SimpleSimon
Active Member
Marty, water molecules form as the result of covalent (shared electron orbital shells) bonds between two hydrogen atoms and one oxygen atom. Due to the particularities of those bonds, the distance between the atomic cores in the molecule are sharply constrained, and the two hydrogen atoms interact with the oxygen atom to form a particular bond angle, with some range of motion.
It is that bond length/strength, and that bond angle, which together determine the resonant frequency of the bond. As it happens, it is a very short radio frequency. Applying the energy for electrolysis at that frequency targets the majority of the applied energy to the specific task of breaking those bonds, and the amount lost in causing thermal motion of the mass of the water is reduced. In effect, it increases the efficiency of the application, much as a laser beam more efficiently transmits light in a specified direction with much reduced "leakage". It does NOT lower the amount of energy necessary to breaking the bonds - that energy is determined by the physics of those atoms.
Overall, by more efficiently using the electric power input to disassociating those covalent bonds, it increases the efficiency of the use of the HHO as a fuel additive, because instead of getting back approzimately 70% (typical electrolytic cracker) of the energy as heat when you burn the HHO, you get back 90%+. It sounds complicated, but if you know fairly basicchemistry, it isn't.
Exactly the same type of frequency controlled application of electrical energy is used in a number of processes in the electronics industry, the petrochemical/plastics industry, and of late, in food processing. Oh yes, in the glass industry it is revolutionizing glass tempering.
I very strongly advise you - DO NOT ATTEMPT TO PRODUCE AND STORE ANY SIGNIFICANT AMOUNT OF HHO IN A PRESSURIZED SYSTEM - PERIOD!!!!
The probability of producing a catastrophic explosion from such an attempt approaches unity - the transition energy necessary to cause a single recombination event between one hydrogen atom and one oxygen atom (particularly in the monatomic state, which both gasses are unstable in the presence of themselves alone in) is so low that simple compression of the gas is sufficient to pass that threshhold. Once that process begins, it is absolutely unstoppable by ANY known means, and the effect is directly analogous to the neutron cascade in a fission bomb - one causes several more that multiply in a time frame of fentoseconds duration. And like that fission bomb, you WILL get heat and light in large quantity in an unbelievably short time - an explosion.
Please, as you love your life and your health, DO NOT ATTEMPT WHAT YOU ARE CONTEMPLATING!
i AM DEADLY SERIOUS.
It is that bond length/strength, and that bond angle, which together determine the resonant frequency of the bond. As it happens, it is a very short radio frequency. Applying the energy for electrolysis at that frequency targets the majority of the applied energy to the specific task of breaking those bonds, and the amount lost in causing thermal motion of the mass of the water is reduced. In effect, it increases the efficiency of the application, much as a laser beam more efficiently transmits light in a specified direction with much reduced "leakage". It does NOT lower the amount of energy necessary to breaking the bonds - that energy is determined by the physics of those atoms.
Overall, by more efficiently using the electric power input to disassociating those covalent bonds, it increases the efficiency of the use of the HHO as a fuel additive, because instead of getting back approzimately 70% (typical electrolytic cracker) of the energy as heat when you burn the HHO, you get back 90%+. It sounds complicated, but if you know fairly basicchemistry, it isn't.
Exactly the same type of frequency controlled application of electrical energy is used in a number of processes in the electronics industry, the petrochemical/plastics industry, and of late, in food processing. Oh yes, in the glass industry it is revolutionizing glass tempering.
I very strongly advise you - DO NOT ATTEMPT TO PRODUCE AND STORE ANY SIGNIFICANT AMOUNT OF HHO IN A PRESSURIZED SYSTEM - PERIOD!!!!
The probability of producing a catastrophic explosion from such an attempt approaches unity - the transition energy necessary to cause a single recombination event between one hydrogen atom and one oxygen atom (particularly in the monatomic state, which both gasses are unstable in the presence of themselves alone in) is so low that simple compression of the gas is sufficient to pass that threshhold. Once that process begins, it is absolutely unstoppable by ANY known means, and the effect is directly analogous to the neutron cascade in a fission bomb - one causes several more that multiply in a time frame of fentoseconds duration. And like that fission bomb, you WILL get heat and light in large quantity in an unbelievably short time - an explosion.
Please, as you love your life and your health, DO NOT ATTEMPT WHAT YOU ARE CONTEMPLATING!
i AM DEADLY SERIOUS.
Last edited: