanket into the molten metal mixture, corrosive fumes are emitted which must be carefully disposed of or they will discolor paint, corrode ferrous metals, and cause annoyance to persons in the vicinity. After the alloy has been made in the above manner, however, it may be subsequently remelted without the formation of such fumes. The chemically-impregnated alloy remaining after the process has been completed is a finely homogenized, high quality alloy which is easily machined, plated or painted, as desired.

The present process also enables the combining of zinc and lead in an alloy, even though these metals are normally incompatible. For example, only one-half of one percent of lead in a zinc based die, such as is used in aircraft production, causes the die to crack during use, because lead will not ordinarily mix with zinc satisfactorily.

The copper slag mentioned in the foregoing process is the waste slag produced in copper smelting plants, and is useful because of its porosity and inert characteristics. It will be obvious that other porous materials which are similarly inert may also be employed to subdivide the chemical ingredients in the above manner and thereby convert an otherwise dangerous single explosion into a multitude of tiny harmless explosions and reactions.

The chemical ingredients thus incorporated into the metal alloy impart to the alloy the capability of flowing naturally and easily by capillary attraction when the alloy is applied to the junction of metal parts, such as aluminum to be united, without the previous use of a flux. Hitherto, it has been necessary to apply a flux in order to form a flux path at the junction of the metal parts to be united, or otherwise the welding metal does not flow well, and does not easily enter the junction between the metal parts to be united.

The proportions, and indeed, the components of the metallic mixture are not critical and many variations may be used. In place of the brass, pure copper or even bronze can be employed, more copper giving greater strength. The nickel and silver components are mere traces which produce better uniting of the metal components with one another. The chemical components of the alloy enable the alloy to penetrate the oxide film on aluminum without wire brushing or other previous preparation and to penetrate the crack or other junction between the parts to be united and to emerge on the opposite side thereof.

Proof that the chemical ingredients remain in the alloy is found in the fact that shavings of the alloy placed in a glass of ordinary tap water cause the flow of an electric current which may be detected by a voltmeter, milliampmeter or cathode ray oscilloscope when leads or electrodes connected thereto are inserted in the water. Moreover when the alloy particles or shavings have been permitted to remain in the water for several hours, gas bubbles will emerge from the water and form on the surface. Each of these bubbles explodes upon the application of a match, showing that chemicals in the alloy shavings produce hydrogen and other gases when placed in water. A still more powerful effect is obtained when salt water is used. Moreover, if the alloy is prepared in the form of a powder, this powder tends to come to the surface of the water and float thereon even though its specific gravity or weight is nearly seven times that of water."

Regards,
Paul

[Goat]

@ All

That's interesting.

A few years ago a Google search would've shown a supplier for ChemAlloy,

I just tried and didn't see any company who supplies this material!

Anyone know of a supplier of this material?

Regards,
Paul

[lumen]

Any useful reference(s) on such results with only pure nickel and hydrogen?

From several links on page 17

http://www.lenr-canr.org/acrobat/FocardiSlargeexces.pdf