A system and method for continuous batch monitoring of key quality characteristics of the production of precisely targeted FAC, optimally HOCl, through use of pressure, temperature, pH, ORP, tonicity sensors and spectroscopy instruments measuring the dynamic averages of product in a circulating vessel that informs the input production system through a dynamic feedback loop to make corrective formulations of key characteristics such that corrections occur to the constantly monitored HOCl solution in order to meet verified quality standard at the storage vessel's point of dispensing.

An electrochemical reaction device includes: an electrolytic unit that includes a cathode, an anode, a diaphragm, a cathode and an anode chamber; a first flow path through which a first fluid containing a reducible material flows, and; a second flow path through which a second fluid containing an oxidizable material flows; a third flow path through which a third fluid containing a reduction product flows; a fourth flow path through which a fourth fluid containing an oxidation product flows; a humidifier in the middle of the first flow path to humidify the first fluid; and a condenser in the middle of the first flow path so as to follow the humidifier and to treat the humidified first fluid and thus condenses a part of water vapor in the humidified first fluid to produce a condensed water, and to control a ratio of the condensed water in the humidified first fluid.

An electrochemical reaction device includes: an electrolytic unit that includes a cathode, an anode, a diaphragm, a cathode and an anode chamber; a first flow path through which a first fluid containing a reducible material flows, and; a second flow path through which a second fluid containing an oxidizable material flows; a third flow path through which a third fluid containing a reduction product flows; a fourth flow path through which a fourth fluid containing an oxidation product flows; a humidifier in the middle of the first flow path to humidify the first fluid; and a condenser in the middle of the first flow path so as to follow the humidifier and to treat the humidified first fluid and thus condenses a part of water vapor in the humidified first fluid to produce a condensed water, and to control a ratio of the condensed water in the humidified first fluid.

The present invention describes an electrochemical system (1) to electrochemically reduce carbon monoxide (CO) into liquid methanol and gaseous H.sub.2, comprising an electrochemical cell with an anodic compartment with an anode (2) with a current collector (2A), at least a catalyst to electrochemically oxidize H.sub.2O, and a cathodic compartment with a cathodic electrolyte solution comprising the solvent (3), and a cathodic supporting electrolyte, the solvent (3) being water at basic pH of between 10.5 and 13.5, the reagent CO; a cathode (4) which comprises, on a current collector (4A) which is electrochemically inert, at least a cobalt molecular catalyst (4B) to electrochemically reduce CO into liquid methanol and the gas H.sub.2, a power supply (5) providing the energy necessary to trigger the electrochemical reactions involving the reagent.

The present invention describes an electrochemical system (1) to electrochemically reduce carbon monoxide (CO) into liquid methanol and gaseous H.sub.2, comprising an electrochemical cell with an anodic compartment with an anode (2) with a current collector (2A), at least a catalyst to electrochemically oxidize H.sub.2O, and a cathodic compartment with a cathodic electrolyte solution comprising the solvent (3), and a cathodic supporting electrolyte, the solvent (3) being water at basic pH of between 10.5 and 13.5, the reagent CO; a cathode (4) which comprises, on a current collector (4A) which is electrochemically inert, at least a cobalt molecular catalyst (4B) to electrochemically reduce CO into liquid methanol and the gas H.sub.2, a power supply (5) providing the energy necessary to trigger the electrochemical reactions involving the reagent.

A solid oxide electrolyzer cell (SOEC) system including a stack of electrolyzer cells configured to receive water or steam in combination with hydrogen, and a steam recycle outlet configured to recycle a portion of the water or steam.

A solid oxide electrolyzer cell (SOEC) system including a stack of electrolyzer cells configured to receive water or steam in combination with hydrogen, and a steam recycle outlet configured to recycle a portion of the water or steam.

The present invention is a portable, on-demand hypochlorous acid (HOCL) generator and sprayer device contained in a wireless electrostatic backpack system designed for the purpose of sanitizing and disinfecting. The system converts a feeder solution of water mixed with sodium chloride acetic acid into a hypochlorous acid solution at adjustable concentrations (25-400 ppm) by electrolysis using both anode and cathode electrodes. The resulting solution is pressurized to 50-130 psi, and then atomized into an ultra-fine mist (40-80 microns) that passes through an electrically charged annular element to positively charge the atomized droplets, increasing the transfer efficiency to negative and neutrally charged surfaces by providing a wraparound, attractive force on surfaces sprayed. Various sensors, controls and a central processing unit (logic controller) are used to ensure the consistency and accuracy of the required output. The hypochlorous acid produced through this on-demand system is non-toxic and environmentally friendly.

The present invention is a portable, on-demand hypochlorous acid (HOCL) generator and sprayer device contained in a wireless electrostatic backpack system designed for the purpose of sanitizing and disinfecting. The system converts a feeder solution of water mixed with sodium chloride acetic acid into a hypochlorous acid solution at adjustable concentrations (25-400 ppm) by electrolysis using both anode and cathode electrodes. The resulting solution is pressurized to 50-130 psi, and then atomized into an ultra-fine mist (40-80 microns) that passes through an electrically charged annular element to positively charge the atomized droplets, increasing the transfer efficiency to negative and neutrally charged surfaces by providing a wraparound, attractive force on surfaces sprayed. Various sensors, controls and a central processing unit (logic controller) are used to ensure the consistency and accuracy of the required output. The hypochlorous acid produced through this on-demand system is non-toxic and environmentally friendly.

Systems and methods for increased oxygen output from an electrolyzer system are provided. The electrolyzer system includes a water storage tank. The electrolyzer system also includes an electrolyzer in fluid communication with the water storage tank and configured to produce oxygen and hydrogen from water e.g., (H.sub.2O). The electrolyzer system also includes one or more pressure isolating components configured to increase the oxygen output pressure of the system by pressure isolating the water storage tank from the electrolyzer stack.