The present invention provides an apparatus and method to generate optimally sized microbubbles and/or nanobubbles of hydrogen gas, oxygen gas and/or oxyhydrogen gas according electrolysis cell parameters and voltage and/or size and/or volume of water in a water reservoir or from a flow of water. In a water reservoir a control unit is operable to control water pump means to pump water at a predetermined velocity through the electrolysis cell according to the parameters of the electrolysis cell to control the average size of the nanobubbles and/or microbubbles generated, and the water flow at the predetermined velocity shears the generated nanobubbles and/or microbubbles from the electrodes into the water flow and through the water outlet of the apparatus. In a water flow, a control unit operable to adjust voltage to the electrolysis cell, whereby the amount of the voltage adjustment is made according to the rate of flow of water and to the parameters of the electrolysis cell to control the average size of the nanobubbles and/or microbubbles generated, and wherein the flow of water shears the generated nanobubbles and/or microbubbles from the electrodes into the water flow and through a water outlet.

The present invention provides an apparatus and method to generate optimally sized microbubbles and/or nanobubbles of hydrogen gas, oxygen gas and/or oxyhydrogen gas according electrolysis cell parameters and voltage and/or size and/or volume of water in a water reservoir or from a flow of water. In a water reservoir a control unit is operable to control water pump means to pump water at a predetermined velocity through the electrolysis cell according to the parameters of the electrolysis cell to control the average size of the nanobubbles and/or microbubbles generated, and the water flow at the predetermined velocity shears the generated nanobubbles and/or microbubbles from the electrodes into the water flow and through the water outlet of the apparatus. In a water flow, a control unit operable to adjust voltage to the electrolysis cell, whereby the amount of the voltage adjustment is made according to the rate of flow of water and to the parameters of the electrolysis cell to control the average size of the nanobubbles and/or microbubbles generated, and wherein the flow of water shears the generated nanobubbles and/or microbubbles from the electrodes into the water flow and through a water outlet.

A method comprising generating process heat from hydrox. In some versions, hydrox comprises at least 10%, 50%, 60%, 70%, 90%, or 99% by volume or by weight of a material having a stoichiometric ratio of hydrogen gas and oxygen gas. The process sometimes further comprises a step of providing an electric hydrox generator (EOG) and some EOG comprise an electrolyzer to produce hydrox. Versions of the (hydrox generator) electrolyzer have two or more cells, some of which sometimes exhibit a variable resistance function. Depending upon the version, the variable resistance function is measured or controlled electrically, mechanically, or electro-mechanically. Similarly, in these or other versions the EOG operates using photovoltaic electricity, which sometimes comes from a group of modules (such as 100 or more modules) arranged flatly on the ground. In some versions of the EOG, the power path does not contain a device that functions to adjust the voltage of the electricity in the power path. The disclosed methods can combust hydrox such that the combustion exhaust has less than 1000 NOx ppb. In various versions the hydrox feeds a boiler, furnace, turbine, engine, or other device using fuel.

A method comprising generating process heat from hydrox. In some versions, hydrox comprises at least 10%, 50%, 60%, 70%, 90%, or 99% by volume or by weight of a material having a stoichiometric ratio of hydrogen gas and oxygen gas. The process sometimes further comprises a step of providing an electric hydrox generator (EOG) and some EOG comprise an electrolyzer to produce hydrox. Versions of the (hydrox generator) electrolyzer have two or more cells, some of which sometimes exhibit a variable resistance function. Depending upon the version, the variable resistance function is measured or controlled electrically, mechanically, or electro-mechanically. Similarly, in these or other versions the EOG operates using photovoltaic electricity, which sometimes comes from a group of modules (such as 100 or more modules) arranged flatly on the ground. In some versions of the EOG, the power path does not contain a device that functions to adjust the voltage of the electricity in the power path. The disclosed methods can combust hydrox such that the combustion exhaust has less than 1000 NOx ppb. In various versions the hydrox feeds a boiler, furnace, turbine, engine, or other device using fuel.

An HHO gas stream for use in an internal combustion engine is heated by heat exchange from with an exhaust gas stream from the internal combustion engine.

Methods and systems for enhancing water treatment and desalination are provided. An example method includes generating structurally altered gas molecules from water, where the structurally altered gas molecules have a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the water. The method further includes mixing the structurally altered gas molecules with raw water to modify properties of the raw water, thereby increasing raw water filtering efficiency of a water filtering system.

Methods and systems for enhancing production of adenosine triphosphate (ATP) in living organisms are provided. An example method includes generating structurally altered gas molecules from water. The structurally altered gas molecules have a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the water. The method further includes infusing the structurally altered gas molecules into a living organism. Upon being infused, the structurally altered gas molecules cause an increase of production of the ATP in the living organism.

Methods and systems for enhancing production of adenosine triphosphate (ATP) in living organisms are provided. An example method includes generating structurally altered gas molecules from water. The structurally altered gas molecules have a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the water. The method further includes infusing the structurally altered gas molecules into a living organism. Upon being infused, the structurally altered gas molecules cause an increase of production of the ATP in the living organism.

A dual-chamber electrolysis vessel safely stores HHO gas for use by an internal combustion engine.

Safety of vehicles employing an electrolysis generator is improved by a rollover abatement system.