The principle of membrane electrode electrolysis to produce ozone is to use low-voltage direct current to conduct positive and negative two-pole pure water of solid-state membrane electrode. Water is separated into hydrogen and oxygen molecules in the form of proton exchange at a special anode interface, and hydrogen is directly from the cathode. Emission, oxygen molecules are excited by electrons generated by high-density currents at the anode, and are polymerized into ozone. The by-products of the production of ozone by electrolysis are oxygen and hydrogen, and no nitrogen oxides (NOx), and air humidity is not consider.
The principle of membrane electrode electrolysis to produce ozone is to use low-voltage direct current to conduct positive and negative two-pole pure water of solid-state membrane electrode. Water is separated into hydrogen and oxygen molecules in the form of proton exchange at a special anode interface, and hydrogen is directly from the cathode. Emission, oxygen molecules are excited by electrons generated by high-density currents at the anode, and are polymerized into ozone. The by-products of the production of ozone by electrolysis are oxygen and hydrogen, and no nitrogen oxides (NOx), and air humidity is not consider.
The principle of membrane electrode electrolysis to produce ozone is to use low-voltage direct current to conduct positive and negative two-pole pure water of solid-state membrane electrode. Water is separated into hydrogen and oxygen molecules in the form of proton exchange at a special anode interface, and hydrogen is directly from the cathode. Emission, oxygen molecules are excited by electrons generated by high-density currents at the anode, and are polymerized into ozone. The by-products of the production of ozone by electrolysis are oxygen and hydrogen, and no nitrogen oxides (NOx), and air humidity is not consider.
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