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Posts tagged Gas
Research to Do
Jul 28th
A standard item in the typical Chemistry Laboratory is a Gas Chromatograph. This device identifies the molecular components of a sample substance specifying their AMU’s. This standard item can be used to analyze Brown’s Gas and reveal its internal molecular structures. Doctor Santilli performed such a GC experiment on a type of Brown’s Gas, and since such analysis has no precedence, there is no means of comparison. What is needed is data from many different Gas Chromatographs of Brown’s Gas produced in varying common ducted electrolyzer designs. Doing so will produce substantive data to analyze and draw precise conclusions. The current conclusions about Brown’s Gas are predominantly theory based on a trickle of laboratory data. Although the currently existing data is exciting, and consistent with proposed theory, subsequent experimentation and data production is required.
Hydrogen Fuel Analysis
Jul 27th
In chemistry, oxygen does not contribute energy to chemical reactions, and its main role is the facilitation of combustion. Considering this, Oxy-Hydrogen, Brown’s Gas, and Pure Hydrogen all have the exact same energy content on a mole per mole basis. Given the 1’st and 2′nd laws of electrolysis, energy in is always greater than energy out, why use one Hydrogen Fuel over another?
Pure Hydrogen
The beauty of pure hydrogen is that it can be substantially pressurized to over ten thousand [10,000] psi, which makes it a suitable fuel for tanking, storage, and distribution. Carbon nano-tube based materials, and potentially high strength alloys, appear to be the future of tanking.
Oxy-Hydrogen
Oxy-Hydrogen can be produced from tanked hydrogen and oxygen gases for torch application. Doing so will allow for the maximum potential of efficient energy recovery from the hydrogen. The more accurate the 2:1 ratio of hydrogen versus oxygen respectively, the more efficient the combustion of the hydrogen and oxygen into water and energy.
Brown’s Gas
Brown’s Gas can only be produced in a common ducted electrolyzer. The most efficient common ducted electrolyzer design is series cell parallel plate. By not separating the product hydrogen and oxygen gases efficiency is improved; when hydrogen is in the presence of oxygen, immediately after electrolytic production, the formation of diatomic hydrogen and oxygen formation is accompanied by subsequent structures of increased energy content. This accounts for the increasingly efficient electrolytic reaction observed in series cell common ducted electrolyzers.