Abstract: Pure water 3 is made to pass through a carbon dioxide contact mechanism, to become carbonated water, and is supplied to an ozone gas and hydrogen gas generation section, so that the concentration of generated ozone gas becomes stable. As a result, the concentration of the generated ozone gas is high and stable, and a high concentration can be maintained.

Abstract: Pure water 3 is made to pass through a carbon dioxide contact mechanism 8, to become carbonated water 6, and is supplied to the ozone gas and hydrogen gas generation section 1, so the concentration of generated ozone gas become stable at all time. As a result, the concentration of the generated ozone gas is high and stable at all times, and high concentration can be maintained.

Abstract: A method of water electrolysis for producing acidic water and alkaline water is disclosed, which is effective in preventing the dissolution of electrode material in the acidic water, etc. attributable to a reverse current flowing in a power supply cutoff state and also in preventing electrode deactivation caused by the electrode material dissolution. This enables the electrolytic cell to be operated stably over a long period of time to yield high-purity acidic and alkaline waters. An electrolytic cell 1 partitioned into an anode chamber and a cathode chamber with a cation-exchange membrane 2 as a solid electrolyte is used to electrolytically produce acidic water and alkaline water. A voltage of 1.2 V or higher and/or a current of 20 mA/dm.sup.2 or higher is applied between the anode 7 and the cathode 8 when the electrolytic cell is in a power supply cutoff state.

Abstract: There are provided an ozone water treatment method by comprising the steps of injecting an ozone-containing gas into pure water to prepare ozone water, supplying the ozone water to use point(s) for treatment of materials to be treated, and circulating for reuse or discharging the ozone water after use, which comprises disposing a deozonizing apparatus, the inside of which is divided into an ozone water passing zone and a reduced pressure zone by a diaphragm, at the downstream side of the use point(s), supplying the ozone water after use to the ozone water passing zone of the deozonizing apparatus, and removing residual ozone and residual oxygen in the ozone water after use by contacting the water with the reduced pressure zone through the diaphragm and an apparatus utilized in the ozone treatment method.

Abstract: An electrolytic ozone generator comprising anode chamber 3 and cathode chamber 4 partitioned by solid electrolyte 2, in which deionized water is electrolyzed in the cathode chamber while feeding air or oxygen-rich air to the cathode chamber through, for example, air holes 14. The air fed suppresses evolution of hydrogen gas thereby affording a saving of energy and eliminating the need a separate cooling mechanism. Furthermore, the air also decomposes ozone having entered the catholyte.

Abstract: A method and apparatus for water electrolysis is described, using an electrolytic cell comprising an anode compartment, a cathode compartment, and a diaphragm separating the anode and cathode compartments, comprising the steps of electrolyzing water to evolve oxygen or an ozone-containing oxygen gas in the anode compartment and hydrogen in the cathode compartment, thereby resulting in a net transfer of electrolyte from the anode compartment to the cathode compartment through the diaphragm, and recycling electrolyte from the cathode compartment to the anode compartment.

Abstract: Disclosed are a method for treatment with ozonized water which comprises feeding primary pure water to an ultrapure-water producing device containing at least a polisher to convert the primary pure water to ultrapure water, injecting an ozone-containing gas into the ultrapure water to produce ozonized water, sending the ozonized water to a point of use, using the ozonized water for treatment, and circulating the resulting spent ozonized water to the ultrapure-water producing device for reuse or discharging the spent water, wherein the method further comprises supplying a hydrogen-containing gas to the spent ozonized water at a point downstream from the use point to remove residual ozone from the ozonized water, a method for the ozone sterilization of ultrapure water which comprises feeding primary pure water from a primary-pure-water tank to an ultrapure-water producing device containing at least a polisher to convert the primary pure water to ultrapure water, sending the ultrapure water to a use point throug

Abstract: Disclosed is an electrode structure for ozone production which comprises a perfluorocarbon sulfonic acid-based ion-exchange membrane as a solid electrolyte and an anode placed on one side of the solid electrolyte and having a lead oxide as an electrode catalyst, wherein a porous, perfluorocarbon sulfonic acid-based ion-exchange resin layer is formed between the electrolyte and the anode. A process for producing the electrode structure for ozone production is also disclosed, which comprises coating one side of a perfluorocarbon sulfonic acid-based ion-exchange membrane as a solid electrolyte with a liquid, perfluorocarbon sulfonic acid-based ion-exchange resin or with a suspension of ion-exchange resin powder, heating-treating the liquid or suspension-formed ion-exchange resin coating to form an ion-exchange resin layer, and then positioning an anode so as to keep it in close contact with the ion-exchange resin layer, the anode having a lead oxide as an electrode catalyst.

Abstract: A method for producing ozone which comprises electrolyzing water using a fluororesin-type ion-exchange membrane as a solid electrolyte thereby to generate an ozone-containing gas, and cooling the gas thereby to remove a fluorine-containing substance present in the gas generated.

Abstract: A process for producing high concentration ozone water, which comprises contacting an ozone-containing gas with fine droplets of water to dissolve ozone in the ozone-containing gas into the fine droplets of water.

Abstract: An electrolytic ozone generator is described, which comprises a feed tank in which water is stored, an ion-exchange column connected to the feed tank, a pump for feeding the stored water in the feed tank to the ion-exchange column, an electrolytic cell connected to the ion-exchange column and containing a solid electrolyte which is an ion-exchange membrane, an anode disposed tightly on one side of the solid electrolyte, and a cathode disposed tightly on the other side of the solid electrolyte, an electromagnetic valve connected to and disposed between the ion-exchange column and the electrolytic cell, and a hydrogen-separating column connected to the electrolytic cell and for separating hydrogen from a gas-liquid mixture sent from the electrolytic cell and circulating the resulting water to the feed tank, and in which the liquid level of the anolyte in the electrolytic cell is sensed, and, in a case wherein said liquid level is below a predetermined value, ion-exchanged water is fed from the ion-exchange colu

Abstract: A method and apparatus for electrolytic ozone generation are described which process comprises feeding raw water to an ozone-generating electrolytic cell partitioned into an anode chamber and a cathode chamber by means of a solid electrolyte, said feeding of raw water being only to the cathode chamber, and conducting electrolysis to thereby produce ozone in the anode chamber.

Abstract: The present invention is directed toward an electrolytic ozonier for treating ozone-containing waste gas and a method of treating ozone-containing waste gas using the ozonier, wherein the method includes evolving oxygen and ozone in an anode compartment of an electrolytic cell by electrolysis of water while evolving hydrogen in a cathode compartment; directing the evolved hydrogen into a waste gas treating section that contains a waste gas decomposition catalyst so as to convert the hydrogen to a harmless form by means of the catalyst; bringing the oxygen and ozone into contact with a medium to be treated in an ozone contactor so as to treat the medium; and subsequently directing waste gas containing oxygen and ozone produced as a result of treatment of the medium into the waste gas treating section where they are brought into either direct or indirect contact with the catalyst so that the ozone in the waste gas is converted into a harmless form.

Abstract: A method and apparatus for water treatment is described, using electrolytic zone, which comprises electrolyzing water to generate an ozone-containing gas in the anode compartment of an electrolytic cell, separating the ozone-containing gas from the anolyte, and contacting the separated ozone-containing gas with the water to be treated said water to be treated being different than the water for electrolysis.

Abstract: A bipolar-electrode electrolytic cell is disclosed, which is to be used in electrolysis of an electrolytic solution having a high electric resistance and including at least two diaphragms positioned to form a plurality of electrode compartments comprising two outer compartments defined between the side walls of the electrolytic cell and the diaphragms positioned closest to the cell walls having a single electrode and at least one electrode compartment having two same-polar electrodes on both sides thereof, each of said electrodes being placed on a diaphragm such that different-polar electrodes are positioned at opposing sides of the diaphragm, wherein the distance between same-polar electrodes within the same compartment is sufficiently large such that electrolysis therebetween does not substantially occur and wherein two of said electrodes at the terminal ends of the series connected electrolytic cell, an anode and a cathode, being further electrically connected to an anode collector and a cathode collector,

Abstract: A bipolar-electrode type electrolytic cell for production of ozone is disclosed, including a plurality of solid electrolyte electrodes comprising a solid electrolyte ion exchange membrane having provided on opposing sides thereof an anode and a cathode, said electrodes positioned to form a plurality of electrode compartments between adjacent solid electrolyte electrodes, such that the anodes face each other to form anode compartments and the cathodes face each other to form cathode compartments, and between the side walls of the electrolytic cell and the solid electrolyte electrodes positioned closest to the cell side walls, wherein each of the anodes and the cathodes provided on the solid electrolyte electrodes are electrically connected to a different-polar electrode, respectively, which face the same direction and are present on adjacent solid electrolyte electrodes.